void Foam::calcTypes::scalarMult::preCalc
(
    const argList& args,
    const Time& runTime,
    const fvMesh& mesh
)
{
    baseFieldName_ = args.additionalArgs()[1];

    if (args.optionFound("value"))
    {
        scalarMultValueStr_ = args.option("value");
    }
    else
    {
        FatalErrorIn("calcTypes::scalarMult::preCalc")
            << "scalarMult requires -value option"
            << nl << exit(FatalError);
    }

    if (args.optionFound("resultName"))
    {
        resultName_ = args.option("resultName");
    }
}
Exemplo n.º 2
0
void Foam::calc(const argList& args, const Time& runTime, const fvMesh& mesh)
{
    bool writeResults = !args.optionFound("noWrite");

    IOobject Uheader
    (
        "U",
        runTime.timeName(),
        mesh,
        IOobject::MUST_READ
    );

    if (Uheader.headerOk())
    {
        Info<< "    Reading U" << endl;
        volVectorField U(Uheader, mesh);

        Info<< "    Calculating vorticity" << endl;
        volVectorField vorticity
        (
            IOobject
            (
                "vorticity",
                runTime.timeName(),
                mesh,
                IOobject::NO_READ
            ),
            fvc::curl(U)
        );

        volScalarField magVorticity
        (
            IOobject
            (
                "magVorticity",
                runTime.timeName(),
                mesh,
                IOobject::NO_READ
            ),
            mag(vorticity)
        );

        Info<< "vorticity max/min : "
            << max(magVorticity).value() << " "
            << min(magVorticity).value() << endl;

        if (writeResults)
        {
            vorticity.write();
            magVorticity.write();
        }
    }
    else
    {
        Info<< "    No U" << endl;
    }

    Info<< "\nEnd\n" << endl;
}
void Foam::calc(const argList& args, const Time& runTime, const fvMesh& mesh)
{
    bool writeResults = !args.optionFound("noWrite");

    #include "getFields.H"

    Info<< "\nEnd\n" << endl;
}
Exemplo n.º 4
0
void Foam::calc(const argList& args, const Time& runTime, const fvMesh& mesh)
{
    bool writeResults = !args.optionFound("noWrite");

    IOobject kheader
    (
        "k",
        runTime.timeName(),
        mesh,
        IOobject::MUST_READ
    );

    if (kheader.headerOk())
    {
        Info<< "    Reading k" << endl;
        volScalarField k(kheader, mesh);

        Info<< "    Calculating uprime" << endl;
        volScalarField uprime
        (
            IOobject
            (
                "uprime",
                runTime.timeName(),
                mesh,
                IOobject::NO_READ
            ),
            sqrt((2.0/3.0)*k)
        );

        Info<< "uprime max/min : "
            << max(uprime).value() << " "
            << min(uprime).value() << endl;

        if (writeResults)
        {
            uprime.write();
        }
    }
    else
    {
        Info<< "    No k" << endl;
    }

    Info<< "\nEnd\n" << endl;
}
Exemplo n.º 5
0
void Foam::calc(const argList& args, const Time& runTime, const fvMesh& mesh)
{
    bool writeResults = !args.optionFound("noWrite");

    IOobject Uheader
    (
        "U",
        runTime.timeName(),
        mesh,
        IOobject::MUST_READ
    );

    if (Uheader.headerOk())
    {
        Info<< "    Reading U" << endl;
        volVectorField U(Uheader, mesh);

        Info<< "    Calculating enstrophy" << endl;
        volScalarField enstrophy
        (
            IOobject
            (
                "enstrophy",
                runTime.timeName(),
                mesh,
                IOobject::NO_READ
            ),
            0.5*magSqr(fvc::curl(U))
        );

        Info<< "enstrophy(U) max/min : "
            << max(enstrophy).value() << " "
            << min(enstrophy).value() << endl;

        if (writeResults)
        {
            enstrophy.write();
        }
    }
    else
    {
        Info<< "    No U" << endl;
    }

