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// -*- mode: C++; tab-width: 4; indent-tabs-mode: nil; c-basic-offset: 4 -*-

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#ifndef DUMUX_SST_STAGGERED_FLUXVARIABLES_HH

#define DUMUX_SST_STAGGERED_FLUXVARIABLES_HH


#include <numeric>

#include <dune/common/exceptions.hh>

#include <dumux/common/properties.hh>

#include <dumux/flux/fluxvariablesbase.hh>

#include <dumux/discretization/method.hh>

#include <dumux/discretization/extrusion.hh>

#include <dumux/freeflow/turbulencemodel.hh>

#include <dumux/freeflow/navierstokes/fluxvariables.hh>

#include <dumux/freeflow/rans/twoeq/sst/fluxvariables.hh>


namespace Dumux {


// forward declaration

template<class TypeTag, class BaseFluxVariables, class DiscretizationMethod>

class SSTFluxVariablesImpl;


template<class TypeTag, class BaseFluxVariables>


class SSTFluxVariablesImpl<TypeTag, BaseFluxVariables, DiscretizationMethods::Staggered>

: public BaseFluxVariables

{

    using ParentType = BaseFluxVariables;


    using GridVariables = GetPropType<TypeTag, Properties::GridVariables>;


    using GridVolumeVariables = typename GridVariables::GridVolumeVariables;

    using ElementVolumeVariables = typename GridVolumeVariables::LocalView;

    using VolumeVariables = typename GridVolumeVariables::VolumeVariables;


    using GridFluxVariablesCache = typename GridVariables::GridFluxVariablesCache;

    using FluxVariablesCache = typename GridFluxVariablesCache::FluxVariablesCache;


    using GridFaceVariables = typename GridVariables::GridFaceVariables;

    using ElementFaceVariables = typename GridFaceVariables::LocalView;

    using FaceVariables = typename GridFaceVariables::FaceVariables;


    using ModelTraits = GetPropType<TypeTag, Properties::ModelTraits>;

    using Scalar = GetPropType<TypeTag, Properties::Scalar>;

    using GridGeometry = GetPropType<TypeTag, Properties::GridGeometry>;

    using FVElementGeometry = typename GridGeometry::LocalView;

    using SubControlVolumeFace = typename GridGeometry::SubControlVolumeFace;

    using Extrusion = Extrusion_t<GridGeometry>;

    using GridView = typename GridGeometry::GridView;

    using Problem = GetPropType<TypeTag, Properties::Problem>;

    using Element = typename GridView::template Codim<0>::Entity;

    using Indices = typename GetPropType<TypeTag, Properties::ModelTraits>::Indices;

    using CellCenterPrimaryVariables = GetPropType<TypeTag, Properties::CellCenterPrimaryVariables>;

    using FacePrimaryVariables = GetPropType<TypeTag, Properties::FacePrimaryVariables>;


    static constexpr int turbulentKineticEnergyEqIdx = Indices::turbulentKineticEnergyEqIdx - ModelTraits::dim();

    static constexpr int dissipationEqIdx = Indices::dissipationEqIdx - ModelTraits::dim();


public:


    CellCenterPrimaryVariables computeMassFlux(const Problem& problem,

                                               const Element &element,

                                               const FVElementGeometry& fvGeometry,

                                               const ElementVolumeVariables& elemVolVars,

                                               const ElementFaceVariables& elemFaceVars,

                                               const SubControlVolumeFace &scvf,

                                               const FluxVariablesCache& fluxVarsCache)

    {

        CellCenterPrimaryVariables flux = ParentType::computeMassFlux(problem, element, fvGeometry,

                                                                      elemVolVars, elemFaceVars, scvf, fluxVarsCache);


        // calculate advective flux

        auto upwindTermK = [](const auto& volVars)

        { return volVars.turbulentKineticEnergy() * volVars.density(); };

        auto upwindTermOmega = [](const auto& volVars)

        { return volVars.dissipation() * volVars.density(); };


        flux[turbulentKineticEnergyEqIdx]

            = ParentType::advectiveFluxForCellCenter(problem, elemVolVars, elemFaceVars, scvf, upwindTermK);

        flux[dissipationEqIdx]

            = ParentType::advectiveFluxForCellCenter(problem, elemVolVars, elemFaceVars, scvf, upwindTermOmega);


