Gestartet durch vorgelagertes Projekt „ha:////4O00y0O7j4W2nWaM9gHyWgpZZxnR88tRf5mZoNhEK5WjAAAApR+LCAAAAAAAAP9b85aBtbiIQTGjNKU4P08vOT+vOD8nVc83PyU1x6OyILUoJzMv2y+/JJUBAhiZGBgqihhk0NSjKDWzXb3RdlLBUSYGJk8GtpzUvPSSDB8G5tKinBIGIZ+sxLJE/ZzEvHT94JKizLx0a6BxUmjGOUNodHsLgAzhEgZJ/az8JH2XxMycSl2X1JyCjMy84PycstQifQBGzWOTzgAAAA==Daily-DelphinSolver“, Build ha:////4JvHpG97JSIODcgSz0vnQmsvmV/K0ThEDfSlKlpCfAeQAAAAqR+LCAAAAAAAAP9b85aBtbiIQTGjNKU4P08vOT+vOD8nVc83PyU1x6OyILUoJzMv2y+/JJUBAhiZGBgqihhk0NSjKDWzXb3RdlLBUSYGJk8GtpzUvPSSDB8G5tKinBIGIZ+sxLJE/ZzEvHT94JKizLx0a6BxUmjGOUNodHsLgAyWEgZZ/az8JH2XxMycSl2X1JyCjMy84PycstQifRNTC1MAamrKldIAAAA=4585 Ursprünglich gestartet durch: Build wurde zeitgesteuert ausgelöst. Running as SYSTEM Baue auf Master in Arbeitsbereich /var/lib/jenkins/jobs/Daily-Examples-Init-DelphinSolver/workspace ha:////4HYyWc4RDderJ6Eog/IUi/UzPlKP2yURlbV0zBUsB+VzAAAAqh+LCAAAAAAAAP9b85aBtbiIQSujNKU4P0+vIKc0PTOvWC8xrzgzOT8nv0gvMbkkEyjhCKb88ktSdwVsu2efuqidiYHRh4EDIu2ZUsIg5JOVWJaon5OYl64fXFKUmZduXVHEIAU1ODk/rzg/J1XPGUKDDGKAAEYmBoaKghIGFVMjc8ukZJM03aSkNHNdk2QzA90kMyCRampplGKUap5qap4EAIQ8TZWvAAAA[workspace] $ /bin/sh -xe /tmp/jenkins3533918889485768887.sh + cd ../../Daily-DelphinSolver/workspace/DelphinSolver/build/cmake/ + echo ++++ starting init tests ++++ ++++ starting init tests ++++ + ./init_tests_examples.sh DELPHIN 6 Solver All rights reserved. The DELPHIN 6 Development Team: Andreas Nicolai, Stefan Vogelsang, Anne Paepcke, Heiko Fechner, John Grunewald Contact: andreas.nicolai [at] tu-dresden.de Compiled with GCC 9.4.0 Delphin model and file format library version 6.1.8 Material model and file format library version 6.1.1 IBK library version 5.0.0 DATAIO library version 7.1.4 CCM library version 1.1.0 JADE library version 1.3.1 JAC library version 1.6.0 Salt library version 1.0.0 Pollutant library version 1.3.0 Integrator Framework Version 1.0.0 SUNDIALS Release Version 2.7.0 Project file: 'DIN_EN_15026-2007/DIN EN 15026 - 2007.d6p' Output root dir: 'DIN_EN_15026-2007/DIN EN 15026 - 2007' Reading project file : DIN EN 15026 - 2007.d6p Project read successfully. Initializing model Initializing Solver Parameter Automatically setting NonLinSolverConvCoeff to 0.1, so that product of reltol and factor is 1e-6. Instantiating Balance Equation Module: 'Energy and Moisture Balance Equations (IBK)' [BEHeatMoisture] Checking assignments for valid ranges Removed unused definitions from project 1 materials (of 1) used: * Material EN 15026:2007 1 interface definitions (of 1) used: * Interface 1 0 initial conditions (of 0) used: 0 field conditions (of 0) used: 0 contact conditions (of 0) used: 2 boundary conditions (of 2) used: * Heat Conduction * Vapour Diffusion 2 climate conditions (of 2) used: * Temperature * RH 2 output file definition (of 2) used: * TempField * MoistField 1 output grids (of 1) used: * Interval Creating default initial conditions Default initial temperature = 20 degC Default initial relative humidity = 80 % Creating definitions for assessments/reports Creating interface definitions for engineering models Reading material data files Reading material file 'EN_150262007_16777217.m6'. Reading climate data files and initializing calculation Connecting Definitions Module Setup Selecting standard flux modules: FluxHeatConduction FluxLiquidConvection FluxMoistureEnthalpy FluxVaporDiffusion Selecting standard boundary flux modules: BCFluxHeatConduction BCFluxMoistureEnthalpy BCFluxVaporDiffusion Instantiating flux modules [BCFluxHeatConduction] Boundary Condition: Heat Conduction Flux (IBK) [BCFluxVaporDiffusion] Boundary Condition: Vapor Diffusion Flux (IBK) [FluxHeatConduction] Heat Conduction Flux (IBK) [FluxLiquidConvection] Liquid Convection Flux (IBK) [FluxVaporDiffusion] Vapor Diffusion Flux (IBK) [BCFluxMoistureEnthalpy] Boundary Condition: Enthalpy flux for liquid convection and vapor diffusion (IBK) [FluxMoistureEnthalpy] Enthalpy flux for liquid convection and vapor diffusion (IBK) Creating auxiliary model data Initializing quantities 34 States 7 Internal Fluxes 8 Boundary Condition Fluxes 2 Sources Discretization and Grid Generation Grid width (x-dim, radius) = 50 m Grid height (y-dim, height) = 1 m Grid depth (z-dimension) = 1 m Assigning materials 'Material EN 15026:2007' [EN_150262007_16777217.m6] Assigning Initial Conditions 'Default initial relative humidity' [RelativeHumidity] assigned to [0, 0, 0] - [524, 0, 0] 'Default initial temperature' [Temperature] assigned to [0, 0, 0] - [524, 0, 0] Assigning field conditions Grid numbering: Optimizing numbering in domain #1. Domain element range: 0..524, size = 525 Numbering Order: col, stack, row [IKJ] (loop order) Optimizing CMK numbering starting from node: 0 -> hbw = 1 524 -> hbw = 1 CMK (optimized) - max. half bandwidth: 1 Total elements count : 525 Used elements count : 525 Assigning interfaces Removing unused sides Assigning output file definitions for horizontal sides. Assigning interfaces 'Interface 1' assigned to [0, 0, 0] - [0, 0, 0] Left Removing unused sides Assigning output file definitions for vertical sides. Assigning interfaces Removing unused sides Assigning output file definitions for frontal sides. Total side count : 2626 Reduced side count : 525 Creating Element -> Side links Computing weight-factors for boundary value extrapolation Volumes/areas for used material references: Material Area [m2] ------------------------------------------------------------ Material EN 15026:2007 50 Grid complete. Elements : 525 Sides (total/internal/boundary) : 525/524/1 Half-Bandwidth (element-based) : 1 Checking field conditions Initializing data storage vectors (memory allocation) Creating/opening output files Composing initial condition vector Input value checks Checking modules for runtime exceptions before starting calculation. Checking sources for runtime exceptions before starting calculation. Checking flux modules for runtime exceptions before starting calculation. Initialization Model Interface Creating Linear Equation Solver Modules Number of unknowns : 1050 Element-based half-Bandwidth : 1 Using generic Band solver with bandwidth 7! Creating Integrator Using CVODE integrator. Model initialization complete. Creating solver framework Initializing CVODE integrator Setting NonlinConvCoef to 0.1. Setting MaxNonLinIters (maxcor) to 3. Initializing LES solver implementation Stopping after successful initialization of integrator. DELPHIN 6 Solver All rights reserved. The DELPHIN 6 Development Team: Andreas Nicolai, Stefan Vogelsang, Anne Paepcke, Heiko Fechner, John Grunewald Contact: andreas.nicolai [at] tu-dresden.de Compiled with GCC 9.4.0 Delphin model and file format library version 6.1.8 Material model and file format library version 6.1.1 IBK library version 5.0.0 DATAIO library version 7.1.4 CCM library version 1.1.0 JADE library version 1.3.1 JAC library version 1.6.0 Salt library version 1.0.0 Pollutant library version 1.3.0 Integrator Framework Version 1.0.0 SUNDIALS Release Version 2.7.0 Project file: 'EN_ISO_10211/DIN EN ISO 10211 Case1.d6p' Output root dir: 'EN_ISO_10211/DIN EN ISO 10211 Case1' Reading project file : DIN EN ISO 10211 Case1.d6p Project read successfully. Initializing model Initializing Solver Parameter Instantiating Balance Equation Module: 'Energy Balance Equation (IBK)' [BEHeat] Checking assignments for valid ranges Removed unused definitions from project 2 materials (of 2) used: * Concrete_C20_25 * Concrete_C20_25 [2] 2 interface definitions (of 2) used: * Interface 1 * Interface 2 0 initial conditions (of 0) used: 0 field conditions (of 0) used: 0 contact conditions (of 0) used: 2 boundary conditions (of 2) used: * Inside Heat Conduction * Outside Heat Conduction 2 climate conditions (of 2) used: * Inside Temperature (constant) * Outside Temperature (constant) 7 output file definition (of 7) used: * TempField1 * TempField2 * TempField3 * TempField4 * TempField5 * TempField6 * TempField7 1 output grids (of 1) used: * Profiles Creating default initial conditions Default initial temperature = 20 degC Default initial relative humidity = 80 % Creating definitions for assessments/reports Creating interface definitions for engineering models Reading material data files Reading material file 'Concrete_C20_25_10000.m6'. Reading material file 'Concrete_C20_25[2]_10001.m6'. Reading climate data files and initializing calculation Connecting Definitions Module Setup Selecting standard flux modules: FluxHeatConduction Selecting standard boundary flux modules: BCFluxHeatConduction Instantiating flux modules [BCFluxHeatConduction] Boundary Condition: Heat Conduction Flux (IBK) [FluxHeatConduction] Heat Conduction Flux (IBK) Creating auxiliary model data Initializing quantities 7 States 2 Internal Fluxes 4 Boundary Condition Fluxes 1 Sources Discretization and Grid Generation Grid width (x-dim, radius) = 0.999999 m Grid height (y-dim, height) = 2 m Grid depth (z-dimension) = 1 m Assigning materials 'Concrete_C20_25 [2]' [Concrete_C20_25[2]_10001.m6] 'Concrete_C20_25' [Concrete_C20_25_10000.m6] Assigning Initial Conditions 'Default initial relative humidity' [RelativeHumidity] assigned to [0, 0, 0] - [99, 199, 0] 'Default initial temperature' [Temperature] assigned to [0, 0, 0] - [99, 199, 0] Assigning field conditions Grid numbering: Optimizing numbering in domain #1. Domain element range: 0..19999, size = 20000 Numbering Order: row, col, stack [JIK] (loop order) Optimizing CMK numbering starting from node: 0 -> hbw = 101 5049 -> hbw = 100 14950 -> hbw = 101 19999 -> hbw = 100 CMK (optimized) - max. half bandwidth: 100 Total elements count : 20000 Used elements count : 20000 Assigning interfaces 'Interface 1' assigned to [0, 199, 0] - [99, 199, 0] Top 'Interface 2' assigned to [0, 0, 0] - [99, 0, 0] Bottom Removing unused sides Assigning output file definitions for horizontal sides. Assigning interfaces 'Interface 2' assigned to [0, 0, 0] - [0, 199, 0] Left Removing unused sides Assigning output file definitions for vertical sides. Assigning interfaces Removing unused sides Assigning output file definitions for frontal sides. Total side count : 80300 Reduced side count : 40100 Creating Element -> Side links Computing weight-factors for boundary value extrapolation Volumes/areas for used material references: Material Area [m2] ------------------------------------------------------------ Concrete_C20_25 0.999998 Concrete_C20_25 [2] 0.999998 Grid complete. Elements : 20000 Sides (total/internal/boundary) : 40100/39700/400 Half-Bandwidth (element-based) : 100 Checking field conditions Initializing data storage vectors (memory allocation) Creating/opening output files Composing initial condition vector Input value checks Checking modules for runtime exceptions before starting calculation. Checking sources for runtime exceptions before starting calculation. Checking flux modules for runtime exceptions before starting calculation. Initialization Model Interface Creating Linear Equation Solver Modules Number of unknowns : 20000 Element-based half-Bandwidth : 100 Using KLU sparse direct solver! Creating Integrator Using CVODE integrator. Model initialization complete. Creating solver framework Initializing CVODE integrator Setting NonlinConvCoef to 1e-05. Setting MaxNonLinIters (maxcor) to 3. Initializing Jacobian implementation SparseMatrix: generating color arrays 7 colors Initializing LES solver implementation Stopping after successful initialization of integrator. DELPHIN 6 Solver All rights reserved. The DELPHIN 6 Development Team: Andreas Nicolai, Stefan Vogelsang, Anne Paepcke, Heiko Fechner, John Grunewald Contact: andreas.nicolai [at] tu-dresden.de Compiled with GCC 9.4.0 Delphin model and file format library version 6.1.8 Material model and file format library version 6.1.1 IBK library version 5.0.0 DATAIO library version 7.1.4 CCM library version 1.1.0 JADE library version 1.3.1 JAC library version 1.6.0 Salt library version 1.0.0 Pollutant library version 1.3.0 Integrator Framework Version 1.0.0 SUNDIALS Release Version 2.7.0 Project file: 'EN_ISO_10211/DIN EN ISO 10211 Case2.d6p' Output root dir: 'EN_ISO_10211/DIN EN ISO 10211 Case2' Reading project file : DIN EN ISO 10211 Case2.d6p Project read successfully. Initializing model Initializing Solver Parameter Instantiating Balance Equation Module: 'Energy Balance Equation (IBK)' [BEHeat] Checking assignments for valid ranges Removed unused definitions from project 4 materials (of 4) used: * Material1 * Material4 * Material3 * Material2 2 interface definitions (of 2) used: * Inside * Outside 0 initial conditions (of 0) used: 0 field conditions (of 0) used: 0 contact conditions (of 0) used: 2 boundary conditions (of 2) used: * Inside Heat Conduction * Outside Heat Conduction 2 climate conditions (of 4) used: * Inside Temperature (constant) * Outside Temperature (constant) 5 output file definition (of 5) used: * HeatFlux * TempField1 * TempField2 * TempField3 * TempField4 2 output grids (of 2) used: * Endtime * Hourly Creating default initial conditions Default initial temperature = 10 degC Default initial relative humidity = 80 % Creating definitions for assessments/reports Creating interface definitions for engineering models Reading material data files Reading material file 'Material1_100000.m6'. Reading material file 'Material4_100003.m6'. Reading material file 'Material3_100002.m6'. Reading material file 'Material2_100001.m6'. Reading climate data files and initializing calculation Connecting Definitions Auto-generating CC 'RelativeHumidity' for constant value: 50 %, referenced from BC 'Outside Heat Conduction' Module Setup Selecting standard flux modules: FluxHeatConduction Selecting standard boundary flux modules: BCFluxHeatConduction Instantiating flux modules [BCFluxHeatConduction] Boundary Condition: Heat Conduction Flux (IBK) [FluxHeatConduction] Heat Conduction Flux (IBK) Creating auxiliary model data Initializing quantities 7 States 2 Internal Fluxes 4 Boundary Condition Fluxes 1 Sources Discretization and Grid Generation Grid width (x-dim, radius) = 0.5 m Grid height (y-dim, height) = 0.0475 m Grid depth (z-dimension) = 1 m Assigning materials 'Material1' [Material1_100000.m6] 'Material2' [Material2_100001.m6] 'Material3' [Material3_100002.m6] 'Material4' [Material4_100003.m6] Assigning Initial Conditions 'Default initial relative humidity' [RelativeHumidity] assigned to [0, 0, 0] - [193, 188, 0] 'Default initial temperature' [Temperature] assigned to [0, 0, 0] - [193, 188, 0] Assigning field conditions Grid numbering: Optimizing numbering in domain #1. Domain element range: 0..36665, size = 36666 Numbering Order: col, row, stack [IJK] (loop order) Optimizing CMK numbering starting from node: 0 -> hbw = 189 17766 -> hbw = 189 18899 -> hbw = 190 36665 -> hbw = 190 CMK (optimized) - max. half bandwidth: 189 Total elements count : 36666 Used elements count : 36666 Assigning interfaces 'Inside' assigned to [0, 0, 0] - [193, 0, 0] Bottom 'Outside' assigned to [0, 188, 0] - [193, 188, 0] Top Removing unused sides Assigning output file definitions for horizontal sides. Assigning interfaces Removing unused sides Assigning output file definitions for vertical sides. Assigning interfaces Removing unused sides Assigning output file definitions for frontal sides. Total side count : 147047 Reduced side count : 73337 Creating Element -> Side links Computing weight-factors for boundary value extrapolation Volumes/areas for used material references: Material Area [m2] ------------------------------------------------------------ Material1 0.003 Material4 0.00082275 Material3 0.0198522 Material2 7.5e-05 Grid complete. Elements : 36666 Sides (total/internal/boundary) : 73337/72949/388 Half-Bandwidth (element-based) : 189 Checking field conditions Initializing data storage vectors (memory allocation) Creating/opening output files Output definition 'HeatFlux' is only assigned to boundary sides, therefore boundary flux sign convention is used. Composing initial condition vector Input value checks Checking modules for runtime exceptions before starting calculation. Checking sources for runtime exceptions before starting calculation. Checking flux modules for runtime exceptions before starting calculation. Initialization Model Interface Creating Linear Equation Solver Modules Number of unknowns : 36666 Element-based half-Bandwidth : 189 Using KLU sparse direct solver! Creating Integrator Using CVODE integrator. Model initialization complete. Creating solver framework Initializing CVODE integrator Setting NonlinConvCoef to 1e-05. Setting MaxNonLinIters (maxcor) to 3. Initializing Jacobian implementation SparseMatrix: generating color arrays 7 colors Initializing LES solver implementation Stopping after successful initialization of integrator. DELPHIN 6 Solver All rights reserved. The DELPHIN 6 Development Team: Andreas Nicolai, Stefan Vogelsang, Anne Paepcke, Heiko Fechner, John Grunewald Contact: andreas.nicolai [at] tu-dresden.de Compiled with GCC 9.4.0 Delphin model and file format library version 6.1.8 Material model and file format library version 6.1.1 IBK library version 5.0.0 DATAIO library version 7.1.4 CCM library version 1.1.0 JADE library version 1.3.1 JAC library version 1.6.0 Salt library version 1.0.0 Pollutant library version 1.3.0 Integrator Framework Version 1.0.0 SUNDIALS Release Version 2.7.0 Project file: 'HamstadBenchmarks/HamstadBenchmark1.d6p' Output root dir: 'HamstadBenchmarks/HamstadBenchmark1' Reading project file : HamstadBenchmark1.d6p Project read successfully. Initializing model Initializing Solver Parameter Automatically setting NonLinSolverConvCoeff to 0.1, so that product of reltol and factor is 1e-6. Instantiating Balance Equation Module: 'Energy and Moisture Balance Equations (IBK)' [BEHeatMoisture] Checking assignments for valid ranges Removed unused definitions from project 2 materials (of 2) used: * Hamstad Benchmark 1 Load bearing material * Hamstad Benchmark 1 Insulation Material 2 interface definitions (of 2) used: * Interface 1 * Interface 2 3 initial conditions (of 3) used: * Temperatur * Wassergehalt_MaterialA * Wassergehalt_MaterialB 0 field conditions (of 0) used: 0 contact conditions (of 0) used: 3 boundary conditions (of 3) used: * Inside Heat Conduction * Inside Vapour Diffusion * Outside Heat Conduction 3 climate conditions (of 4) used: * Inside Temperatures (constant) * Outside Temperature (data points) * Inside Water Vapour Pressure 3 output file definition (of 7) used: * HeatFluxInside * MoistMaterialA * MoistMaterialB 1 output grids (of 1) used: * Hourly Creating default initial conditions Default initial temperature = 20 degC Default initial relative humidity = 80 % Creating definitions for assessments/reports Creating interface definitions for engineering models Reading material data files Reading material file 'HamstadBenchmark1Loadbearingmaterial_16777217.m6'. Reading material file 'HamstadBenchmark1InsulationMaterial_16777218.m6'. Reading climate data files and initializing calculation ${Project Directory}/climates/HB1_Teq_e.ccd  Quantity of climate data file 'TEMPER' does not match requested quantity 'Temperature' of climate condition definition.  ${Project Directory}/climates/HB1_pa_i.ccd  Quantity of climate data file 'VAPPRESS' does not match requested quantity 'VaporPressure' of climate condition definition.  