opm-simulators/opm/simulators/wells/StandardWell_impl.hpp
Håkon Hægland fbb24e2a5a Check group limits in gas lift stage 1.
Check group limits in gas lift stage 1 to avoid adding too much ALQ which must
anyway later be removed in stage 2. This should make the optimization
more efficient for small ALQ increment values. Also adds MPI support.
2021-06-16 12:00:54 +02:00

2193 lines
93 KiB
C++

/*
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/>.
*/
#include <opm/common/utility/numeric/RootFinders.hpp>
#include <opm/parser/eclipse/EclipseState/Schedule/Well/WellInjectionProperties.hpp>
#include <opm/simulators/utils/DeferredLoggingErrorHelpers.hpp>
#include <opm/simulators/linalg/MatrixBlock.hpp>
#include <opm/simulators/wells/VFPHelpers.hpp>
#include <algorithm>
#include <functional>
#include <numeric>
namespace Opm
{
template<typename TypeTag>
StandardWell<TypeTag>::
StandardWell(const Well& well,
const ParallelWellInfo& pw_info,
const int time_step,
const ModelParameters& param,
const RateConverterType& rate_converter,
const int pvtRegionIdx,
const int num_components,
const int num_phases,
const int index_of_well,
const std::vector<PerforationData>& perf_data)
: Base(well, pw_info, time_step, param, rate_converter, pvtRegionIdx, num_components, num_phases, index_of_well, perf_data)
, StdWellEval(static_cast<const WellInterfaceIndices<FluidSystem,Indices,Scalar>&>(*this))
{
assert(num_components_ == numWellConservationEq);
}
template<typename TypeTag>
void
StandardWell<TypeTag>::
init(const PhaseUsage* phase_usage_arg,
const std::vector<double>& depth_arg,
const double gravity_arg,
const int num_cells,
const std::vector< Scalar >& B_avg)
{
Base::init(phase_usage_arg, depth_arg, gravity_arg, num_cells, B_avg);
this->StdWellEval::init(perf_depth_, depth_arg, num_cells, Base::has_polymermw);
}
template<typename TypeTag>
void StandardWell<TypeTag>::
initPrimaryVariablesEvaluation() const
{
this->StdWellEval::initPrimaryVariablesEvaluation();
}
template<typename TypeTag>
typename StandardWell<TypeTag>::Eval
StandardWell<TypeTag>::getPerfCellPressure(const typename StandardWell<TypeTag>::FluidState& fs) const
{
Eval pressure;
if (Indices::oilEnabled) {
pressure = fs.pressure(FluidSystem::oilPhaseIdx);
} else {
if (Indices::waterEnabled) {
pressure = fs.pressure(FluidSystem::waterPhaseIdx);
} else {
pressure = fs.pressure(FluidSystem::gasPhaseIdx);
}
}
return pressure;
}
template<typename TypeTag>
void
StandardWell<TypeTag>::
computePerfRate(const IntensiveQuantities& intQuants,
const std::vector<EvalWell>& mob,
const EvalWell& bhp,
const double Tw,
const int perf,
const bool allow_cf,
std::vector<EvalWell>& cq_s,
double& perf_dis_gas_rate,
double& perf_vap_oil_rate,
DeferredLogger& deferred_logger) const
{
const auto& fs = intQuants.fluidState();
const EvalWell pressure = this->extendEval(getPerfCellPressure(fs));
const EvalWell rs = this->extendEval(fs.Rs());
const EvalWell rv = this->extendEval(fs.Rv());
std::vector<EvalWell> b_perfcells_dense(num_components_, EvalWell{this->numWellEq_ + numEq, 0.0});
for (unsigned phaseIdx = 0; phaseIdx < FluidSystem::numPhases; ++phaseIdx) {
if (!FluidSystem::phaseIsActive(phaseIdx)) {
continue;
}
const unsigned compIdx = Indices::canonicalToActiveComponentIndex(FluidSystem::solventComponentIndex(phaseIdx));
b_perfcells_dense[compIdx] = this->extendEval(fs.invB(phaseIdx));
}
if constexpr (has_solvent) {
b_perfcells_dense[contiSolventEqIdx] = this->extendEval(intQuants.solventInverseFormationVolumeFactor());
}
if constexpr (has_zFraction) {
if (this->isInjector()) {
const unsigned gasCompIdx = Indices::canonicalToActiveComponentIndex(FluidSystem::gasCompIdx);
b_perfcells_dense[gasCompIdx] *= (1.0 - wsolvent());
b_perfcells_dense[gasCompIdx] += wsolvent()*intQuants.zPureInvFormationVolumeFactor().value();
}
}
this->StdWellEval::computePerfRate(mob,
pressure,
bhp,
rs,
rv,
b_perfcells_dense,
Tw,
perf,
allow_cf,
has_polymermw,
cq_s,
perf_dis_gas_rate,
perf_vap_oil_rate,
deferred_logger);
}
template<typename TypeTag>
void
StandardWell<TypeTag>::
assembleWellEqWithoutIteration(const Simulator& ebosSimulator,
const double dt,
const Well::InjectionControls& /*inj_controls*/,
const Well::ProductionControls& /*prod_controls*/,
WellState& well_state,
const GroupState& group_state,
DeferredLogger& deferred_logger)
{
// TODO: only_wells should be put back to save some computation
// for example, the matrices B C does not need to update if only_wells
if (!this->isOperable() && !this->wellIsStopped()) return;
// clear all entries
this->duneB_ = 0.0;
this->duneC_ = 0.0;
this->invDuneD_ = 0.0;
this->resWell_ = 0.0;
assembleWellEqWithoutIterationImpl(ebosSimulator, dt, well_state, group_state, deferred_logger);
}
template<typename TypeTag>
void
StandardWell<TypeTag>::
assembleWellEqWithoutIterationImpl(const Simulator& ebosSimulator,
const double dt,
WellState& well_state,
const GroupState& group_state,
DeferredLogger& deferred_logger)
{
// TODO: it probably can be static member for StandardWell
const double volume = 0.002831684659200; // 0.1 cu ft;
// the solution gas rate and solution oil rate needs to be reset to be zero for well_state.
well_state.wellVaporizedOilRates(index_of_well_) = 0.;
well_state.wellDissolvedGasRates(index_of_well_) = 0.;
const int np = number_of_phases_;
std::vector<RateVector> connectionRates = connectionRates_; // Copy to get right size.
auto& perf_data = well_state.perfData(this->index_of_well_);
auto& perf_rates = perf_data.phase_rates;
for (int perf = 0; perf < number_of_perforations_; ++perf) {
// Calculate perforation quantities.
std::vector<EvalWell> cq_s(num_components_, {this->numWellEq_ + numEq, 0.0});
EvalWell water_flux_s{this->numWellEq_ + numEq, 0.0};
EvalWell cq_s_zfrac_effective{this->numWellEq_ + numEq, 0.0};
calculateSinglePerf(ebosSimulator, perf, well_state, connectionRates, cq_s, water_flux_s, cq_s_zfrac_effective, deferred_logger);
// Equation assembly for this perforation.
if constexpr (has_polymer && Base::has_polymermw) {
if (this->isInjector()) {
handleInjectivityEquations(ebosSimulator, well_state, perf, water_flux_s, deferred_logger);
}
}
const int cell_idx = well_cells_[perf];
for (int componentIdx = 0; componentIdx < num_components_; ++componentIdx) {
// the cq_s entering mass balance equations need to consider the efficiency factors.
const EvalWell cq_s_effective = cq_s[componentIdx] * well_efficiency_factor_;
connectionRates[perf][componentIdx] = Base::restrictEval(cq_s_effective);
// subtract sum of phase fluxes in the well equations.
this->resWell_[0][componentIdx] += cq_s_effective.value();
// assemble the jacobians
for (int pvIdx = 0; pvIdx < this->numWellEq_; ++pvIdx) {
// also need to consider the efficiency factor when manipulating the jacobians.
this->duneC_[0][cell_idx][pvIdx][componentIdx] -= cq_s_effective.derivative(pvIdx+numEq); // intput in transformed matrix
this->invDuneD_[0][0][componentIdx][pvIdx] += cq_s_effective.derivative(pvIdx+numEq);
}
for (int pvIdx = 0; pvIdx < numEq; ++pvIdx) {
this->duneB_[0][cell_idx][componentIdx][pvIdx] += cq_s_effective.derivative(pvIdx);
}
// Store the perforation phase flux for later usage.
