/*--------------------------------*- C++ -*----------------------------------*\ | ========= | | | \\ / F ield | OpenFOAM: The Open Source CFD Toolbox | | \\ / O peration | Version: 1.5 | | \\ / A nd | Web: http://www.OpenFOAM.org | | \\/ M anipulation | | \*---------------------------------------------------------------------------*/ FoamFile { version 2.0; format ascii; class dictionary; object changeDictionaryDict; } // * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * // dictionaryReplacement { boundary { topAir_to_leftSolid { offset ( 0 0 0 ); sampleMode nearestPatchFace; sampleRegion leftSolid; samplePatch leftSolid_to_topAir; } topAir_to_heater { offset ( 0 0 0 ); sampleMode nearestPatchFace; sampleRegion heater; samplePatch heater_to_topAir; } topAir_to_rightSolid { offset ( 0 0 0 ); sampleMode nearestPatchFace; sampleRegion rightSolid; samplePatch rightSolid_to_topAir; } } U { internalField uniform ( 0.01 0 0 ); boundaryField { minX { type fixedValue; value uniform (0.01 0 0); } maxX { type inletOutlet; inletValue uniform (0 0 0); } maxY { type fixedValue; value uniform (0 0 0); } minZ { type fixedValue; value uniform (0 0 0); } maxZ { type fixedValue; value uniform (0 0 0); } topAir_to_leftSolid { type fixedValue; value uniform (0 0 0); } topAir_to_heater { type fixedValue; value uniform (0 0 0); } topAir_to_rightSolid { type fixedValue; value uniform (0 0 0); } } } T { internalField uniform 300; boundaryField { maxY { type fixedValue; value uniform 300; } minX { type fixedValue; value uniform 300; } maxX { type fixedValue; value uniform 300; } minZ { type fixedValue; value uniform 300; } maxZ { type fixedValue; value uniform 300; } topAir_to_leftSolid { type solidWallMixedTemperatureCoupled; neighbourFieldName T; K K; value uniform 300; } topAir_to_heater { type solidWallMixedTemperatureCoupled; neighbourFieldName T; K K; value uniform 300; } topAir_to_rightSolid { type solidWallMixedTemperatureCoupled; neighbourFieldName T; K K; value uniform 300; } } } epsilon { // Set the value on all bc to non-zero. Not used in simulation // since zeroGradient; only used in initialisation. boundaryField { minX { type fixedValue; value uniform 0.01; } maxX { type zeroGradient; value uniform 0.01; } minY { type zeroGradient; value uniform 0.01; } maxY { type zeroGradient; value uniform 0.01; } minZ { type zeroGradient; value uniform 0.01; } maxZ { type zeroGradient; value uniform 0.01; } topAir_to_leftSolid { type zeroGradient; value uniform 0.01; } topAir_to_heater { type zeroGradient; value uniform 0.01; } topAir_to_rightSolid { type zeroGradient; value uniform 0.01; } } } k { internalField uniform 0.1; boundaryField { minX { type fixedValue; value uniform 0.1; } maxX { type zeroGradient; value uniform 0.1; } maxY { type zeroGradient; value uniform 0.1; } minZ { type zeroGradient; value uniform 0.1; } maxZ { type zeroGradient; value uniform 0.1; } topAir_to_leftSolid { type zeroGradient; value uniform 0.1; } topAir_to_heater { type zeroGradient; value uniform 0.1; } topAir_to_rightSolid { type zeroGradient; value uniform 0.1; } } } p { internalField uniform 1E5; boundaryField { minX { type buoyantPressure; value 1e5; } maxX { type waveTransmissive; //field p; phi phi; rho rho; psi psi; gamma 1.4; // cp/cv fieldInf 1e5; lInf 0.40; // double length of domain value uniform 1e5; } maxY { type buoyantPressure; value 1e5; } minZ { type buoyantPressure; value 1e5; } maxZ { type buoyantPressure; value 1e5; } topAir_to_leftSolid { type buoyantPressure; value 1e5; } topAir_to_heater { type buoyantPressure; value 1e5; } topAir_to_rightSolid { type buoyantPressure; value 1e5; } } } } // ************************************************************************* //