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Opm::ImmiscibleFlash< Scalar, FluidSystem > Class Template Reference

Determines the pressures and saturations of all fluid phases given the total mass of all components. More...

#include <ImmiscibleFlash.hpp>

Static Public Member Functions

template<class FluidState , class Evaluation = typename FluidState::Scalar>
static void guessInitial (FluidState &fluidState, const Dune::FieldVector< Evaluation, numComponents > &)
 Guess initial values for all quantities.
 
template<class MaterialLaw , class FluidState >
static void solve (FluidState &fluidState, const typename MaterialLaw::Params &matParams, typename FluidSystem::template ParameterCache< typename FluidState::Scalar > &paramCache, const Dune::FieldVector< typename FluidState::Scalar, numComponents > &globalMolarities, Scalar tolerance=-1)
 Calculates the chemical equilibrium from the component fugacities in a phase. More...
 

Static Protected Member Functions

template<class FluidState >
static void printFluidState_ (const FluidState &fs)
 
template<class MaterialLaw , class InputFluidState , class FlashFluidState >
static void assignFlashFluidState_ (const InputFluidState &inputFluidState, FlashFluidState &flashFluidState, const typename MaterialLaw::Params &matParams, typename FluidSystem::template ParameterCache< typename FlashFluidState::Scalar > &flashParamCache)
 
template<class FlashFluidState , class OutputFluidState >
static void assignOutputFluidState_ (const FlashFluidState &flashFluidState, OutputFluidState &outputFluidState)
 
template<class FluidState >
static void solveAllIncompressible_ (FluidState &fluidState, typename FluidSystem::template ParameterCache< typename FluidState::Scalar > &paramCache, const Dune::FieldVector< typename FluidState::Scalar, numComponents > &globalMolarities)
 
template<class FluidState , class FlashDefectVector , class FlashComponentVector >
static void evalDefect_ (FlashDefectVector &b, const FluidState &fluidState, const FlashComponentVector &globalMolarities)
 
template<class MaterialLaw , class FlashFluidState , class EvalVector >
static Scalar update_ (FlashFluidState &fluidState, typename FluidSystem::template ParameterCache< typename FlashFluidState::Scalar > &paramCache, const typename MaterialLaw::Params &matParams, const EvalVector &deltaX)
 
template<class MaterialLaw , class FlashFluidState >
static void completeFluidState_ (FlashFluidState &flashFluidState, typename FluidSystem::template ParameterCache< typename FlashFluidState::Scalar > &paramCache, const typename MaterialLaw::Params &matParams)
 
static bool isPressureIdx_ (unsigned pvIdx)
 
static bool isSaturationIdx_ (unsigned pvIdx)
 
template<class FluidState >
static const FluidState::Scalar & getQuantity_ (const FluidState &fluidState, unsigned pvIdx)
 
template<class FluidState >
static void setQuantity_ (FluidState &fluidState, unsigned pvIdx, const typename FluidState::Scalar &value)
 
template<class FluidState >
static Scalar quantityWeight_ (const FluidState &, unsigned pvIdx)
 

Detailed Description

template<class Scalar, class FluidSystem>
class Opm::ImmiscibleFlash< Scalar, FluidSystem >

Determines the pressures and saturations of all fluid phases given the total mass of all components.

In a N-phase, N-component context, we have the following unknowns if assuming immiscibility:

  • N pressures
  • N saturations

This sums up to 2*N unknowns. On the equations side of things, we have:

  • N total component molarities
  • 1 The sum of all saturations is 1
  • N-1 Relations from capillary pressure

this also sums up to 2*N. We include the capillary pressures and the sum of the saturations explicitly. This means that we only solve for the first pressure and N-1 saturations.

If a fluid phase is incompressible, the pressure cannot determined by this, though. In this case the original pressure is kept, and the saturation of the phase is calculated by dividing the global molarity of the component by the phase density.

Member Function Documentation

◆ solve()

template<class Scalar , class FluidSystem >
template<class MaterialLaw , class FluidState >
static void Opm::ImmiscibleFlash< Scalar, FluidSystem >::solve ( FluidState &  fluidState,
const typename MaterialLaw::Params &  matParams,
typename FluidSystem::template ParameterCache< typename FluidState::Scalar > &  paramCache,
const Dune::FieldVector< typename FluidState::Scalar, numComponents > &  globalMolarities,
Scalar  tolerance = -1 
)
inlinestatic

Calculates the chemical equilibrium from the component fugacities in a phase.

The phase's fugacities must already be set.


The documentation for this class was generated from the following file: