volumevariables.hh 9.27 KB
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// -*- mode: C++; tab-width: 4; indent-tabs-mode: nil; c-basic-offset: 4 -*-
// vi: set et ts=4 sw=4 sts=4:
/*****************************************************************************
 *   See the file COPYING for full copying permissions.                      *
 *                                                                           *
 *   This program is free software: you can redistribute it and/or modify    *
 *   it under the terms of the GNU General Public License as published by    *
 *   the Free Software Foundation, either version 2 of the License, or       *
 *   (at your option) any later version.                                     *
 *                                                                           *
 *   This program is distributed in the hope that it will be useful,         *
 *   but WITHOUT ANY WARRANTY; without even the implied warranty of          *
 *   MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the            *
 *   GNU General Public License for more details.                            *
 *                                                                           *
 *   You should have received a copy of the GNU General Public License       *
 *   along with this program.  If not, see <http://www.gnu.org/licenses/>.   *
 *****************************************************************************/
/*!
 * \file
 *
 * \brief Contains the quantities which are constant within a
 *        finite volume in the two-phase model.
 */
#ifndef DUMUX_2P_VOLUME_VARIABLES_HH
#define DUMUX_2P_VOLUME_VARIABLES_HH

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#include <dumux/common/properties.hh>
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#include <dumux/discretization/volumevariables.hh>
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#include <dune/common/fvector.hh>

namespace Dumux
{
/*!
 * \ingroup TwoPModel
 * \ingroup ImplicitVolumeVariables
 * \brief Contains the quantities which are are constant within a
 *        finite volume in the two-phase model.
 */
template <class TypeTag>
class TwoPVolumeVariables : public ImplicitVolumeVariables<TypeTag>
{
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    using ParentType = ImplicitVolumeVariables<TypeTag>;

    using Implementation = typename GET_PROP_TYPE(TypeTag, VolumeVariables);
    using Scalar = typename GET_PROP_TYPE(TypeTag, Scalar);
    using Problem = typename GET_PROP_TYPE(TypeTag, Problem);
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    using SpatialParams = typename GET_PROP_TYPE(TypeTag, SpatialParams);
    using PermeabilityType = typename SpatialParams::PermeabilityType;
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    using Indices = typename GET_PROP_TYPE(TypeTag, Indices);
    using FluidSystem = typename GET_PROP_TYPE(TypeTag, FluidSystem);
    using MaterialLaw = typename GET_PROP_TYPE(TypeTag, MaterialLaw);
    using FVElementGeometry = typename GET_PROP_TYPE(TypeTag, FVElementGeometry);
    using SubControlVolume = typename GET_PROP_TYPE(TypeTag, SubControlVolume);
    using ElementSolutionVector = typename GET_PROP_TYPE(TypeTag, ElementSolutionVector);

    enum
    {
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        pwsn = Indices::pwsn,
        pnsw = Indices::pnsw,
        pressureIdx = Indices::pressureIdx,
        saturationIdx = Indices::saturationIdx,
        wPhaseIdx = Indices::wPhaseIdx,
        nPhaseIdx = Indices::nPhaseIdx,
        numPhases = GET_PROP_VALUE(TypeTag, NumPhases),
        formulation = GET_PROP_VALUE(TypeTag, Formulation)
    };

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    using GridView = typename GET_PROP_TYPE(TypeTag, GridView);
    using Element = typename GridView::template Codim<0>::Entity;

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public:
    // export type of fluid state for non-isothermal models
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    using FluidState = typename GET_PROP_TYPE(TypeTag, FluidState);
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    /*!
     * \copydoc ImplicitVolumeVariables::update
     */
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    void update(const ElementSolutionVector &elemSol,
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                const Problem &problem,
                const Element &element,
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                const SubControlVolume& scv)
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    {
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        ParentType::update(elemSol, problem, element, scv);
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        completeFluidState(elemSol, problem, element, scv, fluidState_);
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        const auto& materialParams = problem.spatialParams().materialLawParams(element, scv, elemSol);
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        mobility_[wPhaseIdx] =
            MaterialLaw::krw(materialParams, fluidState_.saturation(wPhaseIdx))
            / fluidState_.viscosity(wPhaseIdx);

        mobility_[nPhaseIdx] =
            MaterialLaw::krn(materialParams, fluidState_.saturation(wPhaseIdx))
            / fluidState_.viscosity(nPhaseIdx);

        // porosity
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        porosity_ = problem.spatialParams().porosity(element, scv, elemSol);
        permeability_ = problem.spatialParams().permeability(element, scv, elemSol);
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    }

    /*!
     * \copydoc ImplicitModel::completeFluidState
     */
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    static void completeFluidState(const ElementSolutionVector& elemSol,
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                                   const Problem& problem,
                                   const Element& element,
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                                   const SubControlVolume& scv,
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                                   FluidState& fluidState)
    {
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        Scalar t =  ParentType::temperature(elemSol, problem, element, scv);
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        fluidState.setTemperature(t);