    Info<< "\nEnd\n" << endl;
}
Exemplo n.º 6
0
Foam::wordList Foam::selectRegionNames(const argList& args, const Time& runTime)
{
    const bool allRegions = args.optionFound("allRegions");

    wordList regionNames;

    if (allRegions)
    {
        const regionProperties rp(runTime);
        forAllConstIter(HashTable<wordList>, rp, iter)
        {
            const wordList& regions = iter();
            forAll(regions, i)
            {
                if (findIndex(regionNames, regions[i]) == -1)
                {
                    regionNames.append(regions[i]);
                }
            }
        }
    }
    else
    {
void calc
(
    const argList& args,
    const Time& runTime,
    const fvMesh& mesh,
    functionObjectList& fol
)
{
    if (args.optionFound("noFlow"))
    {
        Info<< "    Operating in no-flow mode; no models will be loaded."
            << " All vol, surface and point fields will be loaded." << endl;

        // Read objects in time directory
        IOobjectList objects(mesh, runTime.timeName());

        // Read vol fields.

        PtrList<volScalarField> vsFlds;
        ReadFields(mesh, objects, vsFlds);

        PtrList<volVectorField> vvFlds;
        ReadFields(mesh, objects, vvFlds);

        PtrList<volSphericalTensorField> vstFlds;
        ReadFields(mesh, objects, vstFlds);

        PtrList<volSymmTensorField> vsymtFlds;
        ReadFields(mesh, objects, vsymtFlds);

        PtrList<volTensorField> vtFlds;
        ReadFields(mesh, objects, vtFlds);

        // Read surface fields.

        PtrList<surfaceScalarField> ssFlds;
        ReadFields(mesh, objects, ssFlds);

        PtrList<surfaceVectorField> svFlds;
        ReadFields(mesh, objects, svFlds);

        PtrList<surfaceSphericalTensorField> sstFlds;
        ReadFields(mesh, objects, sstFlds);

        PtrList<surfaceSymmTensorField> ssymtFlds;
        ReadFields(mesh, objects, ssymtFlds);

        PtrList<surfaceTensorField> stFlds;
        ReadFields(mesh, objects, stFlds);

        // Read point fields.
        const pointMesh& pMesh = pointMesh::New(mesh);

        PtrList<pointScalarField> psFlds;
        ReadFields(pMesh, objects, psFlds);

        PtrList<pointVectorField> pvFlds;
        ReadFields(pMesh, objects, pvFlds);

        PtrList<pointSphericalTensorField> pstFlds;
        ReadFields(pMesh, objects, pstFlds);

        PtrList<pointSymmTensorField> psymtFlds;
        ReadFields(pMesh, objects, psymtFlds);

        PtrList<pointTensorField> ptFlds;
        ReadFields(pMesh, objects, ptFlds);

        fol.execute(true);
    }
    else
    {
        Info<< "    Reading phi" << endl;
        surfaceScalarField phi
        (
            IOobject
            (
                "phi",
                runTime.timeName(),
                mesh,
                IOobject::MUST_READ
            ),
            mesh
        );

        Info<< "    Reading U" << endl;
        volVectorField U
        (
            IOobject
            (
                "U",
                runTime.timeName(),
                mesh,
                IOobject::MUST_READ
            ),
            mesh
        );

        Info<< "    Reading p" << endl;
        volScalarField p
        (
            IOobject
            (
                "p",
                runTime.timeName(),
                mesh,
                IOobject::MUST_READ
            ),
            mesh
        );

        #include "createFvOptions.H"

        if (phi.dimensions() == dimVolume/dimTime)
        {
            IOobject RASPropertiesHeader
            (
                "RASProperties",
                runTime.constant(),
                mesh,
                IOobject::MUST_READ_IF_MODIFIED,
                IOobject::NO_WRITE,
                false
            );