Connecting Definitions Module Setup Selecting standard flux modules: FluxHeatConduction FluxLiquidConvection FluxMoistureEnthalpy FluxVaporDiffusion Selecting standard boundary flux modules: BCFluxHeatConduction BCFluxMoistureEnthalpy BCFluxVaporDiffusion Instantiating flux modules [BCFluxHeatConduction] Boundary Condition: Heat Conduction Flux (IBK) [BCFluxVaporDiffusion] Boundary Condition: Vapor Diffusion Flux (IBK) [FluxHeatConduction] Heat Conduction Flux (IBK) [FluxLiquidConvection] Liquid Convection Flux (IBK) [FluxVaporDiffusion] Vapor Diffusion Flux (IBK) [BCFluxMoistureEnthalpy] Boundary Condition: Enthalpy flux for liquid convection and vapor diffusion (IBK) [FluxMoistureEnthalpy] Enthalpy flux for liquid convection and vapor diffusion (IBK) Creating auxiliary model data Initializing quantities 34 States 7 Internal Fluxes 8 Boundary Condition Fluxes 2 Sources Discretization and Grid Generation Grid width (x-dim, radius) = 1 m Grid height (y-dim, height) = 0.15 m Grid depth (z-dimension) = 1 m Assigning materials 'Hamstad Benchmark 1 Insulation Material' [HamstadBenchmark1InsulationMaterial_16777218.m6] 'Hamstad Benchmark 1 Load bearing material' [HamstadBenchmark1Loadbearingmaterial_16777217.m6] Assigning Initial Conditions 'Default initial relative humidity' [RelativeHumidity] assigned to [0, 0, 0] - [0, 149, 0] 'Default initial temperature' [Temperature] assigned to [0, 0, 0] - [0, 149, 0] 'Temperatur' [Temperature] assigned to [0, 0, 0] - [0, 149, 0] 'Wassergehalt_MaterialA' [MoistureMass] assigned to [0, 50, 0] - [0, 149, 0] 'Wassergehalt_MaterialB' [MoistureMass] assigned to [0, 0, 0] - [0, 49, 0] Assigning field conditions Grid numbering: Optimizing numbering in domain #1. Domain element range: 0..149, size = 150 Numbering Order: row, stack, col [JKI] (loop order) Optimizing CMK numbering starting from node: 0 -> hbw = 1 149 -> hbw = 1 CMK (optimized) - max. half bandwidth: 1 Total elements count : 150 Used elements count : 150 Assigning interfaces 'Interface 1' assigned to [0, 149, 0] - [0, 149, 0] Top 'Interface 2' assigned to [0, 0, 0] - [0, 0, 0] Bottom Removing unused sides Assigning output file definitions for horizontal sides. Assigning interfaces Removing unused sides Assigning output file definitions for vertical sides. Assigning interfaces Removing unused sides Assigning output file definitions for frontal sides. Total side count : 751 Reduced side count : 151 Creating Element -> Side links Computing weight-factors for boundary value extrapolation Volumes/areas for used material references: Material Area [m2] ------------------------------------------------------------ Hamstad Benchmark 1 Load bearing material 0.1 Hamstad Benchmark 1 Insulation Material 0.05 Grid complete. Elements : 150 Sides (total/internal/boundary) : 151/149/2 Half-Bandwidth (element-based) : 1 Checking field conditions Initializing data storage vectors (memory allocation) Creating/opening output files Output definition 'HeatFluxInside' is only assigned to boundary sides, therefore boundary flux sign convention is used. Composing initial condition vector Input value checks Checking modules for runtime exceptions before starting calculation. Checking sources for runtime exceptions before starting calculation. Checking flux modules for runtime exceptions before starting calculation. Initialization Model Interface Creating Linear Equation Solver Modules Number of unknowns : 300 Element-based half-Bandwidth : 1 Using generic Band solver with bandwidth 7! Creating Integrator Using CVODE integrator. Model initialization complete. Creating solver framework Initializing CVODE integrator Setting NonlinConvCoef to 0.1. Setting MaxNonLinIters (maxcor) to 3. Initializing LES solver implementation Stopping after successful initialization of integrator. DELPHIN 6 Solver All rights reserved. The DELPHIN 6 Development Team: Andreas Nicolai, Stefan Vogelsang, Anne Paepcke, Heiko Fechner, John Grunewald Contact: andreas.nicolai [at] tu-dresden.de Compiled with GCC 9.4.0 Delphin model and file format library version 6.1.8 Material model and file format library version 6.1.1 IBK library version 5.0.0 DATAIO library version 7.1.4 CCM library version 1.1.0 JADE library version 1.3.1 JAC library version 1.6.0 Salt library version 1.0.0 Pollutant library version 1.3.0 Integrator Framework Version 1.0.0 SUNDIALS Release Version 2.7.0 Project file: 'HamstadBenchmarks/HamstadBenchmark2.d6p' Output root dir: 'HamstadBenchmarks/HamstadBenchmark2' Reading project file : HamstadBenchmark2.d6p Project read successfully. Initializing model Initializing Solver Parameter Automatically setting NonLinSolverConvCoeff to 0.1, so that product of reltol and factor is 1e-6. Instantiating Balance Equation Module: 'Energy and Moisture Balance Equations (IBK)' [BEHeatMoisture] Checking assignments for valid ranges Removed unused definitions from project 1 materials (of 1) used: * Hamstad Benchmark 2 Material A 2 interface definitions (of 2) used: * Interface 1 * Interface 2 2 initial conditions (of 2) used: * Initial_Temp * Initial_Moist 0 field conditions (of 0) used: 0 contact conditions (of 0) used: 4 boundary conditions (of 4) used: * Inside Heat Conduction * Inside Vapor Diffusion * Outside Heat Conduction * Outside Vapor Diffusion 4 climate conditions (of 4) used: * Inside Temperature (constant) * Outside Temperature (constant) * Inside Water Vapour Pressure (constant) * Outside Water Vapour Pressure (constant) 1 output file definition (of 1) used: * MoistField 1 output grids (of 1) used: * Variabel Creating default initial conditions Default initial temperature = 20 degC Default initial relative humidity = 80 % Creating definitions for assessments/reports Creating interface definitions for engineering models Reading material data files Reading material file 'HamstadBenchmark2MaterialA_16777217.m6'. Reading climate data files and initializing calculation Connecting Definitions Module Setup Selecting standard flux modules: FluxHeatConduction FluxLiquidConvection FluxMoistureEnthalpy FluxVaporDiffusion Selecting standard boundary flux modules: BCFluxHeatConduction BCFluxMoistureEnthalpy BCFluxVaporDiffusion Instantiating flux modules [BCFluxHeatConduction] Boundary Condition: Heat Conduction Flux (IBK) [BCFluxVaporDiffusion] Boundary Condition: Vapor Diffusion Flux (IBK) [FluxHeatConduction] Heat Conduction Flux (IBK) [FluxLiquidConvection] Liquid Convection Flux (IBK) [FluxVaporDiffusion] Vapor Diffusion Flux (IBK) [BCFluxMoistureEnthalpy] Boundary Condition: Enthalpy flux for liquid convection and vapor diffusion (IBK) [FluxMoistureEnthalpy] Enthalpy flux for liquid convection and vapor diffusion (IBK) Creating auxiliary model data Initializing quantities 34 States 7 Internal Fluxes 8 Boundary Condition Fluxes 2 Sources Discretization and Grid Generation Grid width (x-dim, radius) = 1 m Grid height (y-dim, height) = 0.2 m Grid depth (z-dimension) = 1 m Assigning materials 'Hamstad Benchmark 2 Material A' [HamstadBenchmark2MaterialA_16777217.m6] Assigning Initial Conditions 'Default initial relative humidity' [RelativeHumidity] assigned to [0, 0, 0] - [0, 199, 0] 'Default initial temperature' [Temperature] assigned to [0, 0, 0] - [0, 199, 0] 'Initial_Temp' [Temperature] assigned to [0, 0, 0] - [0, 199, 0] 'Initial_Moist' [MoistureMass] assigned to [0, 0, 0] - [0, 199, 0] Assigning field conditions Grid numbering: Optimizing numbering in domain #1. Domain element range: 0..199, size = 200 Numbering Order: row, stack, col [JKI] (loop order) Optimizing CMK numbering starting from node: 0 -> hbw = 1 199 -> hbw = 1 CMK (optimized) - max. half bandwidth: 1 Total elements count : 200 Used elements count : 200 Assigning interfaces 'Interface 1' assigned to [0, 199, 0] - [0, 199, 0] Top 'Interface 2' assigned to [0, 0, 0] - [0, 0, 0] Bottom Removing unused sides Assigning output file definitions for horizontal sides. Assigning interfaces Removing unused sides Assigning output file definitions for vertical sides. Assigning interfaces Removing unused sides Assigning output file definitions for frontal sides. Total side count : 1001 Reduced side count : 201 Creating Element -> Side links Computing weight-factors for boundary value extrapolation Volumes/areas for used material references: Material Area [m2] ------------------------------------------------------------ Hamstad Benchmark 2 Material A 0.2 Grid complete. Elements : 200 Sides (total/internal/boundary) : 201/199/2 Half-Bandwidth (element-based) : 1 Checking field conditions Initializing data storage vectors (memory allocation) Creating/opening output files Composing initial condition vector Input value checks Checking modules for runtime exceptions before starting calculation. Checking sources for runtime exceptions before starting calculation. Checking flux modules for runtime exceptions before starting calculation. Initialization Model Interface Creating Linear Equation Solver Modules Number of unknowns : 400 Element-based half-Bandwidth : 1 Using generic Band solver with bandwidth 7! Creating Integrator Using CVODE integrator. Model initialization complete. Creating solver framework Initializing CVODE integrator Setting NonlinConvCoef to 0.1. Setting MaxNonLinIters (maxcor) to 3. Initializing LES solver implementation Stopping after successful initialization of integrator. DELPHIN 6 Solver All rights reserved. The DELPHIN 6 Development Team: Andreas Nicolai, Stefan Vogelsang, Anne Paepcke, Heiko Fechner, John Grunewald Contact: andreas.nicolai [at] tu-dresden.de Compiled with GCC 9.4.0 Delphin model and file format library version 6.1.8 Material model and file format library version 6.1.1 IBK library version 5.0.0 DATAIO library version 7.1.4 CCM library version 1.1.0 JADE library version 1.3.1 JAC library version 1.6.0 Salt library version 1.0.0 Pollutant library version 1.3.0 Integrator Framework Version 1.0.0 SUNDIALS Release Version 2.7.0 Project file: 'HamstadBenchmarks/HamstadBenchmark3.d6p' Output root dir: 'HamstadBenchmarks/HamstadBenchmark3' Reading project file : HamstadBenchmark3.d6p Project read successfully. Initializing model Initializing Solver Parameter Automatically setting NonLinSolverConvCoeff