Functions | Variables
readThermalProperties.H File Reference

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Functions

IOobject CIO ("C", runTime.timeName(0), mesh, IOobject::NO_READ, IOobject::NO_WRITE)
 
const dictionary & CDict (thermalProperties.subDict("C"))
 
word CType (CDict.lookup("type"))
 
 if (CType=="uniform")
 
IOobject rhoKIO ("k", runTime.timeName(0), mesh, IOobject::NO_READ, IOobject::NO_WRITE)
 
const dictionary & kDict (thermalProperties.subDict("k"))
 
word kType (kDict.lookup("type"))
 
 if (kType=="uniform")
 
IOobject alphaIO ("alpha", runTime.timeName(0), mesh, IOobject::NO_READ, IOobject::NO_WRITE)
 
const dictionary & alphaDict (thermalProperties.subDict("alpha"))
 
word alphaType (alphaDict.lookup("type"))
 
 if (alphaType=="uniform")
 

Variables

Info<< "Reading thermal properties\n"<< endl;IOdictionary thermalProperties(IOobject("thermalProperties", runTime.constant(), mesh, IOobject::MUST_READ_IF_MODIFIED, IOobject::NO_WRITE));Switch thermalStress(thermalProperties.lookup("thermalStress"));volScalarField threeKalpha(IOobject("threeKalpha", runTime.timeName(), mesh, IOobject::NO_READ, IOobject::NO_WRITE), mesh, dimensionedScalar("0", dimensionSet(0, 2,-2,-1, 0), 0.0));volScalarField DT(IOobject("DT", runTime.timeName(), mesh, IOobject::NO_READ, IOobject::NO_WRITE), mesh, dimensionedScalar("0", dimensionSet(0, 2,-1, 0, 0), 0.0));if(thermalStress){autoPtr< volScalarField > CPtr
 
 else
 
volScalarField & C = CPtr()
 
autoPtr< volScalarField > rhoKPtr
 
volScalarField & rhoK = rhoKPtr()
 
autoPtr< volScalarField > alphaPtr
 
volScalarField & alpha = alphaPtr()
 Fine-structure constant: default SI units: []. More...
 

Function Documentation

IOobject CIO ( "C"  ,
runTime.  timeName0,
mesh  ,
IOobject::NO_READ  ,
IOobject::NO_WRITE   
)

Referenced by if().

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const dictionary& CDict ( thermalProperties.  subDict"C")

Referenced by if().

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word CType ( CDict.  lookup"type")

Referenced by if().

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else if ( CType  = = "uniform")

Definition at line 63 of file readThermalProperties.H.

References CDict(), CIO(), CType(), mesh, and readScalar.

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IOobject rhoKIO ( "k"  ,
runTime.  timeName0,
mesh  ,
IOobject::NO_READ  ,
IOobject::NO_WRITE   
)

Referenced by if().

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const dictionary& kDict ( thermalProperties.  subDict"k")

Referenced by if().

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word kType ( kDict.  lookup"type")

Referenced by if().

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else if ( kType  = = "uniform")

Definition at line 121 of file readThermalProperties.H.

References Foam::abort(), Foam::FatalError, FatalErrorIn, kDict(), kType(), mesh, readScalar, and rhoKIO().

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IOobject alphaIO ( "alpha"  ,
runTime.  timeName0,
mesh  ,
IOobject::NO_READ  ,
IOobject::NO_WRITE   
)

Referenced by if().

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const dictionary& alphaDict ( thermalProperties.  subDict"alpha")

Referenced by if().

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word alphaType ( alphaDict.  lookup"type")

Referenced by if().

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else if ( alphaType  = = "uniform")

Definition at line 181 of file readThermalProperties.H.

References Foam::abort(), alphaDict(), alphaIO(), alphaType(), Foam::dimTemperature, Foam::FatalError, FatalErrorIn, Foam::inv(), mesh, and readScalar.