if (has_solvent && componentIdx == contiSolventEqIdx) {
auto& perf_rate_solvent = perf_data.solvent_rates;
perf_rate_solvent[perf] = cq_s[componentIdx].value();
} else {
perf_rates[perf*np + ebosCompIdxToFlowCompIdx(componentIdx)] = cq_s[componentIdx].value();
}
}
if constexpr (has_zFraction) {
for (int pvIdx = 0; pvIdx < this->numWellEq_; ++pvIdx) {
this->duneC_[0][cell_idx][pvIdx][contiZfracEqIdx] -= cq_s_zfrac_effective.derivative(pvIdx+numEq);
}
}
}
// Update the connection
connectionRates_ = connectionRates;
// accumulate resWell_ and invDuneD_ in parallel to get effects of all perforations (might be distributed)
wellhelpers::sumDistributedWellEntries(this->invDuneD_[0][0], this->resWell_[0],
this->parallel_well_info_.communication());
// add vol * dF/dt + Q to the well equations;
for (int componentIdx = 0; componentIdx < numWellConservationEq; ++componentIdx) {
// TODO: following the development in MSW, we need to convert the volume of the wellbore to be surface volume
// since all the rates are under surface condition
EvalWell resWell_loc(this->numWellEq_ + numEq, 0.0);
if (FluidSystem::numActivePhases() > 1) {
assert(dt > 0);
resWell_loc += (this->wellSurfaceVolumeFraction(componentIdx) - this->F0_[componentIdx]) * volume / dt;
}
resWell_loc -= this->getQs(componentIdx) * well_efficiency_factor_;
for (int pvIdx = 0; pvIdx < this->numWellEq_; ++pvIdx) {
this->invDuneD_[0][0][componentIdx][pvIdx] += resWell_loc.derivative(pvIdx+numEq);
}
this->resWell_[0][componentIdx] += resWell_loc.value();
}
const auto& summaryState = ebosSimulator.vanguard().summaryState();
const Schedule& schedule = ebosSimulator.vanguard().schedule();
this->assembleControlEq(well_state, group_state, schedule, summaryState, deferred_logger);
// do the local inversion of D.
try {
Dune::ISTLUtility::invertMatrix(this->invDuneD_[0][0]);
} catch( ... ) {
OPM_DEFLOG_THROW(NumericalIssue,"Error when inverting local well equations for well " + name(), deferred_logger);
}
}
template<typename TypeTag>
void
StandardWell<TypeTag>::
calculateSinglePerf(const Simulator& ebosSimulator,
const int perf,
WellState& well_state,
std::vector<RateVector>& connectionRates,
std::vector<EvalWell>& cq_s,
EvalWell& water_flux_s,
EvalWell& cq_s_zfrac_effective,
DeferredLogger& deferred_logger) const
{
const bool allow_cf = getAllowCrossFlow() || openCrossFlowAvoidSingularity(ebosSimulator);
const EvalWell& bhp = this->getBhp();
const int cell_idx = well_cells_[perf];
const auto& intQuants = *(ebosSimulator.model().cachedIntensiveQuantities(cell_idx, /*timeIdx=*/ 0));
std::vector<EvalWell> mob(num_components_, {this->numWellEq_ + numEq, 0.});
getMobility(ebosSimulator, perf, mob, deferred_logger);
double perf_dis_gas_rate = 0.;
double perf_vap_oil_rate = 0.;
double trans_mult = ebosSimulator.problem().template rockCompTransMultiplier<double>(intQuants, cell_idx);
const double Tw = well_index_[perf] * trans_mult;
computePerfRate(intQuants, mob, bhp, Tw, perf, allow_cf,
cq_s, perf_dis_gas_rate, perf_vap_oil_rate, deferred_logger);
auto& perf_data = well_state.perfData(this->index_of_well_);
if constexpr (has_polymer && Base::has_polymermw) {
if (this->isInjector()) {
// Store the original water flux computed from the reservoir quantities.
// It will be required to assemble the injectivity equations.
const unsigned water_comp_idx = Indices::canonicalToActiveComponentIndex(FluidSystem::waterCompIdx);
water_flux_s = cq_s[water_comp_idx];
// Modify the water flux for the rest of this function to depend directly on the
// local water velocity primary variable.
handleInjectivityRate(ebosSimulator, perf, cq_s);
}
}
// updating the solution gas rate and solution oil rate
if (this->isProducer()) {
well_state.wellDissolvedGasRates(index_of_well_) += perf_dis_gas_rate;
well_state.wellVaporizedOilRates(index_of_well_) += perf_vap_oil_rate;
}
if constexpr (has_energy) {
connectionRates[perf][contiEnergyEqIdx] = 0.0;
}
if constexpr (has_energy) {
auto fs = intQuants.fluidState();
for (unsigned phaseIdx = 0; phaseIdx < FluidSystem::numPhases; ++phaseIdx) {
if (!FluidSystem::phaseIsActive(phaseIdx)) {
continue;
}
const unsigned activeCompIdx = Indices::canonicalToActiveComponentIndex(FluidSystem::solventComponentIndex(phaseIdx));
// convert to reservoar conditions
EvalWell cq_r_thermal(this->numWellEq_ + numEq, 0.);
if (FluidSystem::phaseIsActive(FluidSystem::oilPhaseIdx) && FluidSystem::phaseIsActive(FluidSystem::gasPhaseIdx)) {
if(FluidSystem::waterPhaseIdx == phaseIdx)
cq_r_thermal = cq_s[activeCompIdx] / this->extendEval(fs.invB(phaseIdx));
// remove dissolved gas and vapporized oil
const unsigned oilCompIdx = Indices::canonicalToActiveComponentIndex(FluidSystem::oilCompIdx);
const unsigned gasCompIdx = Indices::canonicalToActiveComponentIndex(FluidSystem::gasCompIdx);
// q_os = q_or * b_o + rv * q_gr * b_g
// q_gs = q_gr * g_g + rs * q_or * b_o
// d = 1.0 - rs * rv
const EvalWell d = this->extendEval(1.0 - fs.Rv() * fs.Rs());
// q_gr = 1 / (b_g * d) * (q_gs - rs * q_os)
if(FluidSystem::gasPhaseIdx == phaseIdx)
cq_r_thermal = (cq_s[gasCompIdx] - this->extendEval(fs.Rs()) * cq_s[oilCompIdx]) / (d * this->extendEval(fs.invB(phaseIdx)) );
// q_or = 1 / (b_o * d) * (q_os - rv * q_gs)
if(FluidSystem::oilPhaseIdx == phaseIdx)
cq_r_thermal = (cq_s[oilCompIdx] - this->extendEval(fs.Rv()) * cq_s[gasCompIdx]) / (d * this->extendEval(fs.invB(phaseIdx)) );
} else {
cq_r_thermal = cq_s[activeCompIdx] / this->extendEval(fs.invB(phaseIdx));
}
// change temperature for injecting fluids
if (this->isInjector() && cq_s[activeCompIdx] > 0.0){
// only handles single phase injection now
assert(this->well_ecl_.injectorType() != InjectorType::MULTI);
fs.setTemperature(this->well_ecl_.temperature());
typedef typename std::decay<decltype(fs)>::type::Scalar FsScalar;
typename FluidSystem::template ParameterCache<FsScalar> paramCache;
const unsigned pvtRegionIdx = intQuants.pvtRegionIndex();
paramCache.setRegionIndex(pvtRegionIdx);
paramCache.setMaxOilSat(ebosSimulator.problem().maxOilSaturation(cell_idx));
paramCache.updatePhase(fs, phaseIdx);
const auto& rho = FluidSystem::density(fs, paramCache, phaseIdx);
fs.setDensity(phaseIdx, rho);
const auto& h = FluidSystem::enthalpy(fs, paramCache, phaseIdx);
fs.setEnthalpy(phaseIdx, h);
}
// compute the thermal flux
cq_r_thermal *= this->extendEval(fs.enthalpy(phaseIdx)) * this->extendEval(fs.density(phaseIdx));
connectionRates[perf][contiEnergyEqIdx] += Base::restrictEval(cq_r_thermal);
}
}
if constexpr (has_polymer) {
// TODO: the application of well efficiency factor has not been tested with an example yet
const unsigned waterCompIdx = Indices::canonicalToActiveComponentIndex(FluidSystem::waterCompIdx);
EvalWell cq_s_poly = cq_s[waterCompIdx];
if (this->isInjector()) {
cq_s_poly *= wpolymer();
} else {
cq_s_poly *= this->extendEval(intQuants.polymerConcentration() * intQuants.polymerViscosityCorrection());
}
// Note. Efficiency factor is handled in the output layer
auto& perf_rate_polymer = perf_data.polymer_rates;
perf_rate_polymer[perf] = cq_s_poly.value();
cq_s_poly *= well_efficiency_factor_;
connectionRates[perf][contiPolymerEqIdx] = Base::restrictEval(cq_s_poly);
if constexpr (Base::has_polymermw) {
updateConnectionRatePolyMW(cq_s_poly, intQuants, well_state, perf, connectionRates, deferred_logger);
}
}
if constexpr (has_foam) {
// TODO: the application of well efficiency factor has not been tested with an example yet
const unsigned gasCompIdx = Indices::canonicalToActiveComponentIndex(FluidSystem::gasCompIdx);
EvalWell cq_s_foam = cq_s[gasCompIdx] * well_efficiency_factor_;
if (this->isInjector()) {
cq_s_foam *= wfoam();
} else {
cq_s_foam *= this->extendEval(intQuants.foamConcentration());
}
connectionRates[perf][contiFoamEqIdx] = Base::restrictEval(cq_s_foam);
}
if constexpr (has_zFraction) {
// TODO: the application of well efficiency factor has not been tested with an example yet
const unsigned gasCompIdx = Indices::canonicalToActiveComponentIndex(FluidSystem::gasCompIdx);
cq_s_zfrac_effective = cq_s[gasCompIdx];
if (this->isInjector()) {
cq_s_zfrac_effective *= wsolvent();
} else if (cq_s_zfrac_effective.value() != 0.0) {
const double dis_gas_frac = perf_dis_gas_rate / cq_s_zfrac_effective.value();
cq_s_zfrac_effective *= this->extendEval(dis_gas_frac*intQuants.xVolume() + (1.0-dis_gas_frac)*intQuants.yVolume());
}
auto& perf_rate_solvent = perf_data.solvent_rates;
perf_rate_solvent[perf] = cq_s_zfrac_effective.value();
cq_s_zfrac_effective *= well_efficiency_factor_;
connectionRates[perf][contiZfracEqIdx] = Base::restrictEval(cq_s_zfrac_effective);
}
if constexpr (has_brine) {
// TODO: the application of well efficiency factor has not been tested with an example yet
const unsigned waterCompIdx = Indices::canonicalToActiveComponentIndex(FluidSystem::waterCompIdx);
EvalWell cq_s_sm = cq_s[waterCompIdx];
if (this->isInjector()) {
cq_s_sm *= wsalt();
} else {
cq_s_sm *= this->extendEval(intQuants.fluidState().saltConcentration());
}
// Note. Efficiency factor is handled in the output layer
auto& perf_rate_brine = perf_data.brine_rates;
perf_rate_brine[perf] = cq_s_sm.value();
cq_s_sm *= well_efficiency_factor_;
connectionRates[perf][contiBrineEqIdx] = Base::restrictEval(cq_s_sm);
}
// Store the perforation pressure for later usage.