to 0.1, so that product of reltol and factor is 1e-6. Instantiating Balance Equation Module: 'HeatAirMoisture Balance Equation (IBK)' [BEHeatAirMoisture] Checking assignments for valid ranges Removed unused definitions from project 1 materials (of 1) used: * Hamstad Benchmark 3 Leight Weight Wall 2 interface definitions (of 2) used: * Interface 1 * Interface 2 2 initial conditions (of 2) used: * DEFAULT Initial Temperature * DEFAULT Initial Relative Humidity 0 field conditions (of 0) used: 0 contact conditions (of 0) used: 6 boundary conditions (of 6) used: * Inside Air pressure * Inside Heat Conduction * Inside Vapor Diffusion * Outside Air pressure * Outside Heat Conduction * Outside Vapor Diffusion 6 climate conditions (of 6) used: * Inside Temperature (constant) * Outside Temperature (constant) * Inside Relative Humidity (constant) * Outside Relative Humidity (constant) * Inside Air pressure (data) * Outside Air pressure (constant) 10 output file definition (of 10) used: * Temp0.05m * Temp0.10m * Temp0.15m * Temp0.17m * Temp0.19m * Moist0.05m * Moist0.10m * Moist0.15m * Moist0.17m * Moist0.19m 1 output grids (of 1) used: * Daily Creating default initial conditions Default initial temperature = 20 degC Default initial relative humidity = 80 % Creating definitions for assessments/reports Creating interface definitions for engineering models Reading material data files Reading material file 'HamstadBenchmark3LeightWeightWall_16777217.m6'. Reading climate data files and initializing calculation ${Project Directory}/climates/HB3_pa_i.ccd  Quantity of climate data file 'GASPRESS' does not match requested quantity 'GasPressure' of climate condition definition.  Connecting Definitions Module Setup Selecting standard flux modules: FluxAirConvectionEnthalpy FluxAirConvectionMoisture FluxAirConvectionMoistureEnthalpy FluxHeatConduction FluxLiquidConvection FluxMoistureEnthalpy FluxVaporDiffusion Selecting standard boundary flux modules: BCFluxAirConvectionEnthalpy BCFluxAirConvectionMoisture BCFluxAirConvectionMoistureEnthalpy BCFluxHeatConduction BCFluxMoistureEnthalpy BCFluxVaporDiffusion Instantiating flux modules [BCFluxHeatConduction] Boundary Condition: Heat Conduction Flux (IBK) [BCFluxVaporDiffusion] Boundary Condition: Vapor Diffusion Flux (IBK) [FluxHeatConduction] Heat Conduction Flux (IBK) [FluxLiquidConvection] Liquid Convection Flux (IBK) [FluxVaporDiffusion] Vapor Diffusion Flux (IBK) [BCFluxMoistureEnthalpy] Boundary Condition: Enthalpy flux for liquid convection and vapor diffusion (IBK) [BCFluxAirConvectionMoisture] Boundary Condition: AirConvectionMoisture Flux (IBK) [FluxAirConvectionMoisture] Convective dry air and vapor mass fluxes (IBK) [FluxMoistureEnthalpy] Enthalpy flux for liquid convection and vapor diffusion (IBK) [BCFluxAirConvectionEnthalpy] Boundary Condition: AirConvectionEnthalpy Flux (IBK) [BCFluxAirConvectionMoistureEnthalpy] Boundary Condition: AirConvectionEnthalpy Flux (IBK) [FluxAirConvectionEnthalpy] Convective dry air enthalpy flux (IBK) [FluxAirConvectionMoistureEnthalpy] Convective vapor enthalpy flux (IBK) Creating auxiliary model data Initializing quantities 38 States 11 Internal Fluxes 12 Boundary Condition Fluxes 2 Sources Discretization and Grid Generation Grid width (x-dim, radius) = 0.2 m Grid height (y-dim, height) = 1 m Grid depth (z-dimension) = 1 m Assigning materials 'Hamstad Benchmark 3 Leight Weight Wall' [HamstadBenchmark3LeightWeightWall_16777217.m6] Assigning Initial Conditions 'Default initial relative humidity' [RelativeHumidity] assigned to [0, 0, 0] - [199, 0, 0] 'Default initial temperature' [Temperature] assigned to [0, 0, 0] - [199, 0, 0] 'DEFAULT Initial Temperature' [Temperature] assigned to [0, 0, 0] - [199, 0, 0] 'DEFAULT Initial Relative Humidity' [RelativeHumidity] assigned to [0, 0, 0] - [199, 0, 0] Assigning field conditions Grid numbering: Optimizing numbering in domain #1. Domain element range: 0..199, size = 200 Numbering Order: col, stack, row [IKJ] (loop order) Optimizing CMK numbering starting from node: 0 -> hbw = 1 199 -> hbw = 1 CMK (optimized) - max. half bandwidth: 1 Total elements count : 200 Used elements count : 200 Assigning interfaces Removing unused sides Assigning output file definitions for horizontal sides. Assigning interfaces 'Interface 1' assigned to [0, 0, 0] - [0, 0, 0] Left 'Interface 2' assigned to [199, 0, 0] - [199, 0, 0] Right Removing unused sides Assigning output file definitions for vertical sides. Assigning interfaces Removing unused sides Assigning output file definitions for frontal sides. Total side count : 1001 Reduced side count : 201 Creating Element -> Side links Computing weight-factors for boundary value extrapolation Volumes/areas for used material references: Material Area [m2] ------------------------------------------------------------ Hamstad Benchmark 3 Leight Weight Wall 0.2 Grid complete. Elements : 200 Sides (total/internal/boundary) : 201/199/2 Half-Bandwidth (element-based) : 1 Checking field conditions Initializing data storage vectors (memory allocation) Creating/opening output files Composing initial condition vector Input value checks Checking modules for runtime exceptions before starting calculation. Checking sources for runtime exceptions before starting calculation. Checking flux modules for runtime exceptions before starting calculation. Initialization Model Interface Creating Linear Equation Solver Modules Number of unknowns : 400 Element-based half-Bandwidth : 1 Using generic Band solver with bandwidth 7! Creating Integrator Using CVODE integrator. Model initialization complete. Creating solver framework Initializing CVODE integrator Setting NonlinConvCoef to 0.1. Setting MaxNonLinIters (maxcor) to 3. Initializing LES solver implementation Stopping after successful initialization of integrator. DELPHIN 6 Solver All rights reserved. The DELPHIN 6 Development Team: Andreas Nicolai, Stefan Vogelsang, Anne Paepcke, Heiko Fechner, John Grunewald Contact: andreas.nicolai [at] tu-dresden.de Compiled with GCC 9.4.0 Delphin model and file format library version 6.1.8 Material model and file format library version 6.1.1 IBK library version 5.0.0 DATAIO library version 7.1.4 CCM library version 1.1.0 JADE library version 1.3.1 JAC library version 1.6.0 Salt library version 1.0.0 Pollutant library version 1.3.0 Integrator Framework Version 1.0.0 SUNDIALS Release Version 2.7.0 Project file: 'HamstadBenchmarks/HamstadBenchmark4.d6p' Output root dir: 'HamstadBenchmarks/HamstadBenchmark4' Reading project file : HamstadBenchmark4.d6p Project read successfully. Initializing model Initializing Solver Parameter Automatically setting NonLinSolverConvCoeff to 0.1, so that product of reltol and factor is 1e-6. Instantiating Balance Equation Module: 'Energy and Moisture Balance Equations (IBK)' [BEHeatMoisture] Checking assignments for valid ranges Removed unused definitions from project 2 materials (of 2) used: * Hamstad Benchmark 4 Load bearing material * Hamstad Benchmark 4 Finishing material at inside 2 interface definitions (of 2) used: * Interface 1 * Interface 2 2 initial conditions (of 2) used: * Global temperatures * Global capillary pressures 0 field conditions (of 0) used: 0 contact conditions (of 0) used: 5 boundary conditions (of 5) used: * Inside Heatcond * Inside Vapdiff * Outside Heatcond * Outside Vapdiff * Outside Watcontc 6 climate conditions (of 6) used: * Outside ambient temperature (constant) * Outside temperature (data) * Outside vapor pressure (constant) * Outside imposed flux (data) * Inside temperature (constant) * Inside vapor pressure (data) 6 output file definition (of 6) used: * TempField * TempInside * TempOutside * MoistField * MoistInside * MoistOutside 2 output grids (of 2) used: * Hourly * Variabel Creating default initial conditions Default initial temperature = 20 degC Default initial relative humidity = 80 % Creating definitions for assessments/reports Creating interface definitions for engineering models Reading material data files Reading material file 'HamstadBenchmark4Loadbearingmaterial_16777217.m6'. Reading material file 'HamstadBenchmark4Finishingmaterialatinside_16777218.m6'. Reading climate data files and initializing calculation ${Project Directory}/climates/HB4_Teq_e.ccd  Quantity of climate data file 'TEMPER' does not match requested quantity 'Temperature' of climate condition definition.  ${Project Directory}/climates/HB4_rain.ccd  Quantity of climate data file 'WATFLUX' does not match requested quantity 'WaterFlux' of climate condition definition.  ${Project Directory}/climates/HB4_pa_i.ccd  Quantity of climate data file 'VAPPRESS' does not match requested quantity 'VaporPressure' of climate condition definition.  