        // calculate diffusive flux

        const auto& insideScv = fvGeometry.scv(scvf.insideScvIdx());

        const auto& outsideScv = fvGeometry.scv(scvf.outsideScvIdx());

        const auto& insideVolVars = elemVolVars[scvf.insideScvIdx()];

        const auto& outsideVolVars = elemVolVars[scvf.outsideScvIdx()];

        Scalar insideCoeff_k = 0.0, insideCoeff_w = 0.0, outsideCoeff_k = 0.0, outsideCoeff_w = 0.0;


        if(problem.sstModelVersion() == SSTModel::BSL)

        {

            insideCoeff_k = insideVolVars.viscosity()

                                    + ( insideVolVars.sigmaKBSL() * insideVolVars.dynamicEddyViscosity() );

            outsideCoeff_k = outsideVolVars.viscosity()

                                    + ( outsideVolVars.sigmaKBSL() * outsideVolVars.dynamicEddyViscosity() );

            insideCoeff_w = insideVolVars.viscosity()

                                    + ( insideVolVars.sigmaOmegaBSL() * insideVolVars.dynamicEddyViscosity() );

            outsideCoeff_w = outsideVolVars.viscosity()

                                    + ( outsideVolVars.sigmaOmegaBSL() * outsideVolVars.dynamicEddyViscosity() );

        }

        else if(problem.sstModelVersion() == SSTModel::SST)

        {

            insideCoeff_k = insideVolVars.viscosity()

                                    + ( insideVolVars.sigmaKSST() * insideVolVars.dynamicEddyViscosity() );

            outsideCoeff_k = outsideVolVars.viscosity()

                                    + ( outsideVolVars.sigmaKSST() * outsideVolVars.dynamicEddyViscosity() );

            insideCoeff_w = insideVolVars.viscosity()

                                    + ( insideVolVars.sigmaOmegaSST() * insideVolVars.dynamicEddyViscosity() );

            outsideCoeff_w = outsideVolVars.viscosity()

                                    + ( outsideVolVars.sigmaOmegaSST() * outsideVolVars.dynamicEddyViscosity() );

        }

        else

            DUNE_THROW(Dune::NotImplemented, "\nThis SST Model is not implemented.\n");


        // scale by extrusion factor

        insideCoeff_k *= insideVolVars.extrusionFactor();

        outsideCoeff_k *= outsideVolVars.extrusionFactor();

        insideCoeff_w *= insideVolVars.extrusionFactor();

        outsideCoeff_w *= outsideVolVars.extrusionFactor();


        Scalar distance = 0.0;

        Scalar coeff_k = 0.0;

        Scalar coeff_w = 0.0;

        if (scvf.boundary())

        {

            distance = (insideScv.dofPosition() - scvf.ipGlobal()).two_norm();

            coeff_k = insideCoeff_k;

            coeff_w = insideCoeff_w;

        }

        else

        {

            // average and distance

            coeff_k = arithmeticMean(insideCoeff_k, outsideCoeff_k,

                                    (outsideScv.dofPosition() - scvf.ipGlobal()).two_norm(),

                                    (insideScv.dofPosition() - scvf.ipGlobal()).two_norm());

            coeff_w = arithmeticMean(insideCoeff_w, outsideCoeff_w,

                                    (outsideScv.dofPosition() - scvf.ipGlobal()).two_norm(),

                                    (insideScv.dofPosition() - scvf.ipGlobal()).two_norm());

            distance = (outsideScv.dofPosition() - insideScv.dofPosition()).two_norm();

        }


        const auto bcTypes = problem.boundaryTypes(element, scvf);

        if (!(scvf.boundary() && (bcTypes.isOutflow(Indices::turbulentKineticEnergyEqIdx)

                                  || bcTypes.isSymmetry())))

        {

            flux[turbulentKineticEnergyEqIdx]

                += coeff_k / distance

                   * (insideVolVars.turbulentKineticEnergy() - outsideVolVars.turbulentKineticEnergy())

                   * Extrusion::area(scvf);

        }

        if (!(scvf.boundary() && (bcTypes.isOutflow(Indices::dissipationEqIdx)

                                  || bcTypes.isSymmetry())))

        {

            flux[dissipationEqIdx]

