Definition of the spatial parameters for non-equilibrium. More...
#include <dumux/porousmediumflow/fvspatialparamsnonequilibrium.hh>
Definition of the spatial parameters for non-equilibrium.
Public Types | |
using | AwnSurfaceParams = Scalar |
export the types used for interfacial area calculations More... | |
using | AwsSurfaceParams = Scalar |
using | AnsSurfaceParams = Scalar |
Public Member Functions | |
FVPorousMediumFlowSpatialParamsNonEquilibrium (std::shared_ptr< const GridGeometry > gridGeometry) | |
template<class ElementSolution > | |
const Scalar | characteristicLength (const Element &element, const SubControlVolume &scv, const ElementSolution &elemSol) const |
Return the characteristic length for the mass transfer. More... | |
const Scalar | characteristicLengthAtPos (const GlobalPosition &globalPos) const |
Return the characteristic length for the mass transfer. More... | |
template<class ElementSolution > | |
const Scalar | factorEnergyTransfer (const Element &element, const SubControlVolume &scv, const ElementSolution &elemSol) const |
Return the pre-factor the the energy transfer. More... | |
const Scalar | factorEnergyTransferAtPos (const GlobalPosition &globalPos) const |
Return the pre factor the the energy transfer. More... | |
template<class ElementSolution > | |
const Scalar | factorMassTransfer (const Element &element, const SubControlVolume &scv, const ElementSolution &elemSol) const |
Return the pre-factor the the mass transfer. More... | |
const Scalar | factorMassTransferAtPos (const GlobalPosition &globalPos) const |
Return the pre-factor the the mass transfer. More... | |
template<class ElementSolution > | |
decltype(auto) | fluidMatrixInteraction (const Element &element, const SubControlVolume &scv, const ElementSolution &elemSol) const |
Function for defining the parameters needed by constitutive relationships (kr-sw, pc-sw, etc.). More... | |
template<class FluidSystem , class ElementSolution > | |
int | wettingPhase (const Element &element, const SubControlVolume &scv, const ElementSolution &elemSol) const |
Function for defining which phase is to be considered as the wetting phase. More... | |
template<class FluidSystem > | |
int | wettingPhaseAtPos (const GlobalPosition &globalPos) const |
Function for defining which phase is to be considered as the wetting phase. More... | |
template<class ElementSolution > | |
decltype(auto) | permeability (const Element &element, const SubControlVolume &scv, const ElementSolution &elemSol) const |
Function for defining the (intrinsic) permeability \([m^2]\). More... | |
Scalar | beaversJosephCoeffAtPos (const GlobalPosition &globalPos) const |
Function for defining the Beavers-Joseph coefficient for multidomain problems \(\mathrm{[-]}\). More... | |
Scalar | forchCoeff (const SubControlVolumeFace &scvf) const |
Apply the Forchheimer coefficient for inertial forces calculation. More... | |
template<class ElementSolution > | |
Scalar | porosity (const Element &element, const SubControlVolume &scv, const ElementSolution &elemSol) const |
Function for defining the porosity. That is possibly solution dependent. More... | |
template<class SolidSystem , class ElementSolution , typename std::enable_if_t< SolidSystem::isInert() &&SolidSystem::numInertComponents==1 &&!decltype(isValid(Detail::hasInertVolumeFractionAtPos< GlobalPosition, SolidSystem >())(std::declval< Implementation >()))::value, int > = 0> | |
Scalar | inertVolumeFraction (const Element &element, const SubControlVolume &scv, const ElementSolution &elemSol, int compIdx) const |
Function for defining the solid volume fraction. That is possibly solution dependent. More... | |
template<class SolidSystem , class ElementSolution , typename std::enable_if_t< SolidSystem::numInertComponents==0, int > = 0> | |
Scalar | inertVolumeFraction (const Element &element, const SubControlVolume &scv, const ElementSolution &elemSol, int compIdx) const |
template<class SolidSystem , class ElementSolution , typename std::enable_if_t<(SolidSystem::numInertComponents > 1)||((SolidSystem::numInertComponents > 0) &&(!SolidSystem::isInert()||decltype(isValid(Detail::hasInertVolumeFractionAtPos< GlobalPosition, SolidSystem >())(std::declval< Implementation >()))::value)), int > = 0> | |
Scalar | inertVolumeFraction (const Element &element, const SubControlVolume &scv, const ElementSolution &elemSol, int compIdx) const |
template<class ElementSolution > | |
Scalar | extrusionFactor (const Element &element, const SubControlVolume &scv, const ElementSolution &elemSol) const |
Return how much the domain is extruded at a given sub-control volume. More... | |
Scalar | extrusionFactorAtPos (const GlobalPosition &globalPos) const |
Return how much the domain is extruded at a given position. More... | |
template<class ElementSolution > | |
Scalar | temperature (const Element &element, const SubControlVolume &scv, const ElementSolution &elemSol) const |
Return the temperature in the given sub-control volume. More... | |
Scalar | temperatureAtPos (const GlobalPosition &globalPos) const |
Return the temperature in the domain at the given position. More... | |
const GravityVector & | gravity (const GlobalPosition &pos) const |
Returns the acceleration due to gravity \(\mathrm{[m/s^2]}\). More... | |
const GridGeometry & | gridGeometry () const |
The finite volume grid geometry. More... | |
Static Public Member Functions | |
static constexpr bool | evaluatePermeabilityAtScvfIP () |
If the permeability should be evaluated directly at the scvf integration point (for convergence tests with analytical and continuous perm functions) or is evaluated at the scvs (for permeability fields with discontinuities) -> default. More... | |
Protected Member Functions | |
Implementation & | asImp_ () |
Returns the implementation of the spatial parameters (static polymorphism) More... | |
const Implementation & | asImp_ () const |
Returns the implementation of the spatial parameters (static polymorphism) More... | |