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        const auto& materialParams = problem.spatialParams().materialLawParams(element, scv, elemSol);
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        const auto& priVars = ParentType::extractDofPriVars(elemSol, scv);
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        if (int(formulation) == pwsn) {
            Scalar sn = priVars[saturationIdx];
            fluidState.setSaturation(nPhaseIdx, sn);
            fluidState.setSaturation(wPhaseIdx, 1 - sn);

            Scalar pw = priVars[pressureIdx];
            fluidState.setPressure(wPhaseIdx, pw);
            fluidState.setPressure(nPhaseIdx,
                                   pw + MaterialLaw::pc(materialParams, 1 - sn));
        }
        else if (int(formulation) == pnsw) {
            Scalar sw = priVars[saturationIdx];
            fluidState.setSaturation(wPhaseIdx, sw);
            fluidState.setSaturation(nPhaseIdx, 1 - sw);

            Scalar pn = priVars[pressureIdx];
            fluidState.setPressure(nPhaseIdx, pn);
            fluidState.setPressure(wPhaseIdx,
                                   pn - MaterialLaw::pc(materialParams, sw));
        }

        typename FluidSystem::ParameterCache paramCache;
        paramCache.updateAll(fluidState);

        for (int phaseIdx = 0; phaseIdx < numPhases; ++phaseIdx) {
            // compute and set the viscosity
            Scalar mu = FluidSystem::viscosity(fluidState, paramCache, phaseIdx);
            fluidState.setViscosity(phaseIdx, mu);

            // compute and set the density
            Scalar rho = FluidSystem::density(fluidState, paramCache, phaseIdx);
            fluidState.setDensity(phaseIdx, rho);

            // compute and set the enthalpy
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            Scalar h = ParentType::enthalpy(fluidState, paramCache, phaseIdx);
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            fluidState.setEnthalpy(phaseIdx, h);
        }
    }

    /*!
     * \brief Returns the phase state for the control volume.
     */
    const FluidState &fluidState() const
    { return fluidState_; }

    /*!
     * \brief Returns the saturation of a given phase within
     *        the control volume in \f$[-]\f$.
     *
     * \param phaseIdx The phase index
     */
    Scalar saturation(int phaseIdx) const
    { return fluidState_.saturation(phaseIdx); }

    /*!
     * \brief Returns the mass density of a given phase within the
     *        control volume in \f$[kg/m^3]\f$.
     *
     * \param phaseIdx The phase index
     */
    Scalar density(int phaseIdx) const
    { return fluidState_.density(phaseIdx); }

    /*!
     * \brief Returns the effective pressure of a given phase within
     *        the control volume in \f$[kg/(m*s^2)=N/m^2=Pa]\f$.
     *
     * \param phaseIdx The phase index
     */
    Scalar pressure(int phaseIdx) const
    { return fluidState_.pressure(phaseIdx); }

    /*!
     * \brief Returns the capillary pressure within the control volume
     * in \f$[kg/(m*s^2)=N/m^2=Pa]\f$.
     */
    Scalar capillaryPressure() const
    { return fluidState_.pressure(nPhaseIdx) - fluidState_.pressure(wPhaseIdx); }

    /*!
     * \brief Returns temperature inside the sub-control volume
     * in \f$[K]\f$.
     *
     * Note that we assume thermodynamic equilibrium, i.e. the
     * temperature of the rock matrix and of all fluid phases are
     * identical.
     */
    Scalar temperature() const
    { return fluidState_.temperature(/*phaseIdx=*/0); }

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    /*!
     * \brief Returns the dynamic viscosity of the fluid within the
     *        control volume in \f$\mathrm{[Pa s]}\f$.
     *
     * \param phaseIdx The phase index
     */
    Scalar viscosity(int phaseIdx) const
    { return fluidState_.viscosity(phaseIdx); }

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    /*!
     * \brief Returns the effective mobility of a given phase within
     *        the control volume in \f$[s*m/kg]\f$.
     *
     * \param phaseIdx The phase index
     */
    Scalar mobility(int phaseIdx) const
    { return mobility_[phaseIdx]; }

    /*!
     * \brief Returns the average porosity within the control volume in \f$[-]\f$.
     */
    Scalar porosity() const
    { return porosity_; }

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    /*!
     * \brief Returns the permeability within the control volume in \f$[m^2]\f$.
     */
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    const PermeabilityType& permeability() const
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    { return permeability_; }

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protected:

    FluidState fluidState_;
    Scalar porosity_;
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    PermeabilityType permeability_;
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    Scalar mobility_[numPhases];

private:
    Implementation &asImp_()
    { return *static_cast<Implementation*>(this); }

    const Implementation &asImp_() const
    { return *static_cast<const Implementation*>(this); }
};

}

#endif