                += coeff_w / distance

                   * (insideVolVars.dissipation() - outsideVolVars.dissipation())

                   * Extrusion::area(scvf);

        }

        return flux;

    }


    FacePrimaryVariables computeMomentumFlux(const Problem& problem,

                                             const Element& element,

                                             const SubControlVolumeFace& scvf,

                                             const FVElementGeometry& fvGeometry,

                                             const ElementVolumeVariables& elemVolVars,

                                             const ElementFaceVariables& elemFaceVars,

                                             const GridFluxVariablesCache& gridFluxVarsCache)

    {

        const auto& insideVolVars = elemVolVars[scvf.insideScvIdx()];


        return ParentType::computeFrontalMomentumFlux(problem, element, scvf, fvGeometry, elemVolVars, elemFaceVars, gridFluxVarsCache)

               + ParentType::computeLateralMomentumFlux(problem, element, scvf, fvGeometry, elemVolVars, elemFaceVars, gridFluxVarsCache)

               + 2.0 / ModelTraits::dim() * insideVolVars.density() * insideVolVars.turbulentKineticEnergy()

                 * Extrusion::area(scvf) * scvf.directionSign() * insideVolVars.extrusionFactor();

    }


};


} // end namespace


#endif

fluxvariablesbase.hh
Base class for the flux variables living on a sub control volume face.

turbulencemodel.hh
The available free flow turbulence models in Dumux.

method.hh
The available discretization methods in Dumux.

extrusion.hh
Helper classes to compute the integration elements.

Dumux::SSTModel::SST
@ SST
Definition turbulencemodel.hh:75

Dumux::SSTModel::BSL
@ BSL
Definition turbulencemodel.hh:75

Dumux::distance
static ctype distance(const Dune::FieldVector< ctype, dimWorld > &a, const Dune::FieldVector< ctype, dimWorld > &b)
Compute the shortest distance between two points.
Definition distance.hh:292

Dumux::arithmeticMean
constexpr Scalar arithmeticMean(Scalar x, Scalar y, Scalar wx=1.0, Scalar wy=1.0) noexcept
Calculate the (weighted) arithmetic mean of two scalar values.
Definition math.hh:50

Dumux
Definition adapt.hh:29

Dumux::GetPropType
typename Properties::Detail::GetPropImpl< TypeTag, Property >::type::type GetPropType
get the type alias defined in the property
Definition propertysystem.hh:150

Dumux::Extrusion_t
typename Extrusion< T >::type Extrusion_t
Convenience alias for obtaining the extrusion type.
Definition extrusion.hh:177

Dumux::DiscretizationMethods
Definition method.hh:47

Dumux::SSTFluxVariablesImpl
The flux variables class for the SST model using the staggered grid discretization.
Definition freeflow/rans/twoeq/sst/fluxvariables.hh:34

Dumux::SSTFluxVariablesImpl< TypeTag, BaseFluxVariables, DiscretizationMethods::Staggered >::computeMassFlux
CellCenterPrimaryVariables computeMassFlux(const Problem &problem, const Element &element, const FVElementGeometry &fvGeometry, const ElementVolumeVariables &elemVolVars, const ElementFaceVariables &elemFaceVars, const SubControlVolumeFace &scvf, const FluxVariablesCache &fluxVarsCache)
Computes the flux for the cell center residual.
Definition freeflow/rans/twoeq/sst/staggered/fluxvariables.hh:88

Dumux::SSTFluxVariablesImpl< TypeTag, BaseFluxVariables, DiscretizationMethods::Staggered >::computeMomentumFlux
FacePrimaryVariables computeMomentumFlux(const Problem &problem, const Element &element, const SubControlVolumeFace &scvf, const FVElementGeometry &fvGeometry, const ElementVolumeVariables &elemVolVars, const ElementFaceVariables &elemFaceVars, const GridFluxVariablesCache &gridFluxVarsCache)
Returns the momentum flux over all staggered faces.
Definition freeflow/rans/twoeq/sst/staggered/fluxvariables.hh:193

properties.hh
Declares all properties used in Dumux.

fluxvariables.hh
The flux variables class for the Navier-Stokes model. This is a convenience alias for that actual,...

fluxvariables.hh
The flux variables class for the SST model. This is a convenience alias for that actual,...