Opm::MiscibleMultiPhaseComposition< Scalar, FluidSystem, Evaluation > Class Template Reference

Computes the composition of all phases of a N-phase, N-component fluid system assuming that all N phases are present. More...

#include <MiscibleMultiPhaseComposition.hpp>

Static Public Member Functions
template<class FluidState, class ParameterCache>
static void	solve (FluidState &fluidState, ParameterCache &paramCache, int phasePresence, const MMPCAuxConstraint< Evaluation > *auxConstraints, unsigned numAuxConstraints, bool setViscosity, bool setInternalEnergy)
	Computes the composition of all phases of a N-phase, N-component fluid system assuming that all N phases are present.
template<class FluidState, class ParameterCache>
static void	solve (FluidState &fluidState, ParameterCache &paramCache, bool setViscosity, bool setInternalEnergy)
	Computes the composition of all phases of a N-phase, N-component fluid system assuming that all N phases are present.

Detailed Description

template<class Scalar, class FluidSystem, class Evaluation = Scalar>
class Opm::MiscibleMultiPhaseComposition< Scalar, FluidSystem, Evaluation >

Computes the composition of all phases of a N-phase, N-component fluid system assuming that all N phases are present.

The constraint solver assumes the following quantities to be set:

• temperatures of all phases
• saturations of all phases
• pressures of all phases

It also assumes that the mole/mass fractions of all phases sum up to 1. After calling the solve() method the following quantities are calculated in addition:

• temperature of all phases
• density, molar density, molar volume of all phases
• composition in mole and mass fractions and molarities of all phases
• mean molar masses of all phases
• fugacity coefficients of all components in all phases
• if the setViscosity parameter is true, also dynamic viscosities of all phases
• if the setInternalEnergy parameter is true, also specific enthalpies and internal energies of all phases

Member Function Documentation

solve() [1/2]

template<class Scalar, class FluidSystem, class Evaluation = Scalar>

template<class FluidState, class ParameterCache>

void Opm::MiscibleMultiPhaseComposition< Scalar, FluidSystem, Evaluation >::solve ( FluidState & fluidState, ParameterCache & paramCache, bool setViscosity, bool setInternalEnergy )

inlinestatic

Computes the composition of all phases of a N-phase, N-component fluid system assuming that all N phases are present.

This is a convenience method where no auxiliary constraints are used.

solve() [2/2]

template<class Scalar, class FluidSystem, class Evaluation = Scalar>

template<class FluidState, class ParameterCache>

void Opm::MiscibleMultiPhaseComposition< Scalar, FluidSystem, Evaluation >::solve ( FluidState & fluidState, ParameterCache & paramCache, int phasePresence, const MMPCAuxConstraint< Evaluation > * auxConstraints, unsigned numAuxConstraints, bool setViscosity, bool setInternalEnergy )

inlinestatic

Computes the composition of all phases of a N-phase, N-component fluid system assuming that all N phases are present.

The constraint solver assumes the following quantities to be set:

• temperatures of all phases
• saturations of all phases
• pressures of all phases

It also assumes that the mole/mass fractions of all phases sum up to 1. After calling the solve() method the following quantities are calculated in addition:

• temperature of all phases
• density, molar density, molar volume of all phases
• composition in mole and mass fractions and molarities of all phases
• mean molar masses of all phases
• fugacity coefficients of all components in all phases
• if the setViscosity parameter is true, also dynamic viscosities of all phases
• if the setInternalEnergy parameter is true, also specific enthalpies and internal energies of all phases

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

• opm/material/constraintsolvers/MiscibleMultiPhaseComposition.hpp