opm-simulators/opm/simulators/wells/StandardWellPrimaryVariables.hpp
2022-11-22 13:11:17 +01:00

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7.1 KiB
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/*
Copyright 2017 SINTEF Digital, Mathematics and Cybernetics.
Copyright 2017 Statoil ASA.
Copyright 2016 - 2017 IRIS AS.
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 3 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/>.
*/
#ifndef OPM_STANDARDWELL_PRIMARY_VARIABLES_HEADER_INCLUDED
#define OPM_STANDARDWELL_PRIMARY_VARIABLES_HEADER_INCLUDED
#include <opm/material/densead/DynamicEvaluation.hpp>
#include <opm/simulators/wells/StandardWellEquations.hpp>
#include <vector>
namespace Opm
{
class DeferredLogger;
template<class FluidSystem, class Indices, class Scalar> class WellInterfaceIndices;
class WellState;
//! \brief Class holding primary variables for StandardWell.
template<class FluidSystem, class Indices, class Scalar>
class StandardWellPrimaryVariables {
protected:
// the positions of the primary variables for StandardWell
// the first one is the weighted total rate (WQ_t), the second and the third ones are F_w and F_g,
// which represent the fraction of Water and Gas based on the weighted total rate, the last one is BHP.
// correspondingly, we have four well equations for blackoil model, the first three are mass
// converstation equations, and the last one is the well control equation.
// primary variables related to other components, will be before the Bhp and after F_g.
// well control equation is always the last well equation.
// TODO: in the current implementation, we use the well rate as the first primary variables for injectors,
// instead of G_t.
// Table showing the primary variable indices, depending on what phases are present:
//
// WOG OG WG WO W/O/G (single phase)
// WQTotal 0 0 0 0 0
// WFrac 1 -1000 -1000 1 -1000
// GFrac 2 1 1 -1000 -1000
// Spres 3 2 2 2 1
//! \brief Number of the well control equations.
static constexpr int numWellControlEq = 1;
public:
//! \brief Number of the conservation equations.
static constexpr int numWellConservationEq = Indices::numPhases + Indices::numSolvents;
//! \brief Number of the well equations that will always be used.
//! \details Based on the solution strategy, there might be other well equations be introduced.
static constexpr int numStaticWellEq = numWellConservationEq + numWellControlEq;
static constexpr int WQTotal = 0; //!< The index for the weighted total rate
//! \brief The index for Bhp in primary variables and the index of well control equation.
//! \details They both will be the last one in their respective system.
//! \todo: We should have indices for the well equations and well primary variables separately.
static constexpr int Bhp = numStaticWellEq - numWellControlEq;
static constexpr bool has_wfrac_variable = Indices::waterEnabled && Indices::oilEnabled;
static constexpr bool has_gfrac_variable = Indices::gasEnabled && Indices::numPhases > 1;
static constexpr int WFrac = has_wfrac_variable ? 1 : -1000;
static constexpr int GFrac = has_gfrac_variable ? has_wfrac_variable + 1 : -1000;
static constexpr int SFrac = !Indices::enableSolvent ? -1000 : 3;
//! \brief Evaluation for the well equations.
using EvalWell = DenseAd::DynamicEvaluation<Scalar, numStaticWellEq + Indices::numEq + 1>;
using BVectorWell = typename StandardWellEquations<Scalar,Indices::numEq>::BVectorWell;
//! \brief Constructor initializes reference to well interface.
StandardWellPrimaryVariables(const WellInterfaceIndices<FluidSystem,Indices,Scalar>& well)
: well_(well)
{}
//! \brief Initialize evaluations from values.
void init();
//! \brief Resize values and evaluations.
void resize(const int numWellEq);
//! \brief Returns number of well equations.
int numWellEq() const { return numWellEq_; }
//! \brief Copy values from well state.
void update(const WellState& well_state, DeferredLogger& deferred_logger);
//! \brief Copy polymer molecular weigt values from well state.
void updatePolyMW(const WellState& well_state);
//! \brief Update values from newton update vector.
void updateNewton(const BVectorWell& dwells,
const double dFLimit,
const double dBHPLimit);
//! \brief Update polymer molecular weight values from newton update vector.
void updateNewtonPolyMW(const BVectorWell& dwells);
//! \brief Check that all values are finite.
void checkFinite(DeferredLogger& deferred_logger) const;
//! \brief Copy values to well state.
void copyToWellState(WellState& well_state, DeferredLogger& deferred_logger) const;
//! \brief Copy polymer molecular weight values to well state.
void copyToWellStatePolyMW(WellState& well_state) const;
//! \brief Returns scaled volume fraction for a component.
EvalWell volumeFractionScaled(const int compIdx) const;
//! \brief Returns surface volume fraction for a component.
EvalWell surfaceVolumeFraction(const int compIdx) const;
//! \brief Returns scaled rate for a component.
EvalWell getQs(const int compIdx) const;
//! \brief Returns a const ref to an evaluation.
Scalar value(const int idx) const
{ return value_[idx]; }
//! \brief Returns a const ref to an evaluation.
const EvalWell& eval(const int idx) const
{ return evaluation_[idx]; }
private:
//! \brief Calculate a relaxation factor for producers.
//! \details To avoid overshoot of the fractions which might result in negative rates.
double relaxationFactorFractionsProducer(const BVectorWell& dwells) const;
//! \brief Returns volume fraction for a component.
EvalWell volumeFraction(const unsigned compIdx) const;
//! \brief Handle non-reasonable fractions due to numerical overshoot.
void processFractions();
//! \brief The values for the primary variables.
//! \details Based on different solution strategies, the wells can have different primary variables.
std::vector<Scalar> value_;
//! \brief The Evaluation for the well primary variables.
//! \details Contain derivatives and are used in AD calculation
std::vector<EvalWell> evaluation_;
const WellInterfaceIndices<FluidSystem,Indices,Scalar>& well_; //!< Reference to well interface
//! \brief Total number of the well equations and primary variables.
//! \details There might be extra equations be used, numWellEq will be updated during the initialization
int numWellEq_ = numStaticWellEq;
};
}
#endif // OPM_STANDARDWELL_PRIMARY_VARIABLES_HEADER_INCLUDED