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

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#ifndef DUMUX_TEST_2P2C_PROBLEM_HH

#define DUMUX_TEST_2P2C_PROBLEM_HH


#include <dune/grid/yaspgrid.hh>


#include <dumux/porousmediumflow/2p2c/sequential/problem.hh>

#include <dumux/porousmediumflow/2p2c/sequential/fvpressure.hh>

#include <dumux/porousmediumflow/2p2c/sequential/fvtransport.hh>


// fluid properties

#include <dumux/material/fluidsystems/h2oair.hh>


#include "test_dec2p2c_spatialparams.hh"


namespace Dumux

{

template<class TypeTag>

class TestDecTwoPTwoCProblem;


// Specify the properties

namespace Properties

{

NEW_TYPE_TAG(TestDecTwoPTwoC, INHERITS_FROM(SequentialTwoPTwoC, Test2P2CSpatialParams));


// Set the grid type

SET_TYPE_PROP(TestDecTwoPTwoC, Grid, Dune::YaspGrid<3>);


// Set the problem property

SET_TYPE_PROP(TestDecTwoPTwoC, Problem, TestDecTwoPTwoCProblem<TypeTag>);


// Set the model properties

SET_TYPE_PROP(TestDecTwoPTwoC, TransportModel, FVTransport2P2C<TypeTag>);


SET_TYPE_PROP(TestDecTwoPTwoC, PressureModel,FVPressure2P2C<TypeTag>);


SET_INT_PROP(TestDecTwoPTwoC, PressureFormulation, GET_PROP_TYPE(TypeTag, Indices)::pressureN);


// Select fluid system

template<class TypeTag>

struct FluidSystem<TypeTag, TTag::TestDecTwoPTwoC>

{

    using Scalar = typename GET_PROP_TYPE(TypeTag, Scalar);

    using type = FluidSystems::H2OAir<Scalar, Components::H2O<Scalar>>;

};


SET_BOOL_PROP(TestDecTwoPTwoC, EnableCapillarity, true);

SET_INT_PROP(TestDecTwoPTwoC, BoundaryMobility, GET_PROP_TYPE(TypeTag, Indices)::satDependent);

}


template<class TypeTag>

class TestDecTwoPTwoCProblem: public IMPETProblem2P2C<TypeTag>

{

using ParentType = IMPETProblem2P2C<TypeTag>;

using GridView = typename GET_PROP_TYPE(TypeTag, GridView);

using Grid = typename GridView::Grid;

using TimeManager = typename GET_PROP_TYPE(TypeTag, TimeManager);

using Indices = typename GET_PROP_TYPE(TypeTag, ModelTraits)::Indices;


using FluidSystem = typename GET_PROP_TYPE(TypeTag, FluidSystem);


using BoundaryTypes = typename GET_PROP_TYPE(TypeTag, BoundaryTypes);

using PrimaryVariables = typename GET_PROP_TYPE(TypeTag, PrimaryVariables);


enum

{

    dim = GridView::dimension, dimWorld = GridView::dimensionworld

};


using Scalar = typename GET_PROP_TYPE(TypeTag, Scalar);


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

using Intersection = typename GridView::Intersection;

using GlobalPosition = typename Element::Geometry::GlobalCoordinate;


public:

TestDecTwoPTwoCProblem(TimeManager& timeManager, Grid& grid) :

ParentType(timeManager, grid), depthBOR_(1000.0)

{}


// \{


std::string name() const

{

    return "test_dec2p2c";

}

/* The default behaviour is to write no restart file.

 */

bool shouldWriteRestartFile() const

{

    return false;

}


Scalar temperatureAtPos(const GlobalPosition& globalPos) const

{

    return 273.15 + 10; // -> 10°C

}


// \}

 /*This pressure is used in order to calculate the material properties

 * at the beginning of the initialization routine. It should lie within

 * a reasonable pressure range for the current problem.

 * \param globalPos The global Position

 */

Scalar referencePressureAtPos(const GlobalPosition& globalPos) const

{

    return 1e6;

}


void boundaryTypesAtPos(BoundaryTypes &bcTypes, const GlobalPosition& globalPos) const

{

    if (globalPos[0] > this->bBoxMax()[0] - eps_ || globalPos[0] < eps_)

        bcTypes.setAllDirichlet();

    else

        // all other boundaries

        bcTypes.setAllNeumann();

}


void boundaryFormulation(typename Indices::BoundaryFormulation &bcFormulation, const Intersection& intersection) const

{

    bcFormulation = Indices::concentration;

}


void dirichletAtPos(PrimaryVariables &bcValues ,const GlobalPosition& globalPos) const

{

    Scalar pRef = referencePressureAtPos(globalPos);

    Scalar temp = temperatureAtPos(globalPos);