perf_data.pressure[perf] = well_state.bhp(this->index_of_well_) + this->perf_pressure_diffs_[perf];
}
template<typename TypeTag>
void
StandardWell<TypeTag>::
getMobility(const Simulator& ebosSimulator,
const int perf,
std::vector<EvalWell>& mob,
DeferredLogger& deferred_logger) const
{
const int cell_idx = well_cells_[perf];
assert (int(mob.size()) == num_components_);
const auto& intQuants = *(ebosSimulator.model().cachedIntensiveQuantities(cell_idx, /*timeIdx=*/0));
const auto& materialLawManager = ebosSimulator.problem().materialLawManager();
// either use mobility of the perforation cell or calcualte its own
// based on passing the saturation table index
const int satid = saturation_table_number_[perf] - 1;
const int satid_elem = materialLawManager->satnumRegionIdx(cell_idx);
if( satid == satid_elem ) { // the same saturation number is used. i.e. just use the mobilty from the cell
for (unsigned phaseIdx = 0; phaseIdx < FluidSystem::numPhases; ++phaseIdx) {
if (!FluidSystem::phaseIsActive(phaseIdx)) {
continue;
}
const unsigned activeCompIdx = Indices::canonicalToActiveComponentIndex(FluidSystem::solventComponentIndex(phaseIdx));
mob[activeCompIdx] = this->extendEval(intQuants.mobility(phaseIdx));
}
if (has_solvent) {
mob[contiSolventEqIdx] = this->extendEval(intQuants.solventMobility());
}
} else {
const auto& paramsCell = materialLawManager->connectionMaterialLawParams(satid, cell_idx);
Eval relativePerms[3] = { 0.0, 0.0, 0.0 };
MaterialLaw::relativePermeabilities(relativePerms, paramsCell, intQuants.fluidState());
// reset the satnumvalue back to original
materialLawManager->connectionMaterialLawParams(satid_elem, cell_idx);
// compute the mobility
for (unsigned phaseIdx = 0; phaseIdx < FluidSystem::numPhases; ++phaseIdx) {
if (!FluidSystem::phaseIsActive(phaseIdx)) {
continue;
}
const unsigned activeCompIdx = Indices::canonicalToActiveComponentIndex(FluidSystem::solventComponentIndex(phaseIdx));
mob[activeCompIdx] = this->extendEval(relativePerms[phaseIdx] / intQuants.fluidState().viscosity(phaseIdx));
}
// this may not work if viscosity and relperms has been modified?
if constexpr (has_solvent) {
OPM_DEFLOG_THROW(std::runtime_error, "individual mobility for wells does not work in combination with solvent", deferred_logger);
}
}
// modify the water mobility if polymer is present
if constexpr (has_polymer) {
if (!FluidSystem::phaseIsActive(FluidSystem::waterPhaseIdx)) {
OPM_DEFLOG_THROW(std::runtime_error, "Water is required when polymer is active", deferred_logger);
}
// for the cases related to polymer molecular weight, we assume fully mixing
// as a result, the polymer and water share the same viscosity
if constexpr (!Base::has_polymermw) {
updateWaterMobilityWithPolymer(ebosSimulator, perf, mob, deferred_logger);
}
}
}
template<typename TypeTag>
void
StandardWell<TypeTag>::
updateWellState(const BVectorWell& dwells,
WellState& well_state,
DeferredLogger& deferred_logger) const
{
if (!this->isOperable() && !this->wellIsStopped()) return;
updatePrimaryVariablesNewton(dwells, well_state);
updateWellStateFromPrimaryVariables(well_state, deferred_logger);
Base::calculateReservoirRates(well_state);
}
template<typename TypeTag>
void
StandardWell<TypeTag>::
updatePrimaryVariablesNewton(const BVectorWell& dwells,
const WellState& /* well_state */) const
{
const double dFLimit = param_.dwell_fraction_max_;
const double dBHPLimit = param_.dbhp_max_rel_;
this->StdWellEval::updatePrimaryVariablesNewton(dwells, dFLimit, dBHPLimit);
updateExtraPrimaryVariables(dwells);
#ifndef NDEBUG
for (double v : this->primary_variables_) {
assert(isfinite(v));
}
#endif
}
template<typename TypeTag>
void
StandardWell<TypeTag>::
updateExtraPrimaryVariables(const BVectorWell& dwells) const
{
// for the water velocity and skin pressure
if constexpr (Base::has_polymermw) {
this->updatePrimaryVariablesPolyMW(dwells);
}
}
template<typename TypeTag>
void
StandardWell<TypeTag>::
updateWellStateFromPrimaryVariables(WellState& well_state, DeferredLogger& deferred_logger) const
{
this->StdWellEval::updateWellStateFromPrimaryVariables(well_state, deferred_logger);
// other primary variables related to polymer injectivity study
if constexpr (Base::has_polymermw) {
this->updateWellStateFromPrimaryVariablesPolyMW(well_state);
}
}
template<typename TypeTag>
void
StandardWell<TypeTag>::
updateIPR(const Simulator& ebos_simulator, DeferredLogger& deferred_logger) const
{
// TODO: not handling solvent related here for now
// TODO: it only handles the producers for now
// the formular for the injectors are not formulated yet
if (this->isInjector()) {
return;
}
// initialize all the values to be zero to begin with
std::fill(ipr_a_.begin(), ipr_a_.end(), 0.);
std::fill(ipr_b_.begin(), ipr_b_.end(), 0.);
for (int perf = 0; perf < number_of_perforations_; ++perf) {
std::vector<EvalWell> mob(num_components_, {this->numWellEq_ + numEq, 0.0});
// TODO: mabye we should store the mobility somewhere, so that we only need to calculate it one per iteration
getMobility(ebos_simulator, perf, mob, deferred_logger);
const int cell_idx = well_cells_[perf];
const auto& int_quantities = *(ebos_simulator.model().cachedIntensiveQuantities(cell_idx, /*timeIdx=*/ 0));
const auto& fs = int_quantities.fluidState();
// the pressure of the reservoir grid block the well connection is in
Eval perf_pressure = getPerfCellPressure(fs);
double p_r = perf_pressure.value();
// calculating the b for the connection
std::vector<double> b_perf(num_components_);
for (size_t phase = 0; phase < FluidSystem::numPhases; ++phase) {
if (!FluidSystem::phaseIsActive(phase)) {
continue;
}
const unsigned comp_idx = Indices::canonicalToActiveComponentIndex(FluidSystem::solventComponentIndex(phase));
b_perf[comp_idx] = fs.invB(phase).value();
}
// the pressure difference between the connection and BHP
const double h_perf = this->perf_pressure_diffs_[perf];
const double pressure_diff = p_r - h_perf;
// Let us add a check, since the pressure is calculated based on zero value BHP
// it should not be negative anyway. If it is negative, we might need to re-formulate
// to taking into consideration the crossflow here.
