libopm-common/html/ConstantCompressibilityOilPvt_8hpp_source.html

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/*

  This file is part of the Open Porous Media project (OPM).


  OPM 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.


  OPM 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 OPM.  If not, see <http://www.gnu.org/licenses/>.


  Consult the COPYING file in the top-level source directory of this

  module for the precise wording of the license and the list of

  copyright holders.

*/

#ifndef OPM_CONSTANT_COMPRESSIBILITY_OIL_PVT_HPP

#define OPM_CONSTANT_COMPRESSIBILITY_OIL_PVT_HPP


#include <opm/material/densead/Math.hpp>


#include <cstddef>

#include <stdexcept>

#include <vector>


namespace Opm {


class EclipseState;

class Schedule;


template <class Scalar>


class ConstantCompressibilityOilPvt

{

public:

    void initFromState(const EclipseState& eclState, const Schedule&);


    void setNumRegions(std::size_t numRegions);


    void setVapPars(const Scalar, const Scalar)

    {

    }


    void setReferenceDensities(unsigned regionIdx,

                               Scalar rhoRefOil,

                               Scalar /*rhoRefGas*/,

                               Scalar /*rhoRefWater*/)

    { oilReferenceDensity_[regionIdx] = rhoRefOil; }


    void setViscosity(unsigned regionIdx, Scalar muo, Scalar oilViscosibility = 0.0)

    {

        oilViscosity_[regionIdx] = muo;

        oilViscosibility_[regionIdx] = oilViscosibility;

    }


    void setCompressibility(unsigned regionIdx, Scalar oilCompressibility)

    { oilCompressibility_[regionIdx] = oilCompressibility; }


    void setReferencePressure(unsigned regionIdx, Scalar p)

    { oilReferencePressure_[regionIdx] = p; }


    void setReferenceFormationVolumeFactor(unsigned regionIdx, Scalar BoRef)

    { oilReferenceFormationVolumeFactor_[regionIdx] = BoRef; }


    void setViscosibility(unsigned regionIdx, Scalar muComp)

    { oilViscosibility_[regionIdx] = muComp; }


    void initEnd()

    { }


    unsigned numRegions() const

    { return oilViscosity_.size(); }


    template <class Evaluation>


    Evaluation internalEnergy(unsigned,

                        const Evaluation&,

                        const Evaluation&,

                        const Evaluation&) const

    {

        throw std::runtime_error("Requested the enthalpy of oil but the thermal "

                                 "option is not enabled");

    }


    Scalar hVap(unsigned) const

    {

        throw std::runtime_error("Requested the hvap of oil but the thermal "

                                 "option is not enabled");

    }

    template <class Evaluation>


    Evaluation viscosity(unsigned regionIdx,

                         const Evaluation& temperature,

                         const Evaluation& pressure,

                         const Evaluation& /*Rs*/) const

    { return saturatedViscosity(regionIdx, temperature, pressure); }


    template <class Evaluation>


    Evaluation saturatedViscosity(unsigned regionIdx,

                                  const Evaluation& temperature,

                                  const Evaluation& pressure) const

    {

        Scalar BoMuoRef = oilViscosity_[regionIdx]*oilReferenceFormationVolumeFactor_[regionIdx];

        const Evaluation& bo = saturatedInverseFormationVolumeFactor(regionIdx, temperature, pressure);


        Scalar pRef = oilReferencePressure_[regionIdx];

        const Evaluation& Y =

            (oilCompressibility_[regionIdx] - oilViscosibility_[regionIdx])

            * (pressure - pRef);

        return BoMuoRef * bo / (1.0 + Y * (1.0 + Y / 2.0));

    }


    template <class Evaluation>


    Evaluation inverseFormationVolumeFactor(unsigned regionIdx,

                                            const Evaluation& temperature,

                                            const Evaluation& pressure,

                                            const Evaluation& /*Rs*/) const

    { return saturatedInverseFormationVolumeFactor(regionIdx, temperature, pressure); }


    template <class FluidState, class LhsEval = typename FluidState::ValueType>

    std::pair<LhsEval, LhsEval>


    inverseFormationVolumeFactorAndViscosity(const FluidState& fluidState, unsigned regionIdx)

    {

        const LhsEval& p = decay<LhsEval>(fluidState.pressure(FluidState::oilPhaseIdx));

        // Calculate bo(p).