Connecting Definitions Module Setup Selecting standard flux modules: FluxHeatConduction FluxLiquidConvection FluxMoistureEnthalpy FluxVaporDiffusion Selecting standard boundary flux modules: BCFluxHeatConduction BCFluxMoistureEnthalpy BCFluxVaporDiffusion BCFluxWaterContact Instantiating flux modules [BCFluxHeatConduction] Boundary Condition: Heat Conduction Flux (IBK) [BCFluxVaporDiffusion] Boundary Condition: Vapor Diffusion Flux (IBK) [BCFluxWaterContact] Boundary Condition: Water Contact Liquid Water Flux (IBK) [FluxHeatConduction] Heat Conduction Flux (IBK) [FluxLiquidConvection] Liquid Convection Flux (IBK) [FluxVaporDiffusion] Vapor Diffusion Flux (IBK) [BCFluxMoistureEnthalpy] Boundary Condition: Enthalpy flux for liquid convection and vapor diffusion (IBK) [FluxMoistureEnthalpy] Enthalpy flux for liquid convection and vapor diffusion (IBK) Creating auxiliary model data Initializing quantities 34 States 7 Internal Fluxes 9 Boundary Condition Fluxes 2 Sources Discretization and Grid Generation Grid width (x-dim, radius) = 0.12 m Grid height (y-dim, height) = 1 m Grid depth (z-dimension) = 1 m Assigning materials 'Hamstad Benchmark 4 Finishing material at inside' [HamstadBenchmark4Finishingmaterialatinside_16777218.m6] 'Hamstad Benchmark 4 Load bearing material' [HamstadBenchmark4Loadbearingmaterial_16777217.m6] Assigning Initial Conditions 'Default initial relative humidity' [RelativeHumidity] assigned to [0, 0, 0] - [241, 0, 0] 'Default initial temperature' [Temperature] assigned to [0, 0, 0] - [241, 0, 0] 'Global temperatures' [Temperature] assigned to [0, 0, 0] - [241, 0, 0] 'Global capillary pressures' [CapillaryPressure] assigned to [0, 0, 0] - [241, 0, 0] Assigning field conditions Grid numbering: Optimizing numbering in domain #1. Domain element range: 0..241, size = 242 Numbering Order: col, stack, row [IKJ] (loop order) Optimizing CMK numbering starting from node: 0 -> hbw = 1 241 -> hbw = 1 CMK (optimized) - max. half bandwidth: 1 Total elements count : 242 Used elements count : 242 Assigning interfaces Removing unused sides Assigning output file definitions for horizontal sides. Assigning interfaces 'Interface 1' assigned to [0, 0, 0] - [0, 0, 0] Left 'Interface 2' assigned to [241, 0, 0] - [241, 0, 0] Right Removing unused sides Assigning output file definitions for vertical sides. Assigning interfaces Removing unused sides Assigning output file definitions for frontal sides. Total side count : 1211 Reduced side count : 243 Creating Element -> Side links Computing weight-factors for boundary value extrapolation Volumes/areas for used material references: Material Area [m2] ------------------------------------------------------------ Hamstad Benchmark 4 Load bearing material 0.1 Hamstad Benchmark 4 Finishing material at inside 0.02 Grid complete. Elements : 242 Sides (total/internal/boundary) : 243/241/2 Half-Bandwidth (element-based) : 1 Checking field conditions Initializing data storage vectors (memory allocation) Creating/opening output files Composing initial condition vector Input value checks Checking modules for runtime exceptions before starting calculation. Checking sources for runtime exceptions before starting calculation. Checking flux modules for runtime exceptions before starting calculation. Initialization Model Interface Creating Linear Equation Solver Modules Number of unknowns : 484 Element-based half-Bandwidth : 1 Using generic Band solver with bandwidth 7! Creating Integrator Using CVODE integrator. Model initialization complete. Creating solver framework Initializing CVODE integrator Setting NonlinConvCoef to 0.1. Setting MaxNonLinIters (maxcor) to 3. Initializing LES solver implementation Stopping after successful initialization of integrator. DELPHIN 6 Solver All rights reserved. The DELPHIN 6 Development Team: Andreas Nicolai, Stefan Vogelsang, Anne Paepcke, Heiko Fechner, John Grunewald Contact: andreas.nicolai [at] tu-dresden.de Compiled with GCC 9.4.0 Delphin model and file format library version 6.1.8 Material model and file format library version 6.1.1 IBK library version 5.0.0 DATAIO library version 7.1.4 CCM library version 1.1.0 JADE library version 1.3.1 JAC library version 1.6.0 Salt library version 1.0.0 Pollutant library version 1.3.0 Integrator Framework Version 1.0.0 SUNDIALS Release Version 2.7.0 Project file: 'HamstadBenchmarks/HamstadBenchmark5.d6p' Output root dir: 'HamstadBenchmarks/HamstadBenchmark5' Reading project file : HamstadBenchmark5.d6p Project read successfully. Initializing model Initializing Solver Parameter Automatically setting NonLinSolverConvCoeff to 0.1, so that product of reltol and factor is 1e-6. Instantiating Balance Equation Module: 'Energy and Moisture Balance Equations (IBK)' [BEHeatMoisture] Checking assignments for valid ranges Removed unused definitions from project 3 materials (of 3) used: * Hamstad Benchmark 5 Brick * Hamstad Benchmark 5 Inside insulation * Hamstad Benchmark 5 Mortar 2 interface definitions (of 2) used: * Interface 1 * Interface 2 2 initial conditions (of 2) used: * DEFAULT Initial Temperature * DEFAULT Initial Relative Humidity 0 field conditions (of 0) used: 0 contact conditions (of 0) used: 4 boundary conditions (of 4) used: * Inside Heat Conduction * Inside Vapor Diffusion * Outside Heat Conduction * Outside Vapor Diffusion 4 climate conditions (of 4) used: * Inside Temperature (constant) * Outside Temperature (constant) * Inside Relative Humidity (constant) * Outside Relative Humidity (constant) 2 output file definition (of 2) used: * MoistField * RHField 1 output grids (of 1) used: * Endtime Creating default initial conditions Default initial temperature = 20 degC Default initial relative humidity = 80 % Creating definitions for assessments/reports Creating interface definitions for engineering models Reading material data files Reading material file 'HamstadBenchmark5Brick_16777217.m6'. Reading material file 'HamstadBenchmark5Insideinsulation_16777218.m6'. Reading material file 'HamstadBenchmark5Mortar_16777219.m6'. Reading climate data files and initializing calculation Connecting Definitions Module Setup Selecting standard flux modules: FluxHeatConduction FluxLiquidConvection FluxMoistureEnthalpy FluxVaporDiffusion Selecting standard boundary flux modules: BCFluxHeatConduction BCFluxMoistureEnthalpy BCFluxVaporDiffusion Instantiating flux modules [BCFluxHeatConduction] Boundary Condition: Heat Conduction Flux (IBK) [BCFluxVaporDiffusion] Boundary Condition: Vapor Diffusion Flux (IBK) [FluxHeatConduction] Heat Conduction Flux (IBK) [FluxLiquidConvection] Liquid Convection Flux (IBK) [FluxVaporDiffusion] Vapor Diffusion Flux (IBK) [BCFluxMoistureEnthalpy] Boundary Condition: Enthalpy flux for liquid convection and vapor diffusion (IBK) [FluxMoistureEnthalpy] Enthalpy flux for liquid convection and vapor diffusion (IBK) Creating auxiliary model data Initializing quantities 34 States 7 Internal Fluxes 8 Boundary Condition Fluxes 2 Sources Discretization and Grid Generation Grid width (x-dim, radius) = 0.42 m Grid height (y-dim, height) = 1 m Grid depth (z-dimension) = 1 m Assigning materials 'Hamstad Benchmark 5 Brick' [HamstadBenchmark5Brick_16777217.m6] 'Hamstad Benchmark 5 Inside insulation' [HamstadBenchmark5Insideinsulation_16777218.m6] 'Hamstad Benchmark 5 Mortar' [HamstadBenchmark5Mortar_16777219.m6] Assigning Initial Conditions 'Default initial relative humidity' [RelativeHumidity] assigned to [0, 0, 0] - [419, 0, 0] 'Default initial temperature' [Temperature] assigned to [0, 0, 0] - [419, 0, 0] 'DEFAULT Initial Temperature' [Temperature] assigned to [0, 0, 0] - [419, 0, 0] 'DEFAULT Initial Relative Humidity' [RelativeHumidity] assigned to [0, 0, 0] - [419, 0, 0] Assigning field conditions Grid numbering: Optimizing numbering in domain #1. Domain element range: 0..419, size = 420 Numbering Order: col, stack, row [IKJ] (loop order) Optimizing CMK numbering starting from node: 0 -> hbw = 1 419 -> hbw = 1 CMK (optimized) - max. half bandwidth: 1 Total elements count : 420 Used elements count : 420 Assigning interfaces Removing unused sides Assigning output file definitions for horizontal sides. Assigning interfaces 'Interface 1' assigned to [419, 0, 0] - [419, 0, 0] Right 'Interface 2' assigned to [0, 0, 0] - [0, 0, 0] Left Removing unused sides Assigning output file definitions for vertical sides. Assigning interfaces Removing unused sides Assigning output file definitions for frontal sides. Total side count : 2101 Reduced side count : 421 Creating Element -> Side links Computing weight-factors for boundary value extrapolation Volumes/areas for used material references: Material Area [m2] ------------------------------------------------------------ Hamstad Benchmark 5 Brick 0.365 Hamstad Benchmark 5 Inside insulation 0.04 Hamstad Benchmark 5 Mortar 0.015 Grid complete. Elements : 420 Sides (total/internal/boundary) : 421/419/2 Half-Bandwidth (element-based) : 1 Checking field conditions Initializing data storage vectors (memory allocation) Creating/opening output files Composing initial condition vector Input value checks Checking modules for runtime exceptions before starting calculation. Checking sources for runtime exceptions before starting calculation. Checking flux modules for runtime exceptions before starting calculation. Initialization Model Interface Creating Linear Equation Solver Modules Number of unknowns : 840 Element-based half-Bandwidth : 1 Using generic Band solver with bandwidth 7! Creating Integrator Using CVODE integrator. Model initialization complete. Creating solver framework Initializing CVODE integrator Setting NonlinConvCoef to 0.1. Setting MaxNonLinIters (maxcor) to 3. Initializing LES solver implementation Stopping after successful initialization of integrator. DELPHIN 6 Solver All rights reserved. The DELPHIN 6 Development Team: Andreas Nicolai, Stefan Vogelsang, Anne Paepcke, Heiko Fechner, John Grunewald Contact: andreas.nicolai [at] tu-dresden.de Compiled with GCC 9.4.0 Delphin model and file format library version 6.1.8 Material model and file format library version 6.1.1 IBK library version 5.0.0 DATAIO library version 7.1.4 CCM library version 1.1.0 JADE library version 1.3.1 JAC library version 1.6.0 Salt library version 1.0.0 Pollutant library version 1.3.0 Integrator Framework Version 1.0.0 SUNDIALS Release Version 2.7.0 Project file: 'Ice/FreezingBrickWall_1D.d6p' Output root dir: 'Ice/FreezingBrickWall_1D' Reading project file : FreezingBrickWall_1D.d6p Project read successfully. Initializing model Initializing Solver Parameter Instantiating Balance Equation Module: 'Energy and Moisture Balance Equations (IBK)' [BEHeatMoisture] Checking assignments for valid ranges Removed unused definitions from project 1 materials (of 1) used: * Altbauziegel Schloss Güterfelde (EG_Außenwand 1) [544] 2 interface definitions (of 2) used: * Cold side * Warm side 2 initial conditions (of 2) used: * Moisture saturated * 50 % saturated 