if (pressure_diff <= 0.) {
deferred_logger.warning("NON_POSITIVE_DRAWDOWN_IPR",
"non-positive drawdown found when updateIPR for well " + name());
}
// the well index associated with the connection
const double tw_perf = well_index_[perf]*ebos_simulator.problem().template rockCompTransMultiplier<double>(int_quantities, cell_idx);
// TODO: there might be some indices related problems here
// phases vs components
// ipr values for the perforation
std::vector<double> ipr_a_perf(ipr_a_.size());
std::vector<double> ipr_b_perf(ipr_b_.size());
for (int p = 0; p < number_of_phases_; ++p) {
const double tw_mob = tw_perf * mob[p].value() * b_perf[p];
ipr_a_perf[p] += tw_mob * pressure_diff;
ipr_b_perf[p] += tw_mob;
}
// we need to handle the rs and rv when both oil and gas are present
if (FluidSystem::phaseIsActive(FluidSystem::oilPhaseIdx) && FluidSystem::phaseIsActive(FluidSystem::gasPhaseIdx)) {
const unsigned oil_comp_idx = Indices::canonicalToActiveComponentIndex(FluidSystem::oilCompIdx);
const unsigned gas_comp_idx = Indices::canonicalToActiveComponentIndex(FluidSystem::gasCompIdx);
const double rs = (fs.Rs()).value();
const double rv = (fs.Rv()).value();
const double dis_gas_a = rs * ipr_a_perf[oil_comp_idx];
const double vap_oil_a = rv * ipr_a_perf[gas_comp_idx];
ipr_a_perf[gas_comp_idx] += dis_gas_a;
ipr_a_perf[oil_comp_idx] += vap_oil_a;
const double dis_gas_b = rs * ipr_b_perf[oil_comp_idx];
const double vap_oil_b = rv * ipr_b_perf[gas_comp_idx];
ipr_b_perf[gas_comp_idx] += dis_gas_b;
ipr_b_perf[oil_comp_idx] += vap_oil_b;
}
for (int p = 0; p < number_of_phases_; ++p) {
// TODO: double check the indices here
ipr_a_[ebosCompIdxToFlowCompIdx(p)] += ipr_a_perf[p];
ipr_b_[ebosCompIdxToFlowCompIdx(p)] += ipr_b_perf[p];
}
}
this->parallel_well_info_.communication().sum(ipr_a_.data(), ipr_a_.size());
this->parallel_well_info_.communication().sum(ipr_b_.data(), ipr_b_.size());
}
template<typename TypeTag>
void
StandardWell<TypeTag>::
checkOperabilityUnderBHPLimitProducer(const WellState& well_state, const Simulator& ebos_simulator, DeferredLogger& deferred_logger)
{
const auto& summaryState = ebos_simulator.vanguard().summaryState();
const double bhp_limit = mostStrictBhpFromBhpLimits(summaryState);
// Crude but works: default is one atmosphere.
// TODO: a better way to detect whether the BHP is defaulted or not
const bool bhp_limit_not_defaulted = bhp_limit > 1.5 * unit::barsa;
if ( bhp_limit_not_defaulted || !this->wellHasTHPConstraints(summaryState) ) {
// if the BHP limit is not defaulted or the well does not have a THP limit
// we need to check the BHP limit
for (int p = 0; p < number_of_phases_; ++p) {
const double temp = ipr_a_[p] - ipr_b_[p] * bhp_limit;
if (temp < 0.) {
this->operability_status_.operable_under_only_bhp_limit = false;
break;
}
}
// checking whether running under BHP limit will violate THP limit
if (this->operability_status_.operable_under_only_bhp_limit && this->wellHasTHPConstraints(summaryState)) {
// option 1: calculate well rates based on the BHP limit.
// option 2: stick with the above IPR curve
// we use IPR here
std::vector<double> well_rates_bhp_limit;
computeWellRatesWithBhp(ebos_simulator, bhp_limit, well_rates_bhp_limit, deferred_logger);
const double thp = this->calculateThpFromBhp(well_state, well_rates_bhp_limit, bhp_limit, deferred_logger);
const double thp_limit = this->getTHPConstraint(summaryState);
if (thp < thp_limit) {
this->operability_status_.obey_thp_limit_under_bhp_limit = false;
}
}
} else {
// defaulted BHP and there is a THP constraint
// default BHP limit is about 1 atm.
// when applied the hydrostatic pressure correction dp,
// most likely we get a negative value (bhp + dp)to search in the VFP table,
// which is not desirable.
// we assume we can operate under defaulted BHP limit and will violate the THP limit
// when operating under defaulted BHP limit.
this->operability_status_.operable_under_only_bhp_limit = true;
this->operability_status_.obey_thp_limit_under_bhp_limit = false;
}
}
template<typename TypeTag>
void
StandardWell<TypeTag>::
checkOperabilityUnderTHPLimitProducer(const Simulator& ebos_simulator, const WellState& well_state, DeferredLogger& deferred_logger)
{
const auto& summaryState = ebos_simulator.vanguard().summaryState();
const auto obtain_bhp = computeBhpAtThpLimitProd(well_state, ebos_simulator, summaryState, deferred_logger);
if (obtain_bhp) {
this->operability_status_.can_obtain_bhp_with_thp_limit = true;
const double bhp_limit = mostStrictBhpFromBhpLimits(summaryState);
this->operability_status_.obey_bhp_limit_with_thp_limit = (*obtain_bhp >= bhp_limit);
const double thp_limit = this->getTHPConstraint(summaryState);
if (*obtain_bhp < thp_limit) {
const std::string msg = " obtained bhp " + std::to_string(unit::convert::to(*obtain_bhp, unit::barsa))
+ " bars is SMALLER than thp limit "
+ std::to_string(unit::convert::to(thp_limit, unit::barsa))
+ " bars as a producer for well " + name();
deferred_logger.debug(msg);
}
} else {
this->operability_status_.can_obtain_bhp_with_thp_limit = false;
this->operability_status_.obey_bhp_limit_with_thp_limit = false;
if (!this->wellIsStopped()) {
const double thp_limit = this->getTHPConstraint(summaryState);
deferred_logger.debug(" could not find bhp value at thp limit "
+ std::to_string(unit::convert::to(thp_limit, unit::barsa))
+ " bar for well " + name() + ", the well might need to be closed ");
}
}
}
template<typename TypeTag>
bool
StandardWell<TypeTag>::
allDrawDownWrongDirection(const Simulator& ebos_simulator) const
{
bool all_drawdown_wrong_direction = true;
for (int perf = 0; perf < number_of_perforations_; ++perf) {
const int cell_idx = well_cells_[perf];
const auto& intQuants = *(ebos_simulator.model().cachedIntensiveQuantities(cell_idx, /*timeIdx=*/0));
const auto& fs = intQuants.fluidState();
const double pressure = (fs.pressure(FluidSystem::oilPhaseIdx)).value();
const double bhp = this->getBhp().value();
// Pressure drawdown (also used to determine direction of flow)
const double well_pressure = bhp + this->perf_pressure_diffs_[perf];
const double drawdown = pressure - well_pressure;
// for now, if there is one perforation can produce/inject in the correct
// direction, we consider this well can still produce/inject.