            IOobject LESPropertiesHeader
            (
                "LESProperties",
                runTime.constant(),
                mesh,
                IOobject::MUST_READ_IF_MODIFIED,
                IOobject::NO_WRITE,
                false
            );

            if (RASPropertiesHeader.headerOk())
            {
                IOdictionary RASProperties(RASPropertiesHeader);

                singlePhaseTransportModel laminarTransport(U, phi);

                autoPtr<incompressible::RASModel> RASModel
                (
                    incompressible::RASModel::New
                    (
                        U,
                        phi,
                        laminarTransport
                    )
                );

                fol.execute(true);
            }
            else if (LESPropertiesHeader.headerOk())
            {
                IOdictionary LESProperties(LESPropertiesHeader);

                singlePhaseTransportModel laminarTransport(U, phi);

                autoPtr<incompressible::LESModel> sgsModel
                (
                    incompressible::LESModel::New(U, phi, laminarTransport)
                );

                fol.execute(true);
            }
            else
            {
                IOdictionary transportProperties
                (
                    IOobject
                    (
                        "transportProperties",
                        runTime.constant(),
                        mesh,
                        IOobject::MUST_READ_IF_MODIFIED,
                        IOobject::NO_WRITE
                    )
                );

                fol.execute(true);
            }
        }
        else if (phi.dimensions() == dimMass/dimTime)
        {
            autoPtr<fluidThermo> thermo(fluidThermo::New(mesh));

            volScalarField rho
            (
                IOobject
                (
                    "rho",
                    runTime.timeName(),
                    mesh
                ),
                thermo->rho()
            );

            IOobject RASPropertiesHeader
            (
                "RASProperties",
                runTime.constant(),
                mesh,
                IOobject::MUST_READ_IF_MODIFIED,
                IOobject::NO_WRITE,
                false
            );

            IOobject LESPropertiesHeader
            (
                "LESProperties",
                runTime.constant(),
                mesh,
                IOobject::MUST_READ_IF_MODIFIED,
                IOobject::NO_WRITE,
                false
            );

            if (RASPropertiesHeader.headerOk())
            {
                IOdictionary RASProperties(RASPropertiesHeader);

                autoPtr<compressible::RASModel> RASModel
                (
                    compressible::RASModel::New
                    (
                        rho,
                        U,
                        phi,
                        thermo()
                    )
                );

                fol.execute(true);
            }
            else if (LESPropertiesHeader.headerOk())
            {
                IOdictionary LESProperties(LESPropertiesHeader);

                autoPtr<compressible::LESModel> sgsModel
                (
                    compressible::LESModel::New(rho, U, phi, thermo())
                );

                fol.execute(true);
            }
            else
            {
                IOdictionary transportProperties
                (
                    IOobject
                    (
                        "transportProperties",
                        runTime.constant(),
                        mesh,
                        IOobject::MUST_READ_IF_MODIFIED,
                        IOobject::NO_WRITE
                    )
                );

                fol.execute(true);
            }
        }
        else
        {
            FatalErrorIn(args.executable())
                << "Incorrect dimensions of phi: " << phi.dimensions()
                << nl << exit(FatalError);
        }
    }
}
Exemplo n.º 8
0
void Foam::calc(const argList& args, const Time& runTime, const fvMesh& mesh)
{
    bool writeResults = !args.optionFound("noWrite");

    IOobject phiHeader
    (
        "phi",
        runTime.timeName(),
        mesh,
        IOobject::MUST_READ
    );

    if (phiHeader.headerOk())
    {
        autoPtr<surfaceScalarField> PePtr;

        Info<< "    Reading phi" << endl;
        surfaceScalarField phi(phiHeader, mesh);

        volVectorField U
        (
            IOobject
            (
                "U",
                runTime.timeName(),
                mesh,
                IOobject::MUST_READ
            ),
            mesh
        );

        IOobject turbulencePropertiesHeader
        (
            "turbulenceProperties",
            runTime.constant(),
            mesh,
            IOobject::MUST_READ_IF_MODIFIED,
            IOobject::NO_WRITE
        );

        Info<< "    Calculating Pe" << endl;

        if (phi.dimensions() == dimensionSet(0, 3, -1, 0, 0))
        {
            if (turbulencePropertiesHeader.headerOk())
            {
                singlePhaseTransportModel laminarTransport(U, phi);

                autoPtr<incompressible::turbulenceModel> turbulenceModel
                (
                    incompressible::turbulenceModel::New
                    (
                        U,
                        phi,
                        laminarTransport
                    )
                );

