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adding StandardWell class

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copied from the old implementation, which is the starting point for the
new refactoring
This commit is contained in:
Kai Bao 2017-06-15 11:41:03 +02:00
parent 910fe0318c
commit 0cf6699591
3 changed files with 420 additions and 0 deletions
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2
CMakeLists_files.cmake
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@ -50,6 +50,7 @@ list (APPEND MAIN_SOURCE_FILES
opm/autodiff/WellMultiSegment.cpp
opm/autodiff/MultisegmentWells.cpp
opm/autodiff/WellInterface.cpp
opm/autodiff/StandardWell.hpp
opm/autodiff/MissingFeatures.cpp
opm/polymer/PolymerState.cpp
opm/polymer/PolymerBlackoilState.cpp
@ -241,6 +242,7 @@ list (APPEND PUBLIC_HEADER_FILES
opm/autodiff/StandardWells.hpp
opm/autodiff/StandardWells_impl.hpp
opm/autodiff/WellInterface.hpp
opm/autodiff/StandardWell.cpp
opm/autodiff/StandardWellsDense.hpp
opm/autodiff/StandardWellsSolvent.hpp
opm/autodiff/StandardWellsSolvent_impl.hpp

292
opm/autodiff/StandardWell.cpp Normal file
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@ -0,0 +1,292 @@
/*
Copyright 2017 SINTEF ICT, Applied Mathematics.
Copyright 2017 Statoil ASA.
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/>.
*/
#include "config.h"
#include <opm/autodiff/StandardWell.hpp>
namespace Opm
{
StandardWell::
StandardWell(const Well* well, const size_t time_step, const Wells* wells)
: WellInterface(well, time_step, wells)
, perf_densities_(number_of_perforations_)
, perf_pressure_diffs_(number_of_perforations_)
, well_variables_(blocksize) // the number of the primary variables
{
dune_B_.setBuildMode( Mat::row_wise );
dune_C_.setBuildMode( Mat::row_wise );
inv_dune_D_.setBuildMode( Mat::row_wise );
}
const std::vector<double>&
StandardWell::
perfDensities() const
{
return perf_densities_;
}
std::vector<double>&
StandardWell::
perfDensities()
{
return perf_densities_;
}
const std::vector<double>&
StandardWell::
perfPressureDiffs() const
{
return perf_pressure_diffs_;
}
std::vector<double>&
StandardWell::
perfPressureDiffs()
{
return perf_pressure_diffs_;
}
void
StandardWell::
assembleWellEq(Simulator& ebos_simulator,
const double dt,
WellState& well_state,
bool only_wells)
{
}
void StandardWell::
setWellVariables(const WellState& well_state)
{
const int np = number_of_phases_;
const int nw = well_state.bhp().size();
// TODO: it should be the number of primary variables
// TODO: this is from the old version of StandardWellsDense, it is a coincidence, 3 phases and 3 primary variables
// TODO: it needs to be careful.
// TODO: the following code has to be rewritten later for correctness purpose.