0 field conditions (of 0) used: 0 contact conditions (of 0) used: 0 boundary conditions (of 0) used: 0 climate conditions (of 0) used: 22 output file definition (of 22) used: * Profile-Temperature-Saturated * Profile-RelativeHumidity-Saturated * Profile-LiquidMassDensity-Saturated * Integral-IceMassDensity-Saturated * Profile-Temperature-MediumWet * Profile-RelativeHumidity-MediumWet * Profile-LiquidMassDensity-MediumWet * Integral-IceMassDensity-MediumWet * Profile-Temperature-Dry * Profile-RelativeHumidity-Dry * Profile-LiquidMassDensity-Dry * Integral-IceMassDensity-Dry * Profile-IceMassDensity-Saturated * Profile-IceMassDensity-MediumWet * Profile-IceMassDensity-Dry * Profile-MoistureMassDensity-Saturated * Profile-MoistureMassDensity-MediumWet * Profile-MoistureMassDensity-Dry * Capillary pressure-MediumWet * VaporPressure-MediumWet * Profile-Vapor flux densities-MediumWet * Profile-Liquid flux densities-MediumWet 2 output grids (of 2) used: * Felder und Profile * Skalare Creating default initial conditions Default initial temperature = 10 degC Default initial relative humidity = 80 % Creating definitions for assessments/reports Creating interface definitions for engineering models Interface 'Cold side' [EngineeringIndoor] transformed to detailed model Interface 'Warm side' [EngineeringIndoor] transformed to detailed model Reading material data files Reading material file 'AltbauziegelSchlossGueterfeldeEGAussenwand1_544.m6'. Reading climate data files and initializing calculation Connecting Definitions Module Setup Selecting standard flux modules: FluxHeatConduction FluxLiquidConvection FluxMoistureEnthalpy FluxVaporDiffusion Selecting standard boundary flux modules: BCFluxHeatConduction BCFluxMoistureEnthalpy BCFluxVaporDiffusion Instantiating flux modules [BCFluxHeatConduction] Boundary Condition: Heat Conduction Flux (IBK) [BCFluxVaporDiffusion] Boundary Condition: Vapor Diffusion Flux (IBK) [FluxHeatConduction] Heat Conduction Flux (IBK) [FluxLiquidConvection] Liquid Convection Flux (IBK) [FluxVaporDiffusion] Vapor Diffusion Flux (IBK) [BCFluxMoistureEnthalpy] Boundary Condition: Enthalpy flux for liquid convection and vapor diffusion (IBK) [FluxMoistureEnthalpy] Enthalpy flux for liquid convection and vapor diffusion (IBK) Creating auxiliary model data Initializing quantities 36 States 7 Internal Fluxes 8 Boundary Condition Fluxes 2 Sources Discretization and Grid Generation Grid width (x-dim, radius) = 0.1 m Grid height (y-dim, height) = 1 m Grid depth (z-dimension) = 1 m Assigning materials 'Old Building Brick Schloss Güterfelde (GF outer brick 1)' [AltbauziegelSchlossGueterfeldeEGAussenwand1_544.m6] VOID Assigning Initial Conditions 'Default initial relative humidity' [RelativeHumidity] assigned to [0, 0, 0] - [99, 4, 0] 'Default initial temperature' [Temperature] assigned to [0, 0, 0] - [99, 4, 0] 'Moisture saturated' [RelativeHumidity] assigned to [0, 4, 0] - [99, 4, 0] '50 % saturated' [MoistureContent] assigned to [0, 2, 0] - [99, 2, 0] Assigning field conditions Grid numbering: Starting new domain after 100 nodes. Starting new domain after 200 nodes. Optimizing numbering in domain #1. Domain element range: 0..99, size = 100 Numbering Order: col, stack, row [IKJ] (loop order) Optimizing CMK numbering starting from node: 0 -> hbw = 1 99 -> hbw = 1 Optimizing numbering in domain #2. Domain element range: 100..199, size = 100 Numbering Order: col, stack, row [IKJ] (loop order) Optimizing CMK numbering starting from node: 100 -> hbw = 1 199 -> hbw = 1 Optimizing numbering in domain #3. Domain element range: 200..299, size = 100 Numbering Order: col, stack, row [IKJ] (loop order) Optimizing CMK numbering starting from node: 200 -> hbw = 1 299 -> hbw = 1 CMK (optimized) - max. half bandwidth: 1 Total elements count : 500 Used elements count : 300 Assigning interfaces Removing unused sides Assigning output file definitions for horizontal sides. Assigning interfaces 'Cold side' assigned to [0, 0, 0] - [0, 4, 0] Left 'Warm side' assigned to [99, 0, 0] - [99, 4, 0] Right  The following interfaces are assigned in the interior of the construction (between two material elements) or to a void area. This is invalid and the respective interface assignments are ignored in the calculation.  'Cold side'  'Warm side'  Removing unused sides Assigning output file definitions for vertical sides. Assigning interfaces Removing unused sides Assigning output file definitions for frontal sides. Total side count : 2105 Reduced side count : 303 Creating Element -> Side links Computing weight-factors for boundary value extrapolation Volumes/areas for used material references: Material Area [m2] ------------------------------------------------------------ Altbauziegel Schloss Güterfelde (EG_Außenwand 1) [544] 0.06 Grid complete. Elements : 300 Sides (total/internal/boundary) : 303/297/6 Half-Bandwidth (element-based) : 1 Checking field conditions Initializing data storage vectors (memory allocation) Creating/opening output files Output definition 'Profile-Vapor flux densities-MediumWet' is assigned to at least one internal side, therefore field flux sign convention is used.  Boundary flux with ID name 'FluxLiquidConvection' is not being generated with current set of selected modules. Output flux, if requested, will be always 0.  Output definition 'Profile-Liquid flux densities-MediumWet' is assigned to at least one internal side, therefore field flux sign convention is used. Composing initial condition vector Input value checks Checking modules for runtime exceptions before starting calculation. Checking sources for runtime exceptions before starting calculation. Checking flux modules for runtime exceptions before starting calculation. Initialization Model Interface Creating Linear Equation Solver Modules Number of unknowns : 600 Element-based half-Bandwidth : 1 Using generic Band solver with bandwidth 7! Creating Integrator Using CVODE integrator. Model initialization complete. Creating solver framework Initializing CVODE integrator Setting NonlinConvCoef to 0.08. Setting MaxNonLinIters (maxcor) to 3. Initializing LES solver implementation Stopping after successful initialization of integrator. DELPHIN 6 Solver All rights reserved. The DELPHIN 6 Development Team: Andreas Nicolai, Stefan Vogelsang, Anne Paepcke, Heiko Fechner, John Grunewald Contact: andreas.nicolai [at] tu-dresden.de Compiled with GCC 9.4.0 Delphin model and file format library version 6.1.8 Material model and file format library version 6.1.1 IBK library version 5.0.0 DATAIO library version 7.1.4 CCM library version 1.1.0 JADE library version 1.3.1 JAC library version 1.6.0 Salt library version 1.0.0 Pollutant library version 1.3.0 Integrator Framework Version 1.0.0 SUNDIALS Release Version 2.7.0 Project file: 'Realklima/RealKlima.d6p' Output root dir: 'Realklima/RealKlima' Reading project file : RealKlima.d6p Project read successfully. Initializing model Initializing Solver Parameter Automatically setting NonLinSolverConvCoeff to 0.1, so that product of reltol and factor is 1e-6. Instantiating Balance Equation Module: 'Energy and Moisture Balance Equations (IBK)' [BEHeatMoisture] Checking assignments for valid ranges Removed unused definitions from project 9 materials (of 9) used: * Altbauziegel Dresden ZE * Levelling Plaster * Calsitherm KP Glue Mortar * Calsitherm Climate Board WF * Calsitherm KP Lime Plaster * Bitumen * Spruce_radial (from Saxony) mue= 50 lbd_dry=0,1 * Mineral Wool 035 * Gypsum Board 7 interface definitions (of 7) used: * Wand - Nord * Wand - Ost * Wand - Sued * Wand - West * Dach - horizontal * Innenseite, Wand * Innenseite, Dach 0 initial conditions (of 0) used: 0 field conditions (of 0) used: 2 contact conditions (of 2) used: * SIGA Majrex * Unterdachbahn Tyvek 0 boundary conditions (of 0) used: 0 climate conditions (of 0) used: 52 output file definition (of 52) used: * State_Gesamtfeuchtegehalt_DACH * State_Gesamtfeuchtegehalt_NORD * State_Gesamtfeuchtegehalt_OST * State_Gesamtfeuchtegehalt_SÜD * State_Gesamtfeuchtegehalt_WEST * State_Gesamtfeuchtegehalt_DACH_JahresEnde * State_Gesamtfeuchtegehalt_NORD_JahresEnde * State_Gesamtfeuchtegehalt_OST_JahresEnde * State_Gesamtfeuchtegehalt_SÜD_JahresEnde * State_Gesamtfeuchtegehalt_WEST_JahresEnde * Flux_Feuchte_DACH * Flux_Regen_auftreffend_DACH * Flux_Regen_eindringend_DACH * FluxInt_Regen_auftreffend_DACH * Flux_Strahlung_kurzwellig_DACH * FluxInt_Strahlung_kurzwellig_DACH * Flux_Strahlung_langwellig_DACH * FluxInt_Strahlung_langwellig_DACH * Flux_Feuchte_NORD * Flux_Regen_auftreffend_NORD * Flux_Regen_eindringend_NORD * FluxInt_Regen_auftreffend_NORD * Flux_Strahlung_kurzwellig_NORD * FluxInt_Strahlung_kurzwellig_NORD * Flux_Strahlung_langwellig_NORD * FluxInt_Strahlung_langwellig_NORD * Flux_Feuchte_OST * Flux_Regen_auftreffend_OST * Flux_Regen_eindringend_OST * FluxInt_Regen_auftreffend_OST * Flux_Strahlung_kurzwellig_OST * FluxInt_Strahlung_kurzwellig_OST * Flux_Strahlung_langwellig_OST * FluxInt_Strahlung_langwellig_OST * Flux_Feuchte_SÜD * Flux_Regen_auftreffend_SÜD * Flux_Regen_eindringend_SÜD * FluxInt_Regen_auftreffend_SÜD * Flux_Strahlung_kurzwellig_SÜD * FluxInt_Strahlung_kurzwellig_SÜD * Flux_Strahlung_langwellig_SÜD * FluxInt_Strahlung_langwellig_SÜD * Flux_Feuchte_WEST * Flux_Regen_auftreffend_WEST * Flux_Regen_eindringend_WEST * FluxInt_Regen_auftreffend_WEST * Flux_Strahlung_kurzwellig_WEST * FluxInt_Strahlung_kurzwellig_WEST * Flux_Strahlung_langwellig_WEST * FluxInt_Strahlung_langwellig_WEST * TemperaturSensor * RHSensor 2 output grids (of 2) used: * Jahresende * Stündlich Creating default initial conditions Default initial temperature = 20 degC Default initial relative humidity = 80 % Creating definitions for assessments/reports Creating interface definitions for engineering models Interface 'Wand - Nord' [EngineeringOutdoor] transformed