                PePtr.set
                (
                    new surfaceScalarField
                    (
                        IOobject
                        (
                            "Pef",
                            runTime.timeName(),
                            mesh
                        ),
                        mag(phi)
                       /(
                            mesh.magSf()
                          * mesh.surfaceInterpolation::deltaCoeffs()
                          * fvc::interpolate(turbulenceModel->nuEff())
                        )
                    )
                );
            }
            else
            {
                IOdictionary transportProperties
                (
                    IOobject
                    (
                        "transportProperties",
                        runTime.constant(),
                        mesh,
                        IOobject::MUST_READ_IF_MODIFIED,
                        IOobject::NO_WRITE
                    )
                );

                dimensionedScalar nu(transportProperties.lookup("nu"));

                PePtr.set
                (
                    new surfaceScalarField
                    (
                        IOobject
                        (
                            "Pef",
                            runTime.timeName(),
                            mesh
                        ),
                        mag(phi)
                       /(
                            mesh.magSf()
                          * mesh.surfaceInterpolation::deltaCoeffs()
                          * nu
                        )
                    )
                );
            }
        }
        else if (phi.dimensions() == dimensionSet(1, 0, -1, 0, 0))
        {
            if (turbulencePropertiesHeader.headerOk())
            {
                autoPtr<fluidThermo> thermo(fluidThermo::New(mesh));

                volScalarField rho
                (
                    IOobject
                    (
                        "rho",
                        runTime.timeName(),
                        mesh
                    ),
                    thermo->rho()
                );

                autoPtr<compressible::turbulenceModel> turbulenceModel
                (
                    compressible::turbulenceModel::New
                    (
                        rho,
                        U,
                        phi,
                        thermo()
                    )
                );

                PePtr.set
                (
                    new surfaceScalarField
                    (
                        IOobject
                        (
                            "Pef",
                            runTime.timeName(),
                            mesh
                        ),
                        mag(phi)
                       /(
                            mesh.magSf()
                          * mesh.surfaceInterpolation::deltaCoeffs()
                          * fvc::interpolate(turbulenceModel->muEff())
                        )
                    )
                );
            }
            else
            {
                IOdictionary transportProperties
                (
                    IOobject
                    (
                        "transportProperties",
                        runTime.constant(),
                        mesh,
                        IOobject::MUST_READ_IF_MODIFIED,
                        IOobject::NO_WRITE
                    )
                );

                dimensionedScalar mu(transportProperties.lookup("mu"));

                PePtr.set
                (
                    new surfaceScalarField
                    (
                        IOobject
                        (
                            "Pef",
                            runTime.timeName(),
                            mesh
                        ),
                        mag(phi)
                       /(
                            mesh.magSf()
                          * mesh.surfaceInterpolation::deltaCoeffs()
                          * mu
                        )
                    )
                );
            }
        }
        else
        {
            FatalErrorInFunction
                << "Incorrect dimensions of phi: " << phi.dimensions()
                    << abort(FatalError);
        }

        Info<< "    Pe max : " << max(PePtr()).value() << endl;

        if (writeResults)
        {
            Info<< "    Writing surfaceScalarField : "
                << PePtr().name() << endl;
            PePtr().write();

            volScalarField Pe
            (
                IOobject
                (
                    "Pe",
                    runTime.timeName(),
                    mesh
                ),
                fvc::average(PePtr())
            );

            Info<< "    Writing volScalarField : "
                << Pe.name() << endl;
            Pe.write();
        }
    }
    else
    {
        Info<< "    No phi" << endl;
    }
}
Exemplo n.º 9
0
void Foam::calc(const argList& args, const Time& runTime, const fvMesh& mesh)
{
    bool writeResults = !args.optionFound("noWrite");

    IOobject Uheader
    (
        "U",
        runTime.timeName(),
        mesh,
        IOobject::MUST_READ
    );

    if (Uheader.headerOk())
    {
        Info<< "    Reading U" << endl;
        volVectorField U(Uheader, mesh);

        Info<< "    Calculating U^2" << endl;
        volVectorField U2 
        (
            IOobject
            (
                "U2",
                runTime.timeName(),
                mesh,
                IOobject::NO_READ
            ),
            mesh,
			dimensionedVector("U2",dimensionSet(0, 2, -2, 0, 0, 0, 0),vector::zero)
        );

        Info<< "    Calculating U^3" << endl;
        volVectorField U3 
        (
            IOobject
            (
                "U3",
                runTime.timeName(),
                mesh,
                IOobject::NO_READ
            ),
			mesh,
			dimensionedVector("U3",dimensionSet(0, 3, -3, 0, 0, 0, 0),vector::zero)
        );