// TODO: it can be more complicated than this to cause wrong-signed rates
if ( (drawdown < 0. && this->isInjector()) ||
(drawdown > 0. && this->isProducer()) ) {
all_drawdown_wrong_direction = false;
break;
}
}
const auto& comm = this->parallel_well_info_.communication();
if (comm.size() > 1)
{
all_drawdown_wrong_direction =
(comm.min(all_drawdown_wrong_direction ? 1 : 0) == 1);
}
return all_drawdown_wrong_direction;
}
template<typename TypeTag>
bool
StandardWell<TypeTag>::
canProduceInjectWithCurrentBhp(const Simulator& ebos_simulator,
const WellState& well_state,
DeferredLogger& deferred_logger)
{
const double bhp = well_state.bhp(index_of_well_);
std::vector<double> well_rates;
computeWellRatesWithBhp(ebos_simulator, bhp, well_rates, deferred_logger);
const double sign = (this->isProducer()) ? -1. : 1.;
const double threshold = sign * std::numeric_limits<double>::min();
bool can_produce_inject = false;
for (const auto value : well_rates) {
if (this->isProducer() && value < threshold) {
can_produce_inject = true;
break;
} else if (this->isInjector() && value > threshold) {
can_produce_inject = true;
break;
}
}
if (!can_produce_inject) {
deferred_logger.debug(" well " + name() + " CANNOT produce or inejct ");
}
return can_produce_inject;
}
template<typename TypeTag>
bool
StandardWell<TypeTag>::
openCrossFlowAvoidSingularity(const Simulator& ebos_simulator) const
{
return !getAllowCrossFlow() && allDrawDownWrongDirection(ebos_simulator);
}
template<typename TypeTag>
void
StandardWell<TypeTag>::
computePropertiesForWellConnectionPressures(const Simulator& ebosSimulator,
const WellState& well_state,
std::vector<double>& b_perf,
std::vector<double>& rsmax_perf,
std::vector<double>& rvmax_perf,
std::vector<double>& surf_dens_perf) const
{
const int nperf = number_of_perforations_;
const PhaseUsage& pu = phaseUsage();
b_perf.resize(nperf * num_components_);
surf_dens_perf.resize(nperf * num_components_);
const int w = index_of_well_;
const bool waterPresent = FluidSystem::phaseIsActive(FluidSystem::waterPhaseIdx);
const bool oilPresent = FluidSystem::phaseIsActive(FluidSystem::oilPhaseIdx);
const bool gasPresent = FluidSystem::phaseIsActive(FluidSystem::gasPhaseIdx);
//rs and rv are only used if both oil and gas is present
if (oilPresent && gasPresent) {
rsmax_perf.resize(nperf);
rvmax_perf.resize(nperf);
}
// Compute the average pressure in each well block
const auto& perf_press = well_state.perfData(w).pressure;
auto p_above = this->parallel_well_info_.communicateAboveValues(well_state.bhp(w),
perf_press.data(),
nperf);
for (int perf = 0; perf < nperf; ++perf) {
const int cell_idx = well_cells_[perf];
const auto& intQuants = *(ebosSimulator.model().cachedIntensiveQuantities(cell_idx, /*timeIdx=*/0));
const auto& fs = intQuants.fluidState();
// TODO: this is another place to show why WellState need to be a vector of WellState.
// TODO: to check why should be perf - 1
const double p_avg = (perf_press[perf] + p_above[perf])/2;
const double temperature = fs.temperature(FluidSystem::oilPhaseIdx).value();
const double saltConcentration = fs.saltConcentration().value();
if (waterPresent) {
const unsigned waterCompIdx = Indices::canonicalToActiveComponentIndex(FluidSystem::waterCompIdx);
b_perf[ waterCompIdx + perf * num_components_] =
FluidSystem::waterPvt().inverseFormationVolumeFactor(fs.pvtRegionIndex(), temperature, p_avg, saltConcentration);
}
if (gasPresent) {
const unsigned gasCompIdx = Indices::canonicalToActiveComponentIndex(FluidSystem::gasCompIdx);
const int gaspos = gasCompIdx + perf * num_components_;
if (oilPresent) {
const double oilrate = std::abs(well_state.wellRates(w)[pu.phase_pos[Oil]]); //in order to handle negative rates in producers
rvmax_perf[perf] = FluidSystem::gasPvt().saturatedOilVaporizationFactor(fs.pvtRegionIndex(), temperature, p_avg);
if (oilrate > 0) {
const double gasrate = std::abs(well_state.wellRates(w)[pu.phase_pos[Gas]]) - (has_solvent ? well_state.solventWellRate(w) : 0.0);
double rv = 0.0;
if (gasrate > 0) {
rv = oilrate / gasrate;
}
rv = std::min(rv, rvmax_perf[perf]);
b_perf[gaspos] = FluidSystem::gasPvt().inverseFormationVolumeFactor(fs.pvtRegionIndex(), temperature, p_avg, rv);
}
else {
b_perf[gaspos] = FluidSystem::gasPvt().saturatedInverseFormationVolumeFactor(fs.pvtRegionIndex(), temperature, p_avg);
}
} else {
b_perf[gaspos] = FluidSystem::gasPvt().saturatedInverseFormationVolumeFactor(fs.pvtRegionIndex(), temperature, p_avg);
}
}
if (oilPresent) {
const unsigned oilCompIdx = Indices::canonicalToActiveComponentIndex(FluidSystem::oilCompIdx);
const int oilpos = oilCompIdx + perf * num_components_;
if (gasPresent) {
rsmax_perf[perf] = FluidSystem::oilPvt().saturatedGasDissolutionFactor(fs.pvtRegionIndex(), temperature, p_avg);
const double gasrate = std::abs(well_state.wellRates(w)[pu.phase_pos[Gas]]) - (has_solvent ? well_state.solventWellRate(w) : 0.0);
if (gasrate > 0) {
const double oilrate = std::abs(well_state.wellRates(w)[pu.phase_pos[Oil]]);
double rs = 0.0;
if (oilrate > 0) {
rs = gasrate / oilrate;
}
rs = std::min(rs, rsmax_perf[perf]);
b_perf[oilpos] = FluidSystem::oilPvt().inverseFormationVolumeFactor(fs.pvtRegionIndex(), temperature, p_avg, rs);
} else {
b_perf[oilpos] = FluidSystem::oilPvt().saturatedInverseFormationVolumeFactor(fs.pvtRegionIndex(), temperature, p_avg);
}
} else {
b_perf[oilpos] = FluidSystem::oilPvt().saturatedInverseFormationVolumeFactor(fs.pvtRegionIndex(), temperature, p_avg);
}
}
// Surface density.
for (unsigned phaseIdx = 0; phaseIdx < FluidSystem::numPhases; ++phaseIdx) {
if (!FluidSystem::phaseIsActive(phaseIdx)) {
continue;
}
const unsigned compIdx = Indices::canonicalToActiveComponentIndex(FluidSystem::solventComponentIndex(phaseIdx));
surf_dens_perf[num_components_ * perf + compIdx] = FluidSystem::referenceDensity( phaseIdx, fs.pvtRegionIndex() );
}
// We use cell values for solvent injector
if constexpr (has_solvent) {
b_perf[num_components_ * perf + contiSolventEqIdx] = intQuants.solventInverseFormationVolumeFactor().value();
surf_dens_perf[num_components_ * perf + contiSolventEqIdx] = intQuants.solventRefDensity();
}
}
}
template<typename TypeTag>
ConvergenceReport
StandardWell<TypeTag>::
getWellConvergence(const WellState& well_state,
const std::vector<double>& B_avg,
DeferredLogger& deferred_logger,
const bool /*relax_tolerance*/) const
{
// the following implementation assume that the polymer is always after the w-o-g phases
// For the polymer, energy and foam cases, there is one more mass balance equations of reservoir than wells
assert((int(B_avg.size()) == num_components_) || has_polymer || has_energy || has_foam || has_brine || has_zFraction);
const double tol_wells = param_.tolerance_wells_;
const double maxResidualAllowed = param_.max_residual_allowed_;
std::vector<double> res;
ConvergenceReport report = this->StdWellEval::getWellConvergence(well_state,
B_avg,
tol_wells,
maxResidualAllowed,
res,
deferred_logger);
checkConvergenceExtraEqs(res, report);
return report;
}
template<typename TypeTag>
void
StandardWell<TypeTag>::
updateProductivityIndex(const Simulator& ebosSimulator,
const WellProdIndexCalculator& wellPICalc,
WellState& well_state,
DeferredLogger& deferred_logger) const
{
auto fluidState = [&ebosSimulator, this](const int perf)
{
const auto cell_idx = this->well_cells_[perf];
return ebosSimulator.model()
.cachedIntensiveQuantities(cell_idx, /*timeIdx=*/ 0)->fluidState();
};
const int np = this->number_of_phases_;
auto setToZero = [np](double* x) -> void
{
std::fill_n(x, np, 0.0);
};
auto addVector = [np](const double* src, double* dest) -> void
{
std::transform(src, src + np, dest, dest, std::plus<>{});
};
auto& perf_data = well_state.perfData(this->index_of_well_);
auto* wellPI = well_state.productivityIndex(this->index_of_well_).data();
auto* connPI = perf_data.prod_index.data();
setToZero(wellPI);
const auto preferred_phase = this->well_ecl_.getPreferredPhase();
auto subsetPerfID = 0;
for (const auto& perf : *this->perf_data_) {
auto allPerfID = perf.ecl_index;
auto connPICalc = [&wellPICalc, allPerfID](const double mobility) -> double
{
return wellPICalc.connectionProdIndStandard(allPerfID, mobility);
};
std::vector<EvalWell> mob(num_components_, {this->numWellEq_ + numEq, 0.0});
getMobility(ebosSimulator, static_cast<int>(subsetPerfID), mob, deferred_logger);
const auto& fs = fluidState(subsetPerfID);
setToZero(connPI);
if (this->isInjector()) {
this->computeConnLevelInjInd(fs, preferred_phase, connPICalc,
mob, connPI, deferred_logger);
}
else { // Production or zero flow rate
this->computeConnLevelProdInd(fs, connPICalc, mob, connPI);
}
addVector(connPI, wellPI);
++subsetPerfID;
connPI += np;
}
// Sum with communication in case of distributed well.