for (int phase = 0; phase < np; ++phase) {
well_variables_[phase] = 0.0;
well_variables_[phase].setValue(well_state.wellSolutions()[index_of_well_ + nw * phase]);
well_variables_[phase].setDerivative(blocksize + phase, 1.0);
}
}
StandardWell::EvalWell
StandardWell::
getBhp() const
{
const WellControls* wc = well_controls_;
if (well_controls_get_current_type(wc) == BHP) {
EvalWell bhp = 0.0;
const double target_rate = well_controls_get_current_target(wc);
bhp.setValue(target_rate);
return bhp;
} else if (well_controls_get_current_type(wc) == THP) {
const int control = well_controls_get_current(wc);
const double thp = well_controls_get_current_target(wc);
const double alq = well_controls_iget_alq(wc, control);
const int table_id = well_controls_iget_vfp(wc, control);
EvalWell aqua = 0.0;
EvalWell liquid = 0.0;
EvalWell vapour = 0.0;
EvalWell bhp = 0.0;
double vfp_ref_depth = 0.0;
const Opm::PhaseUsage& pu = phaseUsage();
if (active()[ Water ]) {
aqua = getQs(pu.phase_pos[ Water]);
}
if (active()[ Oil ]) {
liquid = getQs(pu.phase_pos[ Oil ]);
}
if (active()[ Gas ]) {
vapour = getQs(pu.phase_pos[ Gas ]);
}
if (wellType() == INJECTOR) {
bhp = vfp_properties_->getInj()->bhp(table_id, aqua, liquid, vapour, thp);
vfp_ref_depth = vfp_properties_->getInj()->getTable(table_id)->getDatumDepth();
} else {
bhp = vfp_properties_->getProd()->bhp(table_id, aqua, liquid, vapour, thp, alq);
vfp_ref_depth = vfp_properties_->getProd()->getTable(table_id)->getDatumDepth();
}
// pick the density in the top layer
const double rho = perf_densities_[0];
// TODO: not sure whether it is always correct
const double well_ref_depth = perf_depth_[0];
// const double dp = wellhelpers::computeHydrostaticCorrection(wells(), wellIdx, vfp_ref_depth, rho, gravity_);
const double dp = wellhelpers::computeHydrostaticCorrection(well_ref_depth, vfp_ref_depth, rho, gravity_);
bhp -= dp;
return bhp;
}
return well_variables_[XvarWell];
}
StandardWell::EvalWell
StandardWell::
getQs(const int phase) const
{
EvalWell qs = 0.0;
const WellControls* wc = well_controls_;
const int np = number_of_phases_;
// the target from the well controls
const double target = well_controls_get_current_target(wc);
// TODO: the formulation for the injectors decides it only work with single phase
// surface rate injection control. Improvement will be required.
// Injectors
if (wellType() == INJECTOR) {
// TODO: we should not rely on comp_frac anymore, it should depend on the values in distr
const double comp_frac = wells().comp_frac[np*wellIdx + phaseIdx];
if (comp_frac == 0.0) {
return qs;
}
if (well_controls_get_current_type(wc) == BHP || well_controls_get_current_type(wc) == THP) {
return wellVariables_[XvarWell];
}
// rate control
// TODO: if it is reservoir volume rate, it should be wrong here
qs.setValue(target);
return qs;
}
// Producers
if (well_controls_get_current_type(wc) == BHP || well_controls_get_current_type(wc) == THP ) {
return wellVariables_[XvarWell] * wellVolumeFractionScaled(phase);
}
}
StandardWell::EvalWell
StandardWell::
wellVolumeFractionScaled(const int phase) const
{
// TODO: we should be able to set the g for the well based on the control type
// instead of using explicit code for g all the times
const WellControls* wc = well_controls_;
if (well_controls_get_current_type(wc) == RESERVOIR_RATE) {
const double* distr = well_controls_get_current_distr(wc);
if (distr[phase] > 0.) {
return wellVolumeFraction(phase) / distr[phase];
} else {
// TODO: not sure why return EvalWell(0.) causing problem here
// Probably due to the wrong Jacobians.
return wellVolumeFraction(phase);
}
}
std::vector<double> g = {1,1,0.01};
return (wellVolumeFraction(phase) / g[phase]);
}
StandardWell::EvalWell
StandardWell::
wellVolumeFraction(const int phase) const
{
if (phase == Water) {
return wellVariables_[WFrac];
}
if (phase == Gas) {
return wellVariables_[GFrac];
}
// Oil fraction
EvalWell well_fraction = 1.0;
if (active_[Water]) {
well_fraction -= wellVariables_[WFrac];
}
if (active_[Gas]) {
well_fraction -= wellVariables_[GFrac];
}
return well_fraction;
}
StandardWell::EvalWell
StandardWell::
wellSurfaceVolumeFraction(const int phase) const
{
EvalWell sum_volume_fraction_scaled = 0.;
const int np = number_of_phases_;
for (int p = 0; p < np; ++p) {
sum_volume_fraction_scaled += wellVolumeFractionScaled(p);
}
assert(sum_volume_fraction_scaled.value() != 0.);
return wellVolumeFractionScaled(phase) / sum_volume_fraction_scaled;
}
}

126
opm/autodiff/StandardWell.hpp Normal file
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@ -0,0 +1,126 @@
/*
Copyright 2017 SINTEF ICT, Applied Mathematics.