        Scalar pRef = oilReferencePressure_[regionIdx];

        const LhsEval X = oilCompressibility_[regionIdx] * (p - pRef);

        Scalar BoRef = oilReferenceFormationVolumeFactor_[regionIdx];

        const LhsEval bo = (1.0 + X * (1.0 + X / 2.0)) / BoRef;

        // Calculate mu(p) as (Bo * mu) * bo. Recall bo = 1/Bo.

        const LhsEval Y = (oilCompressibility_[regionIdx] - oilViscosibility_[regionIdx]) * (p - pRef);

        Scalar BoMuoRef = oilViscosity_[regionIdx]*oilReferenceFormationVolumeFactor_[regionIdx];

        const LhsEval muo = BoMuoRef * bo / (1.0 + Y * (1.0 + Y / 2.0));

        return { bo, muo };

    }


    template <class Evaluation>


    Evaluation saturatedInverseFormationVolumeFactor(unsigned regionIdx,

                                                     const Evaluation& /*temperature*/,

                                                     const Evaluation& pressure) const

    {

        // cf. ECLiPSE 2011 technical description, p. 116

        Scalar pRef = oilReferencePressure_[regionIdx];

        const Evaluation& X = oilCompressibility_[regionIdx]*(pressure - pRef);


        Scalar BoRef = oilReferenceFormationVolumeFactor_[regionIdx];

        return (1 + X*(1 + X/2))/BoRef;

    }


    template <class Evaluation>


    Evaluation saturatedGasDissolutionFactor(unsigned /*regionIdx*/,

                                             const Evaluation& /*temperature*/,

                                             const Evaluation& /*pressure*/) const

    { return 0.0; /* this is dead oil! */ }


    template <class Evaluation>


    Evaluation saturatedGasDissolutionFactor(unsigned /*regionIdx*/,

                                             const Evaluation& /*temperature*/,

                                             const Evaluation& /*pressure*/,

                                             const Evaluation& /*oilSaturation*/,

                                             const Evaluation& /*maxOilSaturation*/) const

    { return 0.0; /* this is dead oil! */ }


    template <class Evaluation>


    Evaluation saturationPressure(unsigned /*regionIdx*/,

                                  const Evaluation& /*temperature*/,

                                  const Evaluation& /*Rs*/) const

    { return 0.0; /* this is dead oil, so there isn't any meaningful saturation pressure! */ }


    template <class Evaluation>

    Evaluation diffusionCoefficient(const Evaluation& /*temperature*/,

                                    const Evaluation& /*pressure*/,

                                    unsigned /*compIdx*/) const

    {

        throw std::runtime_error("Not implemented: The PVT model does not "

                                 "provide a diffusionCoefficient()");

    }


    Scalar oilReferenceDensity(unsigned regionIdx) const

    { return oilReferenceDensity_[regionIdx]; }


    const std::vector<Scalar>& oilReferenceFormationVolumeFactor() const

    { return oilReferenceFormationVolumeFactor_; }


    const std::vector<Scalar>& oilCompressibility() const

    { return oilCompressibility_; }


    const std::vector<Scalar>& oilViscosity() const

    { return oilViscosity_; }


    const std::vector<Scalar>& oilViscosibility() const

    { return oilViscosibility_; }


private:

    std::vector<Scalar> oilReferenceDensity_{};

    std::vector<Scalar> oilReferencePressure_{};

    std::vector<Scalar> oilReferenceFormationVolumeFactor_{};

    std::vector<Scalar> oilCompressibility_{};

    std::vector<Scalar> oilViscosity_{};

    std::vector<Scalar> oilViscosibility_{};

};


} // namespace Opm


#endif

Math.hpp
A number of commonly used algebraic functions for the localized OPM automatic differentiation (AD) fr...

Opm::ConstantCompressibilityOilPvt
This class represents the Pressure-Volume-Temperature relations of the oil phase without dissolved ga...
Definition ConstantCompressibilityOilPvt.hpp:47

Opm::ConstantCompressibilityOilPvt::internalEnergy
Evaluation internalEnergy(unsigned, const Evaluation &, const Evaluation &, const Evaluation &) const
Returns the specific enthalpy [J/kg] of oil given a set of parameters.
Definition ConstantCompressibilityOilPvt.hpp:122

Opm::ConstantCompressibilityOilPvt::saturationPressure
Evaluation saturationPressure(unsigned, const Evaluation &, const Evaluation &) const
Returns the saturation pressure of the oil phase [Pa] depending on its mass fraction of the gas compo...
Definition ConstantCompressibilityOilPvt.hpp:241

Opm::ConstantCompressibilityOilPvt::setViscosity
void setViscosity(unsigned regionIdx, Scalar muo, Scalar oilViscosibility=0.0)
Set the viscosity and "viscosibility" of the oil phase.
Definition ConstantCompressibilityOilPvt.hpp:76

Opm::ConstantCompressibilityOilPvt::initEnd
void initEnd()
Finish initializing the oil phase PVT properties.
Definition ConstantCompressibilityOilPvt.hpp:109