		/* only the internal */
		//U2.internalField().replace(vector::Z, Ux.internalField());
		/* include the boundary */
/*		U2.replace(vector::X, U.component(vector::X)*U.component(vector::X));
		U2.replace(vector::Y, U.component(vector::Y)*U.component(vector::Y));
		U2.replace(vector::Z, U.component(vector::Z)*U.component(vector::Z));
*/
		U2.replace(vector::X, pow(U.component(vector::X), 2));
		U2.replace(vector::Y, pow(U.component(vector::Y), 2));
		U2.replace(vector::Z, pow(U.component(vector::Z), 2));

		U3.replace(vector::X, pow(U.component(vector::X), 3));
		U3.replace(vector::Y, pow(U.component(vector::Y), 3));
		U3.replace(vector::Z, pow(U.component(vector::Z), 3));
/*
        Info<< "vorticity max/min : "
            << max(magVorticity).value() << " "
            << min(magVorticity).value() << endl;
*/
        if (writeResults)
        {
//            vorticity.write();
//            magVorticity.write();
            U2.write();
            U3.write();
        }
    }
    else
    {
        Info<< "    No U" << endl;
    }

    Info<< "\nEnd\n" << endl;
}
Exemplo n.º 10
0
void Foam::calc(const argList& args, const Time& runTime, const fvMesh& mesh)
{
    bool writeResults = !args.optionFound("noWrite");

    IOobject Theader
    (
        "T",
        runTime.timeName(),
        mesh,
        IOobject::MUST_READ
    );

    IOobject qheader
    (
        "q",
        runTime.timeName(),
        mesh,
        IOobject::MUST_READ
    );

    IOdictionary transportProperties
    (
        IOobject
        (
            "transportProperties",
            runTime.constant(),
            mesh,
            IOobject::MUST_READ,
            IOobject::NO_WRITE
        )
    );

    dimensionedScalar Cpa
    (
         transportProperties.lookup("Cpa")
    );

    dimensionedScalar Cpv
    (
         transportProperties.lookup("Cpv")
    );

    dimensionedScalar lambda
    (
         transportProperties.lookup("lambda")
    );

    // Fluid density
    dimensionedScalar rho
    (
        transportProperties.lookup("rho")
    );


    dimensionedScalar TRef
    (
         transportProperties.lookup("TRef")
    );

    dimensionedScalar qRef
    (
         transportProperties.lookup("qRef")
    );

    if (qheader.headerOk() && Theader.headerOk())
    {
        Info<< "    Reading q" << endl;
        volScalarField q(qheader, mesh);

        Info<< "    Reading T" << endl;
        volScalarField T(Theader, mesh);

        // specific enthalpy of dry air hda - ASHRAE 1.8
        volScalarField hda("hda", rho*Cpa*T-rho*Cpa*TRef);

        // specific enthalpy of dry vapor
        volScalarField hdv("hdv", rho*q*(lambda + Cpv*T) - rho*qRef*(lambda + Cpv*TRef));


        // specific enthalpy for moist air hmoist - ASHRAE 1.8
        volScalarField hmoist("hmoist", hda + hdv);

        if (writeResults)
        {
            hda.write();
            hdv.write();
            hmoist.write();
        }
        else
        {
            Info<< "        Min hda    : " << min(hda).value() << " [J/m3]"
                << "\n        Max hda    : "<< max(hda).value() << " [J/m3]" << endl;
            Info<< "        Min hdv    : " << min(hdv).value() << " [J/m3]"
                << "\n        Max hdv    : "<< max(hdv).value() << " [J/m3]" << endl;
            Info<< "        Min hmoist : " << min(hmoist).value() << " [J/m3]"
                << "\n        Max hmoist : "<< max(hmoist).value() << " [J/m3]" << endl;
        }