to detailed model Interface 'Wand - Ost' [EngineeringOutdoor] transformed to detailed model Interface 'Wand - Sued' [EngineeringOutdoor] transformed to detailed model Interface 'Wand - West' [EngineeringOutdoor] transformed to detailed model Interface 'Dach - horizontal' [EngineeringOutdoor] transformed to detailed model Interface 'Innenseite, Wand' [EngineeringIndoor] transformed to detailed model Interface 'Innenseite, Dach' [EngineeringIndoor] transformed to detailed model Reading material data files Reading material file 'Altbauziegel Dresden ZE.m6'. Reading material file 'Levelling Plaster.m6'. Reading material file 'Calsitherm KP Glue Mortar.m6'. Reading material file 'Calsitherm Climate Board WF.m6'. Reading material file 'Calsitherm KP Lime Plaster.m6'. Reading material file 'Bitumen.m6'. Reading material file 'Spruce_radial (from Saxony) mue= 50 lbd_dry=0,1.m6'. Reading material file 'Mineral Wool 035.m6'. Reading material file 'Gypsum Board.m6'. Reading climate data files and initializing calculation Using longitude 8.58 Deg from weather data file. Using latitude 53.53 Deg from weather data file. Using height 7 m from weather data file. Using timezone 1 UTC from weather data file. Connecting Definitions Module Setup Selecting standard flux modules: FluxHeatConduction FluxLiquidConvection FluxMoistureEnthalpy FluxVaporDiffusion Selecting standard boundary flux modules: BCFluxHeatConduction BCFluxLongWaveRadiation BCFluxMoistureEnthalpy BCFluxRain BCFluxRainEnthalpy BCFluxShortWaveRadiation BCFluxVaporDiffusion Instantiating flux modules [BCFluxHeatConduction] Boundary Condition: Heat Conduction Flux (IBK) [BCFluxLongWaveRadiation] Boundary Condition: Long Wave Radiation Flux (IBK) [BCFluxRain] Boundary Condition: Rain Flux (IBK) [BCFluxShortWaveRadiation] Boundary Condition: Short Wave Radiation Flux (IBK) [BCFluxVaporDiffusion] Boundary Condition: Vapor Diffusion Flux (IBK) [FluxHeatConduction] Heat Conduction Flux (IBK) [FluxLiquidConvection] Liquid Convection Flux (IBK) [FluxVaporDiffusion] Vapor Diffusion Flux (IBK) [BCFluxMoistureEnthalpy] Boundary Condition: Enthalpy flux for liquid convection and vapor diffusion (IBK) [BCFluxRainEnthalpy] Boundary Condition: Rain Flux (IBK) [FluxMoistureEnthalpy] Enthalpy flux for liquid convection and vapor diffusion (IBK) Creating auxiliary model data Initializing quantities 34 States 7 Internal Fluxes 16 Boundary Condition Fluxes 2 Sources Discretization and Grid Generation Grid width (x-dim, radius) = 1.882 m Grid height (y-dim, height) = 1 m Grid depth (z-dimension) = 1 m Assigning materials '' [Calsitherm Climate Board WF.m6] '' [Calsitherm KP Glue Mortar.m6] '' [Spruce_radial (from Saxony) mue= 50 lbd_dry=0,1.m6] 'Bitumen' [Bitumen.m6] 'Calsitherm KP Lime Plaster' [Calsitherm KP Lime Plaster.m6] 'Gypsum Board' [Gypsum Board.m6] 'Levelling Plaster' [Levelling Plaster.m6] 'Mineral Wool 035' [Mineral Wool 035.m6] 'Old Building Brick Dresden ZE' [Altbauziegel Dresden ZE.m6] Assigning Initial Conditions 'Default initial relative humidity' [RelativeHumidity] assigned to [0, 0, 0] - [257, 0, 0] 'Default initial temperature' [Temperature] assigned to [0, 0, 0] - [257, 0, 0] Assigning field conditions Grid numbering: Starting new domain after 52 nodes. Starting new domain after 104 nodes. Starting new domain after 156 nodes. Starting new domain after 208 nodes. Optimizing numbering in domain #1. Domain element range: 0..51, size = 52 Numbering Order: col, stack, row [IKJ] (loop order) Optimizing CMK numbering starting from node: 0 -> hbw = 1 51 -> hbw = 1 Optimizing numbering in domain #2. Domain element range: 52..103, size = 52 Numbering Order: col, stack, row [IKJ] (loop order) Optimizing CMK numbering starting from node: 52 -> hbw = 1 103 -> hbw = 1 Optimizing numbering in domain #3. Domain element range: 104..155, size = 52 Numbering Order: col, stack, row [IKJ] (loop order) Optimizing CMK numbering starting from node: 104 -> hbw = 1 155 -> hbw = 1 Optimizing numbering in domain #4. Domain element range: 156..207, size = 52 Numbering Order: col, stack, row [IKJ] (loop order) Optimizing CMK numbering starting from node: 156 -> hbw = 1 207 -> hbw = 1 Optimizing numbering in domain #5. Domain element range: 208..249, size = 42 Numbering Order: col, stack, row [IKJ] (loop order) Optimizing CMK numbering starting from node: 208 -> hbw = 1 249 -> hbw = 1 CMK (optimized) - max. half bandwidth: 1 Total elements count : 258 Used elements count : 250 Assigning interfaces Assigning contact conditions Removing unused sides Assigning output file definitions for horizontal sides. Assigning interfaces 'Wand - Nord' assigned to [0, 0, 0] - [0, 0, 0] Left 'Wand - Ost' assigned to [54, 0, 0] - [54, 0, 0] Left 'Wand - Sued' assigned to [108, 0, 0] - [108, 0, 0] Left 'Wand - West' assigned to [162, 0, 0] - [162, 0, 0] Left 'Dach - horizontal' assigned to [216, 0, 0] - [216, 0, 0] Left 'Innenseite, Wand' assigned to [51, 0, 0] - [51, 0, 0] Right 'Innenseite, Wand' assigned to [105, 0, 0] - [105, 0, 0] Right 'Innenseite, Wand' assigned to [159, 0, 0] - [159, 0, 0] Right 'Innenseite, Wand' assigned to [213, 0, 0] - [213, 0, 0] Right 'Innenseite, Dach' assigned to [257, 0, 0] - [257, 0, 0] Right Assigning contact conditions 'SIGA Majrex' assigned to [248, 0, 0] - [248, 0, 0] Left 'Unterdachbahn Tyvek' assigned to [230, 0, 0] - [230, 0, 0] Left Removing unused sides Assigning output file definitions for vertical sides. Assigning interfaces Assigning contact conditions Removing unused sides Assigning output file definitions for frontal sides. Total side count : 1291 Reduced side count : 255 Creating Element -> Side links Computing weight-factors for boundary value extrapolation Volumes/areas for used material references: Material Area [m2] ------------------------------------------------------------ Altbauziegel Dresden ZE 0.960001 Levelling Plaster 0.04 Calsitherm KP Glue Mortar 0.032 Calsitherm Climate Board WF 0.24 Calsitherm KP Lime Plaster 0.016 Bitumen 0.004 Spruce_radial (from Saxony) mue= 50 lbd_dry=0,1 0.025 Mineral Wool 035 0.14 Gypsum Board 0.025 Grid complete. Elements : 250 Sides (total/internal/boundary) : 255/245/10 Half-Bandwidth (element-based) : 1 Checking field conditions Initializing data storage vectors (memory allocation) Creating/opening output files Output definition 'Flux_Feuchte_DACH' is only assigned to boundary sides, therefore boundary flux sign convention is used. Output definition 'Flux_Regen_auftreffend_DACH' is only assigned to boundary sides, therefore boundary flux sign convention is used. Output definition 'Flux_Regen_eindringend_DACH' is only assigned to boundary sides, therefore boundary flux sign convention is used. Output definition 'FluxInt_Regen_auftreffend_DACH' is only assigned to boundary sides, therefore boundary flux sign convention is used. Output definition 'Flux_Strahlung_kurzwellig_DACH' is only assigned to boundary sides, therefore boundary flux sign convention is used. Output definition 'FluxInt_Strahlung_kurzwellig_DACH' is only assigned to boundary sides, therefore boundary flux sign convention is used. Output definition 'Flux_Strahlung_langwellig_DACH' is only assigned to boundary sides, therefore boundary flux sign convention is used. Output definition 'FluxInt_Strahlung_langwellig_DACH' is only assigned to boundary sides, therefore boundary flux sign convention is used. Output definition 'Flux_Feuchte_NORD' is only assigned to boundary sides, therefore boundary flux sign convention is used. Output definition 'Flux_Regen_auftreffend_NORD' is only assigned to boundary sides, therefore boundary flux sign convention is used. Output definition 'Flux_Regen_eindringend_NORD' is only assigned to boundary sides, therefore boundary flux sign convention is used. Output definition 'FluxInt_Regen_auftreffend_NORD' is only assigned to boundary sides, therefore boundary flux sign convention is used. Output definition 'Flux_Strahlung_kurzwellig_NORD' is only assigned to boundary sides, therefore boundary flux sign convention is used. Output definition 'FluxInt_Strahlung_kurzwellig_NORD' is only assigned to boundary sides, therefore boundary flux sign convention is used. Output definition 'Flux_Strahlung_langwellig_NORD' is only assigned to boundary sides, therefore boundary flux sign convention is used. Output definition 'FluxInt_Strahlung_langwellig_NORD' is only assigned to boundary sides, therefore boundary flux sign convention is used. Output definition 'Flux_Feuchte_OST' is only assigned to boundary sides, therefore boundary flux sign convention is used. Output definition 'Flux_Regen_auftreffend_OST' is only assigned to boundary sides, therefore boundary flux sign convention is used. Output definition 'Flux_Regen_eindringend_OST' is only assigned to boundary sides, therefore boundary flux sign convention is used. Output definition 'FluxInt_Regen_auftreffend_OST' is only assigned to boundary sides, therefore boundary flux sign convention is used. Output definition 'Flux_Strahlung_kurzwellig_OST' is only assigned to boundary sides, therefore boundary flux sign convention is used. Output definition 'FluxInt_Strahlung_kurzwellig_OST' is only assigned to boundary sides, therefore boundary flux sign convention is used. Output definition 'Flux_Strahlung_langwellig_OST' is only assigned to boundary sides, therefore boundary flux sign convention is used. Output definition 'FluxInt_Strahlung_langwellig_OST' is only assigned to boundary sides, therefore boundary flux sign convention is used. Output definition 'Flux_Feuchte_SÜD' is only assigned to boundary sides, therefore boundary flux sign convention is used. Output definition 'Flux_Regen_auftreffend_SÜD' is only assigned to boundary sides, therefore boundary flux sign convention is used. Output definition 'Flux_Regen_eindringend_SÜD' is only