const auto& comm = this->parallel_well_info_.communication();
if (comm.size() > 1) {
comm.sum(wellPI, np);
}
assert ((static_cast<int>(subsetPerfID) == this->number_of_perforations_) &&
"Internal logic error in processing connections for PI/II");
}
template<typename TypeTag>
void
StandardWell<TypeTag>::
computeWellConnectionDensitesPressures(const Simulator& ebosSimulator,
const WellState& well_state,
const std::vector<double>& b_perf,
const std::vector<double>& rsmax_perf,
const std::vector<double>& rvmax_perf,
const std::vector<double>& surf_dens_perf)
{
// Compute densities
const int nperf = number_of_perforations_;
const int np = number_of_phases_;
std::vector<double> perfRates(b_perf.size(),0.0);
const auto& perf_data = well_state.perfData(this->index_of_well_);
const auto& perf_rates_state = perf_data.phase_rates;
for (int perf = 0; perf < nperf; ++perf) {
for (int comp = 0; comp < np; ++comp) {
perfRates[perf * num_components_ + comp] = perf_rates_state[perf * np + ebosCompIdxToFlowCompIdx(comp)];
}
}
if constexpr (has_solvent) {
const auto& solvent_perf_rates_state = perf_data.solvent_rates;
for (int perf = 0; perf < nperf; ++perf) {
perfRates[perf * num_components_ + contiSolventEqIdx] = solvent_perf_rates_state[perf];
}
}
// for producers where all perforations have zero rate we
// approximate the perforation mixture using the mobility ratio
// and weight the perforations using the well transmissibility.
bool all_zero = std::all_of(perfRates.begin(), perfRates.end(), [](double val) { return val == 0.0; });
if ( all_zero && this->isProducer() ) {
double total_tw = 0;
for (int perf = 0; perf < nperf; ++perf) {
total_tw += well_index_[perf];
}
for (int perf = 0; perf < nperf; ++perf) {
const int cell_idx = well_cells_[perf];
const auto& intQuants = *(ebosSimulator.model().cachedIntensiveQuantities(cell_idx, /*timeIdx=*/0));
const auto& fs = intQuants.fluidState();
const double well_tw_fraction = well_index_[perf] / total_tw;
double total_mobility = 0.0;
for (int p = 0; p < np; ++p) {
int ebosPhaseIdx = flowPhaseToEbosPhaseIdx(p);
total_mobility += fs.invB(ebosPhaseIdx).value() * intQuants.mobility(ebosPhaseIdx).value();
}
if constexpr (has_solvent) {
total_mobility += intQuants.solventInverseFormationVolumeFactor().value() * intQuants.solventMobility().value();
}
for (int p = 0; p < np; ++p) {
int ebosPhaseIdx = flowPhaseToEbosPhaseIdx(p);
perfRates[perf * num_components_ + p] = well_tw_fraction * intQuants.mobility(ebosPhaseIdx).value() / total_mobility;
}
if constexpr (has_solvent) {
perfRates[perf * num_components_ + contiSolventEqIdx] = well_tw_fraction * intQuants.solventInverseFormationVolumeFactor().value() / total_mobility;
}
}
}
this->computeConnectionDensities(perfRates, b_perf, rsmax_perf, rvmax_perf, surf_dens_perf);
this->computeConnectionPressureDelta();
}
template<typename TypeTag>
void
StandardWell<TypeTag>::
computeWellConnectionPressures(const Simulator& ebosSimulator,
const WellState& well_state)
{
// 1. Compute properties required by computeConnectionPressureDelta().
// Note that some of the complexity of this part is due to the function
// taking std::vector<double> arguments, and not Eigen objects.
std::vector<double> b_perf;
std::vector<double> rsmax_perf;
std::vector<double> rvmax_perf;
std::vector<double> surf_dens_perf;
computePropertiesForWellConnectionPressures(ebosSimulator, well_state, b_perf, rsmax_perf, rvmax_perf, surf_dens_perf);
computeWellConnectionDensitesPressures(ebosSimulator, well_state, b_perf, rsmax_perf, rvmax_perf, surf_dens_perf);
}
template<typename TypeTag>
void
StandardWell<TypeTag>::
solveEqAndUpdateWellState(WellState& well_state, DeferredLogger& deferred_logger)
{
if (!this->isOperable() && !this->wellIsStopped()) return;
// We assemble the well equations, then we check the convergence,
// which is why we do not put the assembleWellEq here.
BVectorWell dx_well(1);
dx_well[0].resize(this->numWellEq_);
this->invDuneD_.mv(this->resWell_, dx_well);
updateWellState(dx_well, well_state, deferred_logger);
}
template<typename TypeTag>
void
StandardWell<TypeTag>::
calculateExplicitQuantities(const Simulator& ebosSimulator,
const WellState& well_state,
DeferredLogger& deferred_logger)
{
updatePrimaryVariables(well_state, deferred_logger);
initPrimaryVariablesEvaluation();
computeWellConnectionPressures(ebosSimulator, well_state);
this->computeAccumWell();
}
template<typename TypeTag>
void
StandardWell<TypeTag>::
apply(const BVector& x, BVector& Ax) const
{
if (!this->isOperable() && !this->wellIsStopped()) return;
if ( param_.matrix_add_well_contributions_ )
{
// Contributions are already in the matrix itself
return;
}
assert( this->Bx_.size() == this->duneB_.N() );
assert( this->invDrw_.size() == this->invDuneD_.N() );
// Bx_ = duneB_ * x
this->parallelB_.mv(x, this->Bx_);
// invDBx = invDuneD_ * Bx_
// TODO: with this, we modified the content of the invDrw_.
// Is it necessary to do this to save some memory?
BVectorWell& invDBx = this->invDrw_;
this->invDuneD_.mv(this->Bx_, invDBx);
// Ax = Ax - duneC_^T * invDBx
this->duneC_.mmtv(invDBx,Ax);
}
template<typename TypeTag>
void
StandardWell<TypeTag>::
apply(BVector& r) const
{
if (!this->isOperable() && !this->wellIsStopped()) return;
assert( this->invDrw_.size() == this->invDuneD_.N() );
// invDrw_ = invDuneD_ * resWell_
this->invDuneD_.mv(this->resWell_, this->invDrw_);
// r = r - duneC_^T * invDrw_
this->duneC_.mmtv(this->invDrw_, r);
}
template<typename TypeTag>
void
StandardWell<TypeTag>::
recoverSolutionWell(const BVector& x, BVectorWell& xw) const
{
if (!this->isOperable() && !this->wellIsStopped()) return;
BVectorWell resWell = this->resWell_;
// resWell = resWell - B * x
this->parallelB_.mmv(x, resWell);
// xw = D^-1 * resWell
this->invDuneD_.mv(resWell, xw);
}
template<typename TypeTag>
void
StandardWell<TypeTag>::
recoverWellSolutionAndUpdateWellState(const BVector& x,
WellState& well_state,
DeferredLogger& deferred_logger) const
{
if (!this->isOperable() && !this->wellIsStopped()) return;
BVectorWell xw(1);
xw[0].resize(this->numWellEq_);
recoverSolutionWell(x, xw);
updateWellState(xw, well_state, deferred_logger);
}
template<typename TypeTag>
void
StandardWell<TypeTag>::
computeWellRatesWithBhp(const Simulator& ebosSimulator,
const double& bhp,
std::vector<double>& well_flux,
DeferredLogger& deferred_logger) const
{
const int np = number_of_phases_;
well_flux.resize(np, 0.0);
const bool allow_cf = getAllowCrossFlow();
for (int perf = 0; perf < number_of_perforations_; ++perf) {
const int cell_idx = well_cells_[perf];
const auto& intQuants = *(ebosSimulator.model().cachedIntensiveQuantities(cell_idx, /*timeIdx=*/ 0));
// flux for each perforation
std::vector<EvalWell> mob(num_components_, {this->numWellEq_ + numEq, 0.});
getMobility(ebosSimulator, perf, mob, deferred_logger);
double trans_mult = ebosSimulator.problem().template rockCompTransMultiplier<double>(intQuants, cell_idx);
const double Tw = well_index_[perf] * trans_mult;
std::vector<EvalWell> cq_s(num_components_, {this->numWellEq_ + numEq, 0.});
double perf_dis_gas_rate = 0.;
double perf_vap_oil_rate = 0.;
computePerfRate(intQuants, mob, EvalWell(this->numWellEq_ + numEq, bhp), Tw, perf, allow_cf,
cq_s, perf_dis_gas_rate, perf_vap_oil_rate, deferred_logger);
for(int p = 0; p < np; ++p) {
well_flux[ebosCompIdxToFlowCompIdx(p)] += cq_s[p].value();
}
}
this->parallel_well_info_.communication().sum(well_flux.data(), well_flux.size());
}
template<typename TypeTag>
void
StandardWell<TypeTag>::
computeWellRatesWithBhpPotential(const Simulator& ebosSimulator,
const double& bhp,
std::vector<double>& well_flux,
DeferredLogger& deferred_logger)
{
// iterate to get a more accurate well density
// create a copy of the well_state to use. If the operability checking is sucessful, we use this one
// to replace the original one
WellState well_state_copy = ebosSimulator.problem().wellModel().wellState();
const auto& group_state = ebosSimulator.problem().wellModel().groupState();
// Set current control to bhp, and bhp value in state, modify bhp limit in control object.