        // print results
       //
      //   surfaceScalarField hdaBoundary =
      //     fvc::interpolate(hda);
       //
      //   const surfaceScalarField::GeometricBoundaryField& patchhda =
      //       hdaBoundary.boundaryField();
      //   // const surfaceScalarField::GeometricBoundaryField& patchCondHeatFlux =
      //   //     condHeatFluxNormal.boundaryField();
      //   // const surfaceScalarField::GeometricBoundaryField& patchTurbHeatFlux =
      //   //     turbHeatFluxNormal.boundaryField();
      //   // const surfaceScalarField::GeometricBoundaryField& patchTotHeatFlux =
      //   //     totHeatFluxNormal.boundaryField();
       //
      //   Info<< "\nHeat at the boundaries " << endl;
      //   forAll(patchhda, patchi)
      //   {
      //       if ( (!isA<emptyFvPatch>(mesh.boundary()[patchi])) &&
      //            (mesh.boundary()[patchi].size() > 0) )
      //       {
      //           Info<< "    "
      //               << mesh.boundary()[patchi].name()
      //               << "\n        Total area [m2]                   : "
      //               << gSum(mesh.magSf().boundaryField()[patchi])
      //               << "\n        Integral Energy [J] : "
      //               << gSum
      //                  (
      //                      mesh.magSf().boundaryField()[patchi]
      //                     *patchhda[patchi]
      //                  )
      //               << nl << endl;
      //       }
      //  }
      //  Info << endl;

    }
    else
    {
        Info<< "    No q or No T" << endl;
    }

    Info<< "\nEnd\n" << endl;
}
Exemplo n.º 11
0
void Foam::calc(const argList& args, const Time& runTime, const fvMesh& mesh)
{
    bool writeResults = !args.optionFound("noWrite");

    IOobject phiHeader
    (
        "phi",
        runTime.timeName(),
        mesh,
        IOobject::MUST_READ
    );

    if (phiHeader.headerOk())
    {
        autoPtr<surfaceScalarField> PePtr;

        Info<< "    Reading phi" << endl;
        surfaceScalarField phi(phiHeader, mesh);

        volVectorField U
        (
            IOobject
            (
                "U",
                runTime.timeName(),
                mesh,
                IOobject::MUST_READ
            ),
            mesh
        );

        IOobject RASPropertiesHeader
        (
            "RASProperties",
            runTime.constant(),
            mesh,
            IOobject::MUST_READ,
            IOobject::NO_WRITE
        );

        IOobject LESPropertiesHeader
        (
            "LESProperties",
            runTime.constant(),
            mesh,
            IOobject::MUST_READ,
            IOobject::NO_WRITE
        );

        Info<< "    Calculating Pe" << endl;

        if (phi.dimensions() == dimensionSet(0, 3, -1, 0, 0))
        {
            if (RASPropertiesHeader.headerOk())
            {
                IOdictionary RASProperties(RASPropertiesHeader);

                singlePhaseTransportModel laminarTransport(U, phi);

                autoPtr<incompressible::RASModel> RASModel
                (
                    incompressible::RASModel::New
                    (
                        U,
                        phi,
                        laminarTransport
                    )
                );

                PePtr.set
                (
                    new surfaceScalarField
                    (
                        IOobject
                        (
                            "Pe",
                            runTime.timeName(),
                            mesh,
                            IOobject::NO_READ
                        ),
                        mag(phi)
                        /(
                            mesh.magSf()
                            * mesh.surfaceInterpolation::deltaCoeffs()
                            * fvc::interpolate(RASModel->nuEff())
                        )
                    )
                );
            }
            else if (LESPropertiesHeader.headerOk())
            {
                IOdictionary LESProperties(LESPropertiesHeader);

                singlePhaseTransportModel laminarTransport(U, phi);

                autoPtr<incompressible::LESModel> sgsModel
                (
                    incompressible::LESModel::New(U, phi, laminarTransport)
                );

                PePtr.set
                (
                    new surfaceScalarField
                    (
                        IOobject
                        (
                            "Pe",
                            runTime.timeName(),
                            mesh,
                            IOobject::NO_READ
                        ),
                        mag(phi)
                        /(
                            mesh.magSf()
                            * mesh.surfaceInterpolation::deltaCoeffs()
                            * fvc::interpolate(sgsModel->nuEff())
                        )
                    )
                );
            }
            else
            {
                IOdictionary transportProperties
                (
                    IOobject
                    (
                        "transportProperties",
                        runTime.constant(),
                        mesh,
                        IOobject::MUST_READ,
                        IOobject::NO_WRITE
                    )
                );

                dimensionedScalar nu(transportProperties.lookup("nu"));