using Dumux::FVPorousMediumFlowSpatialParamsNonEquilibrium< GridGeometry, Scalar, Implementation >::AnsSurfaceParams = Scalar |
using Dumux::FVPorousMediumFlowSpatialParamsNonEquilibrium< GridGeometry, Scalar, Implementation >::AwnSurfaceParams = Scalar |
export the types used for interfacial area calculations
using Dumux::FVPorousMediumFlowSpatialParamsNonEquilibrium< GridGeometry, Scalar, Implementation >::AwsSurfaceParams = Scalar |
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inline |
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inlineprotectedinherited |
Returns the implementation of the spatial parameters (static polymorphism)
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inlineprotectedinherited |
Returns the implementation of the spatial parameters (static polymorphism)
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inlineinherited |
Function for defining the Beavers-Joseph coefficient for multidomain problems \(\mathrm{[-]}\).
globalPos | The global position |
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inline |
Return the characteristic length for the mass transfer.
The position is determined based on the coordinate of the vertex belonging to the considered sub control volume.
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inline |
Return the characteristic length for the mass transfer.
globalPos | The position in global coordinates. |
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inlinestaticconstexprinherited |
If the permeability should be evaluated directly at the scvf integration point (for convergence tests with analytical and continuous perm functions) or is evaluated at the scvs (for permeability fields with discontinuities) -> default.
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inlineinherited |
Return how much the domain is extruded at a given sub-control volume.
This means the factor by which a lower-dimensional (1D or 2D) entity needs to be expanded to get a full dimensional cell. The default is 1.0 which means that 1D problems are actually thought as pipes with a cross section of 1 m^2 and 2D problems are assumed to extend 1 m to the back.
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inlineinherited |
Return how much the domain is extruded at a given position.
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inline |
Return the pre-factor the the energy transfer.
The position is determined based on the coordinate of the vertex belonging to the considered sub control volume.
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inline |
Return the pre factor the the energy transfer.
globalPos | The position in global coordinates. |
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inline |
Return the pre-factor the the mass transfer.
The position is determined based on the coordinate of the vertex belonging to the considered sub control volume.
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inline |
Return the pre-factor the the mass transfer.
globalPos | The position in global coordinates. |
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inlineinherited |
Function for defining the parameters needed by constitutive relationships (kr-sw, pc-sw, etc.).
element | The current element |
scv | The sub-control volume inside the element. |
elemSol | The solution at the dofs connected to the element. |
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inlineinherited |
Apply the Forchheimer coefficient for inertial forces calculation.
scvf | The sub-control volume face where the intrinsic velocity ought to be calculated. |
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inlineinherited |
Returns the acceleration due to gravity \(\mathrm{[m/s^2]}\).
The default behaviour is a constant gravity vector; if the Problem.EnableGravity
parameter is true, \(\boldsymbol{g} = ( 0,\dots,\ -9.81)^T \), else \(\boldsymbol{g} = ( 0,\dots, 0)^T \).
pos | the spatial position at which to evaluate the gravity vector |
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inlineinherited |
The finite volume grid geometry.
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inlineinherited |
Function for defining the solid volume fraction. That is possibly solution dependent.
element | The current element |
scv | The sub-control volume inside the element. |
elemSol | The solution at the dofs connected to the element. |
compIdx | The solid component index |
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inlineinherited |
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inlineinherited |
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inlineinherited |
Function for defining the (intrinsic) permeability \([m^2]\).
element | The current element |
scv | The sub-control volume inside the element. |
elemSol | The solution at the dofs connected to the element. |
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inlineinherited |
Function for defining the porosity. That is possibly solution dependent.
element | The current element |
scv | The sub-control volume inside the element. |
elemSol | The solution at the dofs connected to the element. |
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inlineinherited |
Return the temperature in the given sub-control volume.
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inlineinherited |
Return the temperature in the domain at the given position.
globalPos | The position in global coordinates where the temperature should be specified. |
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inlineinherited |
Function for defining which phase is to be considered as the wetting phase.
element | The current element |
scv | The sub-control volume inside the element. |
elemSol | The solution at the dofs connected to the element. |
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inlineinherited |
Function for defining which phase is to be considered as the wetting phase.
globalPos | The global position |