    // Dirichlet for pressure equation

    bcValues[Indices::pressureEqIdx] = (globalPos[0] < eps_) ? (2.5e5 - FluidSystem::H2O::liquidDensity(temp, pRef) * this->gravity()[dim-1])

            : (2e5 - FluidSystem::H2O::liquidDensity(temp, pRef) * this->gravity()[dim-1]);


    // Dirichlet values for transport equations

    bcValues[Indices::contiWEqIdx] = 1.;

    bcValues[Indices::contiNEqIdx] = 1.- bcValues[Indices::contiWEqIdx];


}


void neumannAtPos(PrimaryVariables &neumannValues, const GlobalPosition& globalPos) const

{

    this->setZero(neumannValues);

}


void sourceAtPos(PrimaryVariables &sourceValues, const GlobalPosition& globalPos) const

{

    this->setZero(sourceValues);

    using std::abs;

    if (abs(globalPos[0] - 4.8) < 0.5 + eps_ && abs(globalPos[1] - 4.8) < 0.5 + eps_)

        sourceValues[Indices::contiNEqIdx] = 0.0001;

}


void initialFormulation(typename Indices::BoundaryFormulation &initialFormulation, const Element& element) const

{

    initialFormulation = Indices::concentration;

}


Scalar initConcentrationAtPos(const GlobalPosition& globalPos) const

{

    return 1;

}

private:

GlobalPosition lowerLeft_;

GlobalPosition upperRight_;


static constexpr Scalar eps_ = 1e-6;

const Scalar depthBOR_;

};

} //end namespace


#endif

fvtransport.hh
Finite volume discretization of the component transport equation.

fvpressure.hh
Finite volume 2p2c pressure model.

h2oair.hh
A compositional two-phase fluid system with water and air as components in both, the liquid and the g...

GET_PROP_TYPE
#define GET_PROP_TYPE(TypeTag, PropTagName)
Definition: propertysystemmacros.hh:283

NEW_TYPE_TAG
#define NEW_TYPE_TAG(...)
Definition: propertysystemmacros.hh:130

test_dec2p2c_spatialparams.hh
spatial parameters for the sequential 2p2c test

Dumux
make the local view function available whenever we use the grid geometry
Definition: adapt.hh:29

Dumux::Properties::EnableCapillarity
Property tag EnableCapillarity
Returns whether capillarity is regarded.
Definition: porousmediumflow/2p2c/sequential/properties.hh:60

Dumux::Properties::BoundaryMobility
Property tag BoundaryMobility
Definition: porousmediumflow/2p2c/sequential/properties.hh:61

Dumux::Properties::SET_INT_PROP
SET_INT_PROP(SequentialOneP, NumEq, 1)
Set number of equations to 1 for isothermal one-phase models.

Dumux::Properties::SET_TYPE_PROP
SET_TYPE_PROP(FVPressureOneP, Velocity, FVVelocity1P< TypeTag >)
Set velocity reconstruction implementation standard cell centered finite volume schemes as default.

Dumux::Properties::TransportModel
Property tag TransportModel
The type of the discretization of a transport model.
Definition: porousmediumflow/sequential/properties.hh:66

Dumux::Properties::INHERITS_FROM
Type tag FVPressureOneP INHERITS_FROM(PressureOneP))
The type tag for the one-phase problems using a standard finite volume model.

Dumux::Properties::Indices
Property tag Indices
Definition: porousmediumflow/sequential/properties.hh:59

Dumux::Properties::SET_BOOL_PROP
SET_BOOL_PROP(FVPressureOneP, VisitFacesOnlyOnce, true)
Allow assembling algorithm for the pressure matrix to assemble only from one side of a cell-cell inte...

Dumux::Properties::PressureModel
Property tag PressureModel
The type of the discretization of a pressure model.
Definition: porousmediumflow/sequential/properties.hh:65

Dumux::Properties::Grid
The DUNE grid type.
Definition: common/properties.hh:57

Dumux::Properties::Problem
Property to specify the type of a problem which has to be solved.
Definition: common/properties.hh:69

Dumux::Properties::FluidSystem
The type of the fluid system to use.
Definition: common/properties.hh:223

Dumux::Properties::PressureFormulation
Definition: common/properties.hh:312

Dumux::FluidSystems::H2OAir
A compositional two-phase fluid system with water and air as components in both, the liquid and the g...
Definition: h2oair.hh:75

Dumux::IMPESProblem2P::gravity
const GravityVector & gravity() const
Returns the acceleration due to gravity.
Definition: dumux/porousmediumflow/2p/sequential/impes/problem.hh:167

Dumux::FVPressure2P2C
The finite volume model for the solution of the compositional pressure equation.
Definition: fvpressure.hh:73

Dumux::FVTransport2P2C
Compositional transport step in a Finite Volume discretization.
Definition: fvtransport.hh:60

Dumux::IMPETProblem2P2C
Base class for all compositional 2-phase problems which use an impet algorithm.
Definition: dumux/porousmediumflow/2p2c/sequential/problem.hh:43

Dumux::IMPETProblem2P2C::setZero
void setZero(typename GET_PROP_TYPE(TypeTag, PrimaryVariables) &values, const int equation=-1) const
Sets entries of the primary variable vector to zero.
Definition: dumux/porousmediumflow/2p2c/sequential/problem.hh:199

Dumux::IMPETProblem
base class for problems using a sequential implicit-explicit strategy
Definition: impetproblem.hh:46

Dumux::IMPETProblem::timeManager
TimeManager & timeManager()
Returns TimeManager object used by the simulation.
Definition: impetproblem.hh:663

Dumux::IMPETProblem::bBoxMax
const GlobalPosition & bBoxMax() const
The coordinate of the corner of the GridView's bounding box with the largest values.
Definition: impetproblem.hh:655

Dumux::IMPETProblem::grid
Grid & grid()
Returns the current grid which used by the problem.
Definition: impetproblem.hh:581

Dumux::Test2P2CSpatialParams
spatial parameters for the sequential 2p2c test
Definition: test_dec2p2c_spatialparams.hh:64

Dumux::TestDecTwoPTwoCProblem
test problem for the sequential 2p2c model
Definition: test_dec2p2cproblem.hh:92

Dumux::TestDecTwoPTwoCProblem::boundaryFormulation
void boundaryFormulation(typename Indices::BoundaryFormulation &bcFormulation, const Intersection &intersection) const
Flag for the type of Dirichlet conditions.
Definition: test_dec2p2cproblem.hh:186

Dumux::TestDecTwoPTwoCProblem::referencePressureAtPos
Scalar referencePressureAtPos(const GlobalPosition &globalPos) const
Returns the reference pressure.
Definition: test_dec2p2cproblem.hh:156

Dumux::TestDecTwoPTwoCProblem::neumannAtPos
void neumannAtPos(PrimaryVariables &neumannValues, const GlobalPosition &globalPos) const
Value for neumann boundary condition .
Definition: test_dec2p2cproblem.hh:224

Dumux::TestDecTwoPTwoCProblem::shouldWriteRestartFile
bool shouldWriteRestartFile() const
Returns true if a restart file should be written.
Definition: test_dec2p2cproblem.hh:135

Dumux::TestDecTwoPTwoCProblem::initConcentrationAtPos
Scalar initConcentrationAtPos(const GlobalPosition &globalPos) const
Concentration initial condition (dimensionless)
Definition: test_dec2p2cproblem.hh:258

Dumux::TestDecTwoPTwoCProblem::TestDecTwoPTwoCProblem
TestDecTwoPTwoCProblem(TimeManager &timeManager, Grid &grid)
Definition: test_dec2p2cproblem.hh:116

Dumux::TestDecTwoPTwoCProblem::name
std::string name() const
The problem name.
Definition: test_dec2p2cproblem.hh:128

Dumux::TestDecTwoPTwoCProblem::dirichletAtPos
void dirichletAtPos(PrimaryVariables &bcValues, const GlobalPosition &globalPos) const
Values for dirichlet boundary condition  for pressure and  or  for transport.
Definition: test_dec2p2cproblem.hh:199

Dumux::TestDecTwoPTwoCProblem::initialFormulation
void initialFormulation(typename Indices::BoundaryFormulation &initialFormulation, const Element &element) const
Flag for the type of initial conditions.
Definition: test_dec2p2cproblem.hh:251

Dumux::TestDecTwoPTwoCProblem::sourceAtPos
void sourceAtPos(PrimaryVariables &sourceValues, const GlobalPosition &globalPos) const
Source of mass .
Definition: test_dec2p2cproblem.hh:239

Dumux::TestDecTwoPTwoCProblem::boundaryTypesAtPos
void boundaryTypesAtPos(BoundaryTypes &bcTypes, const GlobalPosition &globalPos) const
Type of boundary condition.
Definition: test_dec2p2cproblem.hh:169

Dumux::TestDecTwoPTwoCProblem::temperatureAtPos
Scalar temperatureAtPos(const GlobalPosition &globalPos) const
Returns the temperature within the domain.
Definition: test_dec2p2cproblem.hh:144

Dumux::Properties::FluidSystem< TypeTag, TTag::TestDecTwoPTwoC >::Scalar
typename GET_PROP_TYPE(TypeTag, Scalar) Scalar
Definition: test_dec2p2cproblem.hh:70

problem.hh
Base class for sequential 2p2c compositional problems.