                PePtr.set
                (
                    new surfaceScalarField
                    (
                        IOobject
                        (
                            "Pe",
                            runTime.timeName(),
                            mesh,
                            IOobject::NO_READ
                        ),
                        mesh.surfaceInterpolation::deltaCoeffs()
                        * (mag(phi)/mesh.magSf())*(runTime.deltaT()/nu)
                    )
                );
            }
        }
        else if (phi.dimensions() == dimensionSet(1, 0, -1, 0, 0))
        {
            if (RASPropertiesHeader.headerOk())
            {
                IOdictionary RASProperties(RASPropertiesHeader);

                autoPtr<basicPsiThermo> thermo(basicPsiThermo::New(mesh));

                volScalarField rho
                (
                    IOobject
                    (
                        "rho",
                        runTime.timeName(),
                        mesh
                    ),
                    thermo->rho()
                );

                autoPtr<compressible::RASModel> RASModel
                (
                    compressible::RASModel::New
                    (
                        rho,
                        U,
                        phi,
                        thermo()
                    )
                );

                PePtr.set
                (
                    new surfaceScalarField
                    (
                        IOobject
                        (
                            "Pe",
                            runTime.timeName(),
                            mesh,
                            IOobject::NO_READ
                        ),
                        mag(phi)
                        /(
                            mesh.magSf()
                            * mesh.surfaceInterpolation::deltaCoeffs()
                            * fvc::interpolate(RASModel->muEff())
                        )
                    )
                );
            }
            else if (LESPropertiesHeader.headerOk())
            {
                IOdictionary LESProperties(LESPropertiesHeader);

                autoPtr<basicPsiThermo> thermo(basicPsiThermo::New(mesh));

                volScalarField rho
                (
                    IOobject
                    (
                        "rho",
                        runTime.timeName(),
                        mesh
                    ),
                    thermo->rho()
                );

                autoPtr<compressible::LESModel> sgsModel
                (
                    compressible::LESModel::New(rho, U, phi, thermo())
                );

                PePtr.set
                (
                    new surfaceScalarField
                    (
                        IOobject
                        (
                            "Pe",
                            runTime.timeName(),
                            mesh,
                            IOobject::NO_READ
                        ),
                        mag(phi)
                        /(
                            mesh.magSf()
                            * mesh.surfaceInterpolation::deltaCoeffs()
                            * fvc::interpolate(sgsModel->muEff())
                        )
                    )
                );
            }
            else
            {
                IOdictionary transportProperties
                (
                    IOobject
                    (
                        "transportProperties",
                        runTime.constant(),
                        mesh,
                        IOobject::MUST_READ,
                        IOobject::NO_WRITE
                    )
                );

                dimensionedScalar mu(transportProperties.lookup("mu"));

                PePtr.set
                (
                    new surfaceScalarField
                    (
                        IOobject
                        (
                            "Pe",
                            runTime.timeName(),
                            mesh,
                            IOobject::NO_READ
                        ),
                        mesh.surfaceInterpolation::deltaCoeffs()
                        * (mag(phi)/(mesh.magSf()))*(runTime.deltaT()/mu)
                    )
                );
            }
        }
        else
        {
            FatalErrorIn(args.executable())
                    << "Incorrect dimensions of phi: " << phi.dimensions()
                    << abort(FatalError);
        }


        // can also check how many cells exceed a particular Pe limit
        /*
        {
            label count = 0;
            label PeLimit = 200;
            forAll(PePtr(), i)
            {
                if (PePtr()[i] > PeLimit)
                {
                    count++;
                }

            }

            Info<< "Fraction > " << PeLimit << " = "
                << scalar(count)/Pe.size() << endl;
        }
        */

        Info << "Pe max : " << max(PePtr()).value() << endl;

        if (writeResults)
        {
            PePtr().write();
        }
    }
    else
    {
        Info<< "    No phi" << endl;
    }

    Info<< "\nEnd\n" << endl;
}
Exemplo n.º 12
0
void Foam::calc(const argList& args, const Time& runTime, const fvMesh& mesh)
{
    bool writeResults = !args.optionFound("noWrite");