Opm::ConstantCompressibilityOilPvt::saturatedGasDissolutionFactor
Evaluation saturatedGasDissolutionFactor(unsigned, const Evaluation &, const Evaluation &, const Evaluation &, const Evaluation &) const
Returns the gas dissolution factor  [m^3/m^3] of the oil phase.
Definition ConstantCompressibilityOilPvt.hpp:226

Opm::ConstantCompressibilityOilPvt::inverseFormationVolumeFactorAndViscosity
std::pair< LhsEval, LhsEval > inverseFormationVolumeFactorAndViscosity(const FluidState &fluidState, unsigned regionIdx)
Returns the formation volume factor [-] and viscosity [Pa s] of the fluid phase.
Definition ConstantCompressibilityOilPvt.hpp:179

Opm::ConstantCompressibilityOilPvt::setReferencePressure
void setReferencePressure(unsigned regionIdx, Scalar p)
Set the oil reference pressure [Pa].
Definition ConstantCompressibilityOilPvt.hpp:91

Opm::ConstantCompressibilityOilPvt::setCompressibility
void setCompressibility(unsigned regionIdx, Scalar oilCompressibility)
Set the compressibility of the oil phase.
Definition ConstantCompressibilityOilPvt.hpp:85

Opm::ConstantCompressibilityOilPvt::viscosity
Evaluation viscosity(unsigned regionIdx, const Evaluation &temperature, const Evaluation &pressure, const Evaluation &) const
Returns the dynamic viscosity [Pa s] of gas saturated oil given a pressure and a phase composition.
Definition ConstantCompressibilityOilPvt.hpp:140

Opm::ConstantCompressibilityOilPvt::setReferenceDensities
void setReferenceDensities(unsigned regionIdx, Scalar rhoRefOil, Scalar, Scalar)
Initialize the reference densities of all fluids for a given PVT region.
Definition ConstantCompressibilityOilPvt.hpp:67

Opm::ConstantCompressibilityOilPvt::setViscosibility
void setViscosibility(unsigned regionIdx, Scalar muComp)
Set the oil "viscosibility" [1/ (Pa s)].
Definition ConstantCompressibilityOilPvt.hpp:103

Opm::ConstantCompressibilityOilPvt::initFromState
void initFromState(const EclipseState &eclState, const Schedule &)
Sets the pressure-dependent oil viscosity and density using the Eclipse PVCDO keyword.
Definition ConstantCompressibilityOilPvt.cpp:37

Opm::ConstantCompressibilityOilPvt::inverseFormationVolumeFactor
Evaluation inverseFormationVolumeFactor(unsigned regionIdx, const Evaluation &temperature, const Evaluation &pressure, const Evaluation &) const
Returns the formation volume factor [-] of the fluid phase.
Definition ConstantCompressibilityOilPvt.hpp:168

Opm::ConstantCompressibilityOilPvt::saturatedInverseFormationVolumeFactor
Evaluation saturatedInverseFormationVolumeFactor(unsigned regionIdx, const Evaluation &, const Evaluation &pressure) const
Returns the formation volume factor [-] of gas saturated oil.
Definition ConstantCompressibilityOilPvt.hpp:201

Opm::ConstantCompressibilityOilPvt::setReferenceFormationVolumeFactor
void setReferenceFormationVolumeFactor(unsigned regionIdx, Scalar BoRef)
Set the oil reference formation volume factor [-].
Definition ConstantCompressibilityOilPvt.hpp:97

Opm::ConstantCompressibilityOilPvt::saturatedGasDissolutionFactor
Evaluation saturatedGasDissolutionFactor(unsigned, const Evaluation &, const Evaluation &) const
Returns the gas dissolution factor  [m^3/m^3] of the oil phase.
Definition ConstantCompressibilityOilPvt.hpp:217

Opm::ConstantCompressibilityOilPvt::saturatedViscosity
Evaluation saturatedViscosity(unsigned regionIdx, const Evaluation &temperature, const Evaluation &pressure) const
Returns the dynamic viscosity [Pa s] of gas saturated oil given a pressure.
Definition ConstantCompressibilityOilPvt.hpp:150

Opm::ConstantCompressibilityOilPvt::numRegions
unsigned numRegions() const
Return the number of PVT regions which are considered by this PVT-object.
Definition ConstantCompressibilityOilPvt.hpp:115

Opm::EclipseState
Definition EclipseState.hpp:66

Opm::Schedule
Definition Schedule.hpp:101

Opm
This class implements a small container which holds the transmissibility mulitpliers for all the face...
Definition Exceptions.hpp:30