if (well_ecl_.isInjector()) {
well_state_copy.currentInjectionControl(index_of_well_, Well::InjectorCMode::BHP);
} else {
well_state_copy.currentProductionControl(index_of_well_, Well::ProducerCMode::BHP);
}
well_state_copy.update_bhp(index_of_well_, bhp);
const double dt = ebosSimulator.timeStepSize();
bool converged = this->iterateWellEquations(ebosSimulator, dt, well_state_copy, group_state, deferred_logger);
if (!converged) {
const std::string msg = " well " + name() + " did not get converged during well potential calculations "
"returning zero values for the potential";
deferred_logger.debug(msg);
return;
}
updatePrimaryVariables(well_state_copy, deferred_logger);
computeWellConnectionPressures(ebosSimulator, well_state_copy);
initPrimaryVariablesEvaluation();
computeWellRatesWithBhp(ebosSimulator, bhp, well_flux, deferred_logger);
}
template<typename TypeTag>
std::vector<double>
StandardWell<TypeTag>::
computeWellPotentialWithTHP(const Simulator& ebos_simulator,
DeferredLogger& deferred_logger,
const WellState &well_state) const
{
std::vector<double> potentials(number_of_phases_, 0.0);
const auto& summary_state = ebos_simulator.vanguard().summaryState();
const auto& well = well_ecl_;
if (well.isInjector()){
const auto& controls = well_ecl_.injectionControls(summary_state);
auto bhp_at_thp_limit = computeBhpAtThpLimitInj(ebos_simulator, summary_state, deferred_logger);
if (bhp_at_thp_limit) {
const double bhp = std::min(*bhp_at_thp_limit, controls.bhp_limit);
computeWellRatesWithBhp(ebos_simulator, bhp, potentials, deferred_logger);
} else {
deferred_logger.warning("FAILURE_GETTING_CONVERGED_POTENTIAL",
"Failed in getting converged thp based potential calculation for well "
+ name() + ". Instead the bhp based value is used");
const double bhp = controls.bhp_limit;
computeWellRatesWithBhp(ebos_simulator, bhp, potentials, deferred_logger);
}
} else {
computeWellRatesWithThpAlqProd(
ebos_simulator, summary_state,
deferred_logger, potentials, getALQ(well_state)
);
}
return potentials;
}
template<typename TypeTag>
double
StandardWell<TypeTag>::
computeWellRatesAndBhpWithThpAlqProd(const Simulator &ebos_simulator,
const SummaryState &summary_state,
DeferredLogger &deferred_logger,
std::vector<double> &potentials,
double alq) const
{
double bhp;
auto bhp_at_thp_limit = computeBhpAtThpLimitProdWithAlq(
ebos_simulator, summary_state, deferred_logger, alq);
if (bhp_at_thp_limit) {
const auto& controls = well_ecl_.productionControls(summary_state);
bhp = std::max(*bhp_at_thp_limit, controls.bhp_limit);
computeWellRatesWithBhp(ebos_simulator, bhp, potentials, deferred_logger);
}
else {
deferred_logger.warning("FAILURE_GETTING_CONVERGED_POTENTIAL",
"Failed in getting converged thp based potential calculation for well "
+ name() + ". Instead the bhp based value is used");
const auto& controls = well_ecl_.productionControls(summary_state);
bhp = controls.bhp_limit;
computeWellRatesWithBhp(ebos_simulator, bhp, potentials, deferred_logger);
}
return bhp;
}
template<typename TypeTag>
void
StandardWell<TypeTag>::
computeWellRatesWithThpAlqProd(const Simulator &ebos_simulator,
const SummaryState &summary_state,
DeferredLogger &deferred_logger,
std::vector<double> &potentials,
double alq) const
{
/*double bhp =*/
computeWellRatesAndBhpWithThpAlqProd(ebos_simulator,
summary_state,
deferred_logger,
potentials,
alq);
}
template<typename TypeTag>
void
StandardWell<TypeTag>::
gasLiftOptimizationStage1(
WellState& well_state,
const Simulator& ebos_simulator,
DeferredLogger& deferred_logger,
GLiftProdWells &prod_wells,
GLiftOptWells &glift_wells,
GLiftWellStateMap &glift_state_map,
GasLiftGroupInfo &group_info,
GLiftSyncGroups &sync_groups
) const
{
const auto& summary_state = ebos_simulator.vanguard().summaryState();
std::unique_ptr<GasLiftSingleWell> glift
= std::make_unique<GasLiftSingleWell>(
*this, ebos_simulator, summary_state,
deferred_logger, well_state, group_info, sync_groups);
auto state = glift->runOptimize(
ebos_simulator.model().newtonMethod().numIterations());
if (state) {
glift_state_map.insert({this->name(), std::move(state)});
glift_wells.insert({this->name(), std::move(glift)});
return;
}
prod_wells.insert({this->name(), this});
}
template<typename TypeTag>
void
StandardWell<TypeTag>::
computeWellPotentials(const Simulator& ebosSimulator,
const WellState& well_state,
std::vector<double>& well_potentials,
DeferredLogger& deferred_logger) // const
{
const int np = number_of_phases_;
well_potentials.resize(np, 0.0);
if (this->wellIsStopped()) {
return;
}
// If the well is pressure controlled the potential equals the rate.
bool pressure_controlled_well = false;
if (this->isInjector()) {
const Well::InjectorCMode& current = well_state.currentInjectionControl(index_of_well_);
if (current == Well::InjectorCMode::BHP || current == Well::InjectorCMode::THP) {
pressure_controlled_well = true;
}
} else {
const Well::ProducerCMode& current = well_state.currentProductionControl(index_of_well_);
if (current == Well::ProducerCMode::BHP || current == Well::ProducerCMode::THP) {
pressure_controlled_well = true;
}
}
if (pressure_controlled_well) {
// initialized the well rates with the potentials i.e. the well rates based on bhp
const double sign = this->well_ecl_.isInjector() ? 1.0 : -1.0;
for (int phase = 0; phase < np; ++phase){
well_potentials[phase] = sign * well_state.wellRates(index_of_well_)[phase];
}
return;
}
// creating a copy of the well itself, to avoid messing up the explicit informations
// during this copy, the only information not copied properly is the well controls
StandardWell<TypeTag> well(*this);
well.calculateExplicitQuantities(ebosSimulator, well_state, deferred_logger);
// does the well have a THP related constraint?