assigned to boundary sides, therefore boundary flux sign convention is used. Output definition 'FluxInt_Regen_auftreffend_SÜD' is only assigned to boundary sides, therefore boundary flux sign convention is used. Output definition 'Flux_Strahlung_kurzwellig_SÜD' is only assigned to boundary sides, therefore boundary flux sign convention is used. Output definition 'FluxInt_Strahlung_kurzwellig_SÜD' is only assigned to boundary sides, therefore boundary flux sign convention is used. Output definition 'Flux_Strahlung_langwellig_SÜD' is only assigned to boundary sides, therefore boundary flux sign convention is used. Output definition 'FluxInt_Strahlung_langwellig_SÜD' is only assigned to boundary sides, therefore boundary flux sign convention is used. Output definition 'Flux_Feuchte_WEST' is only assigned to boundary sides, therefore boundary flux sign convention is used. Output definition 'Flux_Regen_auftreffend_WEST' is only assigned to boundary sides, therefore boundary flux sign convention is used. Output definition 'Flux_Regen_eindringend_WEST' is only assigned to boundary sides, therefore boundary flux sign convention is used. Output definition 'FluxInt_Regen_auftreffend_WEST' is only assigned to boundary sides, therefore boundary flux sign convention is used. Output definition 'Flux_Strahlung_kurzwellig_WEST' is only assigned to boundary sides, therefore boundary flux sign convention is used. Output definition 'FluxInt_Strahlung_kurzwellig_WEST' is only assigned to boundary sides, therefore boundary flux sign convention is used. Output definition 'Flux_Strahlung_langwellig_WEST' is only assigned to boundary sides, therefore boundary flux sign convention is used. Output definition 'FluxInt_Strahlung_langwellig_WEST' is only assigned to boundary sides, therefore boundary flux sign convention is used. Enabling computation of integral/min/max outputs because of output file 'Realklima/RealKlima/results/FluxInt_Regen_auftreffend_DACH.d6o'. Note: this requires some additional computation after each step. Composing initial condition vector Input value checks Checking modules for runtime exceptions before starting calculation. Checking sources for runtime exceptions before starting calculation. Checking flux modules for runtime exceptions before starting calculation. Initialization Model Interface Creating Linear Equation Solver Modules Number of unknowns : 500 Element-based half-Bandwidth : 1 Using generic Band solver with bandwidth 7! Creating Integrator Using CVODE integrator. Model initialization complete. Creating solver framework Initializing CVODE integrator Setting NonlinConvCoef to 0.1. Setting MaxNonLinIters (maxcor) to 3. Initializing LES solver implementation Stopping after successful initialization of integrator. DELPHIN 6 Solver All rights reserved. The DELPHIN 6 Development Team: Andreas Nicolai, Stefan Vogelsang, Anne Paepcke, Heiko Fechner, John Grunewald Contact: andreas.nicolai [at] tu-dresden.de Compiled with GCC 9.4.0 Delphin model and file format library version 6.1.8 Material model and file format library version 6.1.1 IBK library version 5.0.0 DATAIO library version 7.1.4 CCM library version 1.1.0 JADE library version 1.3.1 JAC library version 1.6.0 Salt library version 1.0.0 Pollutant library version 1.3.0 Integrator Framework Version 1.0.0 SUNDIALS Release Version 2.7.0 Project file: 'VOC/EmissionTest_BP1_Hexanal_h0.5.d6p' Output root dir: 'VOC/EmissionTest_BP1_Hexanal_h0.5' Reading project file : EmissionTest_BP1_Hexanal_h0.5.d6p Project read successfully. Initializing model Initializing Solver Parameter Automatically setting NonLinSolverConvCoeff to 0.1, so that product of reltol and factor is 1e-6. Instantiating Balance Equation Module: 'Pollutant Balance Equation (IBK)' [BEPollutant] Checking assignments for valid ranges Removed unused definitions from project 2 materials (of 2) used: * Particle board [348] * Air gap 50 mm (vertical) [18] 0 interface definitions (of 0) used: 1 initial conditions (of 1) used: * Initial VOC concentration 1 field conditions (of 1) used: * Air change of chamber 1 contact conditions (of 1) used: * VOC mass transfer between material and air 0 boundary conditions (of 0) used: 0 climate conditions (of 0) used: 4 output file definition (of 4) used: * VOC concentration chamber * VOC Permeability * VOC concentration profile (gas) * Emission flux 2 output grids (of 2) used: * Fields and Profiles * Scalars Creating default initial conditions Default initial temperature = 20 degC Default initial relative humidity = 80 % Creating definitions for assessments/reports Creating interface definitions for engineering models Reading material data files Reading material file 'SpanplatteV100E1F0_348.m6'. Reading material file 'AirGapVertical50mm_18.m6'. Setting up pollutant module Reading pollutant database '${Project Directory}/DB_Pollutants/voc_db_tests.vdb'. VOC database read with 2 VOCs, 1 materials Reading climate data files and initializing calculation Connecting Definitions Auto-generating CC 'Temperature' for constant value: 20 C, referenced from FC 'Air change of chamber' Auto-generating CC 'RelativeHumidity' for constant value: 50 %, referenced from FC 'Air change of chamber' Auto-generating CC 'VOCDensity' for constant value: 0 µg/m3, referenced from FC 'Air change of chamber' Auto-generating CC 'FluidChangeRate' for constant value: 1 1/h, referenced from FC 'Air change of chamber' Module Setup Selecting standard flux modules: FluxVOCDiffusion No boundary conditions parameterized. Instantiating flux modules [FluxVOCDiffusion] VOC/Pollutant Diffusion Flux (IBK) Selecting standard source modules: AirChange Instantiating source modules [SourceAirChange] Air exchange between an air filled cavity and outside air Creating auxiliary model data Initializing quantities 5 States 3 Internal Fluxes 2 Boundary Condition Fluxes 5 Sources Discretization and Grid Generation Grid width (x-dim, radius) = 1.1125 m Grid height (y-dim, height) = 1 m Grid depth (z-dimension) = 1 m Assigning materials 'Air gap 50 mm (vertical)' [AirGapVertical50mm_18.m6] 'Particle board' [SpanplatteV100E1F0_348.m6] Assigning Initial Conditions 'Default initial relative humidity' [RelativeHumidity] assigned to [0, 0, 0] - [159, 0, 0] 'Default initial temperature' [Temperature] assigned to [0, 0, 0] - [159, 0, 0] 'Initial VOC concentration' [VOCMass] assigned to [0, 0, 0] - [158, 0, 0] Assigning field conditions 'Air change of chamber' [AirChange] assigned to [159, 0, 0] - [159, 0, 0] Grid numbering: Optimizing numbering in domain #1. Domain element range: 0..159, size = 160 Numbering Order: col, stack, row [IKJ] (loop order) Optimizing CMK numbering starting from node: 0 -> hbw = 1 159 -> hbw = 1 CMK (optimized) - max. half bandwidth: 1 Total elements count : 160 Used elements count : 160  No interfaces assigned, construction is tight/adiabatic at all boundaries.  Assigning contact conditions Removing unused sides Assigning output file definitions for horizontal sides.  No interfaces assigned, construction is tight/adiabatic at all boundaries.  Assigning contact conditions 'VOC mass transfer between material and air' assigned to [158, 0, 0] - [158, 0, 0] Right Removing unused sides Assigning output file definitions for vertical sides.  No interfaces assigned, construction is tight/adiabatic at all boundaries.  Assigning contact conditions Removing unused sides Assigning output file definitions for frontal sides. Total side count : 801 Reduced side count : 159 Creating Element -> Side links Computing weight-factors for boundary value extrapolation Volumes/areas for used material references: Material Area [m2] ------------------------------------------------------------ Particle board [348] 0.0159 Air gap 50 mm (vertical) [18] 1.0966 Volumes/areas for assigned field conditions: Field Condition Area [m2] ------------------------------------------------------------ Air change of chamber 1.0966 Grid complete. Elements : 160 Sides (total/internal/boundary) : 159/159/0 Half-Bandwidth (element-based) : 1 Checking field conditions Initializing data storage vectors (memory allocation) Creating/opening output files  Boundary flux with ID name 'FluxVOCDiffusion' is not being generated with current set of selected modules. Output flux, if requested, will be always 0.  Output definition 'Emission flux' is assigned to at least one internal side, therefore field flux sign convention is used. Composing initial condition vector Input value checks Checking modules for runtime exceptions before starting calculation. Checking sources for runtime exceptions before starting calculation. Checking flux modules for runtime exceptions before starting calculation. Initialization Model Interface Creating Linear Equation Solver Modules Number of unknowns : 320 Element-based half-Bandwidth : 1 Using generic Band solver with bandwidth 7! Creating Integrator Using CVODE integrator. Model initialization complete. Creating solver framework Initializing CVODE integrator Setting NonlinConvCoef to 0.1. Setting MaxNonLinIters (maxcor) to 3. Initializing LES solver implementation Stopping after successful initialization of integrator. Enabling colored console output Compiler ID : gcc_linux Test suite : ./ Solver : ../../bin/release/DelphinSolver Project file extension : d6p Number of projects : 11 ./DIN_EN_15026-2007/DIN EN 15026 - 2007.d6p ./EN_ISO_10211/DIN EN ISO 10211 Case1.d6p ./EN_ISO_10211/DIN EN ISO 10211 Case2.d6p ./HamstadBenchmarks/HamstadBenchmark1.d6p ./HamstadBenchmarks/HamstadBenchmark2.d6p ./HamstadBenchmarks/HamstadBenchmark3.d6p ./HamstadBenchmarks/HamstadBenchmark4.d6p ./HamstadBenchmarks/HamstadBenchmark5.d6p ./Ice/FreezingBrickWall_1D.d6p ./Realklima/RealKlima.d6p ./VOC/EmissionTest_BP1_Hexanal_h0.5.d6p Successful projects: Project path Wall clock time [s] *** Success *** Finished: SUCCESS