File: fvSchemesUp

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/*--------------------------------*- C++ -*----------------------------------*\
| =========                 |                                                 |
| \\      /  F ield         | OpenFOAM: The Open Source CFD Toolbox           |
|  \\    /   O peration     | Version:  v1912                                 |
|   \\  /    A nd           | Website:  www.openfoam.com                      |
|    \\/     M anipulation  |                                                 |
\*---------------------------------------------------------------------------*/
FoamFile
{
    version     2.0;
    format      ascii;
    class       dictionary;
    location    "system";
    object      fvSchemes;
}
// * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * //

ddtSchemes
{
    default         Euler;
}

gradSchemes
{
    default         Gauss linear;
    grad(p)         Gauss linear;
    grad(b)         fourth;
}

divSchemes
{
    default         Gauss upwind;
/*
    div(phi,U)      Gauss limitedLinearV 1;
    div(phiU,p)     Gauss limitedLinear 1;
    div(phid,p)     Gauss limitedLinear 1;
    div(phi,k)      Gauss limitedLinear 1;
    div(phi,epsilon) Gauss limitedLinear 1;

    div(phiXi,Xi)   Gauss limitedLinear 1;
    div(phiSt,b)    Gauss limitedLinear01 1;

    div(phi,K)      Gauss limitedLinear 1;
*/
    div(phi,ft_b_h_hu) Gauss multivariateSelection
    {
        ft              upwind;//limitedLinear01 1;
        b               upwind;//limitedLinear01 1;
        Xi              upwind;//limitedLinear 1;
        h               upwind;//limitedLinear 1;
        hu              upwind;//limitedLinear 1;
        Xp              upwind;
        Ep              upwind;
    };

    div((Su*grad(b)))               Gauss linear;
    div((U+((Su*Xi)*grad(b))))      Gauss linear;
    //div((muEff*dev2(T(grad(U)))))   Gauss linear;
    div(U)                          Gauss linear;
    div((muEff*dev2(T(grad(Ubet)))))  Gauss linear;
    div(phi,Ubet)       Gauss linear;
}

laplacianSchemes
{
    default none;

    laplacian(muEff,Ubet)  Gauss linear limited 0.333;
    laplacian(DkEff,k) Gauss linear limited 0.333;
    laplacian(DepsilonEff,epsilon) Gauss linear limited 0.333;
    laplacian((rho*inv((((1)*A(Ubet))+tDragDcu))),p) Gauss linear limited 0.333;
    //laplacian((rho*inv((((1)*A(U))+((((0.5*rho)*CR)*mag(U))+((((Csu*(1))*betav)*muEff)*sqr(Aw)))))),p) Gauss linear limited 0.333;
    laplacian(Db,b) Gauss linear limited 0.333;
    laplacian(Db,ft) Gauss linear limited 0.333;
    laplacian(Db,h) Gauss linear limited 0.333;
    laplacian(Db,hu) Gauss linear limited 0.333;
    laplacian(Db,Ep) Gauss linear limited 0.333;
    laplacian(Db,GRxp) Gauss linear limited 0.333;
    laplacian(Db,GRep) Gauss linear limited 0.333;
}

interpolationSchemes
{
    default linear;
}

snGradSchemes
{
    default limited 0.333;
}

fluxRequired
{
    default no;
    p;
}

// ************************************************************************* //