Copyright 2017 Statoil ASA.
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_HEADER_INCLUDED
#define OPM_STANDARDWELL_HEADER_INCLUDED
#include "config.h"
#include <opm/autodiff/WellInterface.hpp>
#include<dune/common/fmatrix.hh>
#include<dune/istl/bcrsmatrix.hh>
#include<dune/istl/matrixmatrix.hh>
#include <opm/material/densead/Math.hpp>
#include <opm/material/densead/Evaluation.hpp>
namespace Opm
{
class StandardWell: public WellInterface
{
public:
using WellInterface::Simulator;
using WellInterface::WellState;
// the positions of the primary variables for StandardWell
// there are three primary variables, the second and the third ones are F_w and F_g
// the first one can be total rate (G_t) or bhp, based on the control
enum WellVariablePositions {
XvarWell = 0,
WFrac = 1,
GFrac = 2
};
// for now, using the matrix and block version in StandardWellsDense.
// TODO: for bettern generality, it should contain blocksize_field and blocksize_well.
// They are allowed to be different and it will create four types of matrix blocks and two types of
// vector blocks.
/* const static int blocksize = 3;
typedef double Scalar;
typedef Dune::FieldVector<Scalar, blocksize > VectorBlockType;
typedef Dune::FieldMatrix<Scalar, blocksize, blocksize > MatrixBlockType;
typedef Dune::BCRSMatrix <MatrixBlockType> Mat;
typedef Dune::BlockVector<VectorBlockType> BVector;
typedef DenseAd::Evaluation<double, blocksize + blocksize> EvalWell; */
/* using WellInterface::EvalWell;
using WellInterface::BVector;
using WellInterface::Mat;
using WellInterface::MatrixBlockType;
using WellInterface::VectorBlockType; */
StandardWell(const Well* well, const size_t time_step, const Wells* wells);
/// the densities of the fluid in each perforation
virtual const std::vector<double>& perfDensities() const;
virtual std::vector<double>& perfDensities();
/// the pressure difference between different perforations
virtual const std::vector<double>& perfPressureDiffs() const;
virtual std::vector<double>& perfPressureDiffs();
virtual void assembleWellEq(Simulator& ebos_simulator,
const double dt,
WellState& well_state,
bool only_wells);
virtual void setWellVariables(const WellState& well_state);
EvalWell wellVolumeFractionScaled(const int phase) const;
EvalWell wellVolumeFraction(const int phase) const;
EvalWell wellSurfaceVolumeFraction(const int phase) const;
protected:
// densities of the fluid in each perforation
std::vector<double> perf_densities_;
// pressure drop between different perforations
std::vector<double> perf_pressure_diffs_;
// TODO: probably, they should be moved to the WellInterface, when
// we decide the template paramters.
// two off-diagonal matrices
Mat dune_B_;
Mat dune_C_;
// diagonal matrix for the well
Mat inv_dune_D_;
BVector res_well_;
std::vector<EvalWell> well_variables_;
// TODO: this function should be moved to the base class.
// while it faces chanllenges for MSWell later, since the calculation of bhp
// based on THP is never implemented for MSWell yet.
EvalWell getBhp() const;
// TODO: it is also possible to be moved to the base class.
EvalWell getQs(const int phase) const;
};
}
#endif // OPM_STANDARDWELL_HEADER_INCLUDED