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Variable Documentation

Info<< "Reading thermal properties\n" << endl;IOdictionary thermalProperties( IOobject ( "thermalProperties", runTime.constant(), mesh, IOobject::MUST_READ_IF_MODIFIED, IOobject::NO_WRITE ));Switch thermalStress(thermalProperties.lookup("thermalStress"));volScalarField threeKalpha( IOobject ( "threeKalpha", runTime.timeName(), mesh, IOobject::NO_READ, IOobject::NO_WRITE ), mesh, dimensionedScalar("0", dimensionSet(0, 2, -2 , -1, 0), 0.0));volScalarField DT( IOobject ( "DT", runTime.timeName(), mesh, IOobject::NO_READ, IOobject::NO_WRITE ), mesh, dimensionedScalar("0", dimensionSet(0, 2, -1 , 0, 0), 0.0));if (thermalStress){ autoPtr<volScalarField> CPtr

Definition at line 50 of file readThermalProperties.H.

else
Initial value:
{
(
"readThermalProperties.H"
) << "Valid type entries are uniform or field for C"
errorManip< error > abort(error &err)
Definition: errorManip.H:131
#define FatalErrorIn(functionName)
Report an error message using Foam::FatalError.
Definition: error.H:314
error FatalError

Definition at line 98 of file readThermalProperties.H.

volScalarField& C = CPtr()
autoPtr<volScalarField> rhoKPtr

Definition at line 108 of file readThermalProperties.H.

volScalarField& rhoK = rhoKPtr()

Definition at line 164 of file readThermalProperties.H.

autoPtr<volScalarField> alphaPtr

Definition at line 166 of file readThermalProperties.H.

Referenced by regionSizeDistribution::write().

volScalarField& alpha = alphaPtr()

Fine-structure constant: default SI units: [].

Definition at line 222 of file readThermalProperties.H.

Referenced by KinematicCloud< CloudType >::alpha(), BrownianMotionForce< CloudType >::calcCoupled(), fieldAverage::calculateMeanFieldType(), fieldAverage::calculatePrime2MeanFieldType(), pointMVCWeight::calcWeights(), equilibrium::clone(), isotropic::clone(), nonEquilibrium::clone(), exponential::clone(), Lun::clone(), TrajectoryCollision< CloudType >::collideParcels(), contactAngleForce::correct(), thixotropicViscosity::correct(), solidification::correctModel(), SpalartAllmarasIDDES< BasicTurbulenceModel >::dTilda(), fvMatrix< Type >::faceFluxCorrectionPtr(), forAll(), forAllIter(), MPPICCloud< CloudType >::info(), Analytical< Type >::integrate(), triangleFuncs::intersectAxesBundle(), steadyStateDdtScheme< Type >::mesh(), EulerDdtScheme< Type >::mesh(), boundedDdtScheme< Type >::mesh(), backwardDdtScheme< Type >::mesh(), CoEulerDdtScheme< Type >::mesh(), SLTSDdtScheme< Type >::mesh(), ddtScheme< Type >::mesh(), localEulerDdtScheme< Type >::mesh(), RASModel< BasicTurbulenceModel >::New(), LESModel< BasicTurbulenceModel >::New(), CrankNicolsonDdtScheme< Type >::ocCoeff(), ListPlusEqOp< T, Size >::operator()(), option::iNew::operator()(), KinematicCloud< CloudType >::penetration(), ParticleErosion< CloudType >::postPatch(), ParticleTrap< CloudType >::preEvolve(), fvMatrix< Type >::relax(), general::sample(), ConeInjection< CloudType >::setProperties(), ConeNozzleInjection< CloudType >::setProperties(), primaryRadiation::Shs(), standardRadiation::Shs(), constantRadiation::Shs(), PCICG< Type, DType, LUType >::solve(), PBiCICG< Type, DType, LUType >::solve(), PBiCCCG< Type, DType, LUType >::solve(), PCG::solve(), PBiCG::solve(), thermalBaffle::solveEnergy(), reactingOneDim::solveEnergy(), ThermoSurfaceFilm< CloudType >::splashDirection(), TurbulenceModel< Alpha, Rho, BasicTurbulenceModel, TransportModel >::TurbulenceModel(), filmPyrolysisRadiativeCoupledMixedFvPatchScalarField::updateCoeffs(), advectiveFvPatchField< Type >::updateCoeffs(), thermalBaffle1DFvPatchScalarField< solidType >::updateCoeffs(), Explicit< CloudType >::velocityCorrection(), while(), FacePostProcessing< CloudType >::write(), ParticleCollector< CloudType >::write(), PengRobinsonGas< Specie >::Z(), explicitPorositySource::~explicitPorositySource(), HarrisCrighton::~HarrisCrighton(), and optionList::~optionList().