    IOobject phiHeader
    (
        "phi",
        runTime.timeName(),
        mesh,
        IOobject::MUST_READ
    );

    if (phiHeader.headerOk())
    {
        volScalarField Co
        (
            IOobject
            (
                "Co",
                runTime.timeName(),
                mesh,
                IOobject::NO_READ
            ),
            mesh,
            dimensionedScalar("0", dimless, 0),
            zeroGradientFvPatchScalarField::typeName
        );

        Info<< "    Reading phi" << endl;
        surfaceScalarField phi(phiHeader, mesh);

        if (phi.dimensions() == dimensionSet(1, 0, -1, 0, 0))
        {
            Info<< "    Calculating compressible Co" << endl;

            Info<< "    Reading rho" << endl;
            volScalarField rho
            (
                IOobject
                (
                    "rho",
                    runTime.timeName(),
                    mesh,
                    IOobject::MUST_READ
                ),
                mesh
            );

            Co.dimensionedInternalField() =
                (0.5*runTime.deltaT())
               *fvc::surfaceSum(mag(phi))().dimensionedInternalField()
               /(rho*mesh.V());
            Co.correctBoundaryConditions();
        }
        else if (phi.dimensions() == dimensionSet(0, 3, -1, 0, 0))
        {
            Info<< "    Calculating incompressible Co" << endl;

            Co.dimensionedInternalField() =
                (0.5*runTime.deltaT())
               *fvc::surfaceSum(mag(phi))().dimensionedInternalField()
               /mesh.V();
            Co.correctBoundaryConditions();
        }
        else
        {
            FatalErrorIn(args.executable())
                << "Incorrect dimensions of phi: " << phi.dimensions()
                << abort(FatalError);
        }

        Info<< "Co max : " << max(Co).value() << endl;

        if (writeResults)
        {
            Co.write();
        }
    }
    else
    {
        Info<< "    No phi" << endl;
    }

    Info<< "\nEnd\n" << endl;
}
Exemplo n.º 13
0
void Foam::calc(const argList& args, const Time& runTime, const fvMesh& mesh)
{
    bool writeResults = !args.optionFound("noWrite");

    IOobject Uheader
    (
        "U",
        runTime.timeName(),
        mesh,
        IOobject::MUST_READ
    );

    IOobject Theader
    (
        "T",
        runTime.timeName(),
        mesh,
        IOobject::MUST_READ
    );

    // Check U and T exists
    if (Uheader.headerOk() && Theader.headerOk())
    {
        autoPtr<volScalarField> MachPtr;

        volVectorField U(Uheader, mesh);

        if (isFile(runTime.constantPath()/"thermophysicalProperties"))
        {
            // thermophysical Mach
            autoPtr<basicPsiThermo> thermo
            (
                basicPsiThermo::New(mesh)
            );

            volScalarField Cp = thermo->Cp();
            volScalarField Cv = thermo->Cv();

            MachPtr.set
            (
                new volScalarField
                (
                    IOobject
                    (
                        "Ma",
                        runTime.timeName(),
                        mesh
                    ),
                    mag(U)/(sqrt((Cp/Cv)*(Cp - Cv)*thermo->T()))
                )
            );
        }
        else
        {
            // thermodynamic Mach
            IOdictionary thermoProps
            (
                IOobject
                (
                    "thermodynamicProperties",
                    runTime.constant(),
                    mesh,
                    IOobject::MUST_READ,
                    IOobject::NO_WRITE
                )
            );

            dimensionedScalar R(thermoProps.lookup("R"));
            dimensionedScalar Cv(thermoProps.lookup("Cv"));

            volScalarField T(Theader, mesh);

            MachPtr.set
            (
                new volScalarField
                (
                    IOobject
                    (
                        "Ma",
                        runTime.timeName(),
                        mesh
                    ),
                    mag(U)/(sqrt(((Cv + R)/Cv)*R*T))
                )
            );
        }

        Info<< "Mach max : " << max(MachPtr()).value() << endl;

        if (writeResults)
        {
            MachPtr().write();
        }
    }
    else
    {
        Info<< "    Missing U or T" << endl;
    }
}