const auto& summaryState = ebosSimulator.vanguard().summaryState();
if (!well.Base::wellHasTHPConstraints(summaryState)) {
// get the bhp value based on the bhp constraints
const double bhp = well.mostStrictBhpFromBhpLimits(summaryState);
assert(std::abs(bhp) != std::numeric_limits<double>::max());
well.computeWellRatesWithBhpPotential(ebosSimulator, bhp, well_potentials, deferred_logger);
} else {
// the well has a THP related constraint
well_potentials = well.computeWellPotentialWithTHP(ebosSimulator, deferred_logger, well_state);
}
}
template<typename TypeTag>
void
StandardWell<TypeTag>::
updatePrimaryVariables(const WellState& well_state, DeferredLogger& deferred_logger) const
{
this->StdWellEval::updatePrimaryVariables(well_state, deferred_logger);
if (!this->isOperable() && !this->wellIsStopped()) return;
// other primary variables related to polymer injection
if constexpr (Base::has_polymermw) {
if (this->isInjector()) {
const auto& perf_data = well_state.perfData(this->index_of_well_);
const auto& water_velocity = perf_data.water_velocity;
const auto& skin_pressure = perf_data.skin_pressure;
for (int perf = 0; perf < number_of_perforations_; ++perf) {
this->primary_variables_[Bhp + 1 + perf] = water_velocity[perf];
this->primary_variables_[Bhp + 1 + number_of_perforations_ + perf] = skin_pressure[perf];
}
}
}
#ifndef NDEBUG
for (double v : this->primary_variables_) {
assert(isfinite(v));
}
#endif
}
template<typename TypeTag>
double
StandardWell<TypeTag>::
getRefDensity() const
{
return this->perf_densities_[0];
}
template<typename TypeTag>
void
StandardWell<TypeTag>::
updateWaterMobilityWithPolymer(const Simulator& ebos_simulator,
const int perf,
std::vector<EvalWell>& mob,
DeferredLogger& deferred_logger) const
{
const int cell_idx = well_cells_[perf];
const auto& int_quant = *(ebos_simulator.model().cachedIntensiveQuantities(cell_idx, /*timeIdx=*/ 0));
const EvalWell polymer_concentration = this->extendEval(int_quant.polymerConcentration());
// TODO: not sure should based on the well type or injecting/producing peforations
// it can be different for crossflow
if (this->isInjector()) {
// assume fully mixing within injecting wellbore
const auto& visc_mult_table = PolymerModule::plyviscViscosityMultiplierTable(int_quant.pvtRegionIndex());
const unsigned waterCompIdx = Indices::canonicalToActiveComponentIndex(FluidSystem::waterCompIdx);
mob[waterCompIdx] /= (this->extendEval(int_quant.waterViscosityCorrection()) * visc_mult_table.eval(polymer_concentration, /*extrapolate=*/true) );
}
if (PolymerModule::hasPlyshlog()) {
// we do not calculate the shear effects for injection wells when they do not
// inject polymer.
if (this->isInjector() && wpolymer() == 0.) {
return;
}
// compute the well water velocity with out shear effects.
// TODO: do we need to turn on crossflow here?
const bool allow_cf = getAllowCrossFlow() || openCrossFlowAvoidSingularity(ebos_simulator);
const EvalWell& bhp = this->getBhp();
std::vector<EvalWell> cq_s(num_components_, {this->numWellEq_ + numEq, 0.});
double perf_dis_gas_rate = 0.;
double perf_vap_oil_rate = 0.;
double trans_mult = ebos_simulator.problem().template rockCompTransMultiplier<double>(int_quant, cell_idx);
const double Tw = well_index_[perf] * trans_mult;
computePerfRate(int_quant, mob, bhp, Tw, perf, allow_cf,
cq_s, perf_dis_gas_rate, perf_vap_oil_rate, deferred_logger);
// TODO: make area a member
const double area = 2 * M_PI * perf_rep_radius_[perf] * perf_length_[perf];
const auto& material_law_manager = ebos_simulator.problem().materialLawManager();
const auto& scaled_drainage_info =
material_law_manager->oilWaterScaledEpsInfoDrainage(cell_idx);
const double swcr = scaled_drainage_info.Swcr;
const EvalWell poro = this->extendEval(int_quant.porosity());
const EvalWell sw = this->extendEval(int_quant.fluidState().saturation(FluidSystem::waterPhaseIdx));
// guard against zero porosity and no water
const EvalWell denom = max( (area * poro * (sw - swcr)), 1e-12);
const unsigned waterCompIdx = Indices::canonicalToActiveComponentIndex(FluidSystem::waterCompIdx);
EvalWell water_velocity = cq_s[waterCompIdx] / denom * this->extendEval(int_quant.fluidState().invB(FluidSystem::waterPhaseIdx));
if (PolymerModule::hasShrate()) {
// the equation for the water velocity conversion for the wells and reservoir are from different version
// of implementation. It can be changed to be more consistent when possible.
water_velocity *= PolymerModule::shrate( int_quant.pvtRegionIndex() ) / bore_diameters_[perf];
}
const EvalWell shear_factor = PolymerModule::computeShearFactor(polymer_concentration,
int_quant.pvtRegionIndex(),
water_velocity);
// modify the mobility with the shear factor.
mob[waterCompIdx] /= shear_factor;
}
}
template<typename TypeTag>
void
StandardWell<TypeTag>::addWellContributions(SparseMatrixAdapter& jacobian) const
{
// We need to change matrx A as follows
// A -= C^T D^-1 B
// D is diagonal
// B and C have 1 row, nc colums and nonzero
// at (0,j) only if this well has a perforation at cell j.
typename SparseMatrixAdapter::MatrixBlock tmpMat;
Dune::DynamicMatrix<Scalar> tmp;
for ( auto colC = this->duneC_[0].begin(), endC = this->duneC_[0].end(); colC != endC; ++colC )
{
const auto row_index = colC.index();
for ( auto colB = this->duneB_[0].begin(), endB = this->duneB_[0].end(); colB != endB; ++colB )
{
Detail::multMatrix(this->invDuneD_[0][0], (*colB), tmp);
Detail::negativeMultMatrixTransposed((*colC), tmp, tmpMat);
jacobian.addToBlock( row_index, colB.index(), tmpMat );
}
}
}
template<typename TypeTag>
typename StandardWell<TypeTag>::EvalWell
StandardWell<TypeTag>::
pskinwater(const double throughput,
const EvalWell& water_velocity,
DeferredLogger& deferred_logger) const
{
if constexpr (Base::has_polymermw) {
const int water_table_id = well_ecl_.getPolymerProperties().m_skprwattable;
if (water_table_id <= 0) {
OPM_DEFLOG_THROW(std::runtime_error, "Unused SKPRWAT table id used for well " << name(), deferred_logger);
}
const auto& water_table_func = PolymerModule::getSkprwatTable(water_table_id);
const EvalWell throughput_eval(this->numWellEq_ + numEq, throughput);
// the skin pressure when injecting water, which also means the polymer concentration is zero
EvalWell pskin_water(this->numWellEq_ + numEq, 0.0);
pskin_water = water_table_func.eval(throughput_eval, water_velocity);
return pskin_water;
} else {
OPM_DEFLOG_THROW(std::runtime_error, "Polymermw is not activated, "
"while injecting skin pressure is requested for well " << name(), deferred_logger);
}
}
template<typename TypeTag>
typename StandardWell<TypeTag>::EvalWell
StandardWell<TypeTag>::
pskin(const double throughput,
const EvalWell& water_velocity,
const EvalWell& poly_inj_conc,
DeferredLogger& deferred_logger) const
{
if constexpr (Base::has_polymermw) {
const double sign = water_velocity >= 0. ? 1.0 : -1.0;
const EvalWell water_velocity_abs = abs(water_velocity);
if (poly_inj_conc == 0.) {
return sign * pskinwater(throughput, water_velocity_abs, deferred_logger);
}
const int polymer_table_id = well_ecl_.getPolymerProperties().m_skprpolytable;
if (polymer_table_id <= 0) {
OPM_DEFLOG_THROW(std::runtime_error, "Unavailable SKPRPOLY table id used for well " << name(), deferred_logger);
}
const auto& skprpolytable = PolymerModule::getSkprpolyTable(polymer_table_id);
const double reference_concentration = skprpolytable.refConcentration;
const EvalWell throughput_eval(this->numWellEq_ + numEq, throughput);
// the skin pressure when injecting water, which also means the polymer concentration is zero
EvalWell pskin_poly(this->numWellEq_ + numEq, 0.0);
pskin_poly = skprpolytable.table_func.eval(throughput_eval, water_velocity_abs);
if (poly_inj_conc == reference_concentration) {
return sign * pskin_poly;
}
// poly_inj_conc != reference concentration of the table, then some interpolation will be required
const EvalWell pskin_water = pskinwater(throughput, water_velocity_abs, deferred_logger);
const EvalWell pskin = pskin_water + (pskin_poly - pskin_water) / reference_concentration * poly_inj_conc;
return sign * pskin;
} else {
OPM_DEFLOG_THROW(std::runtime_error, "Polymermw is not activated, "
"while injecting skin pressure is requested for well " << name(), deferred_logger);
}
}
template<typename TypeTag>
typename StandardWell<TypeTag>::EvalWell
StandardWell<TypeTag>::
wpolymermw(const double throughput,
const EvalWell& water_velocity,
DeferredLogger& deferred_logger) const
{
if constexpr (Base::has_polymermw) {
const int table_id = well_ecl_.getPolymerProperties().m_plymwinjtable;
const auto& table_func = PolymerModule::getPlymwinjTable(table_id);
const EvalWell throughput_eval(this->numWellEq_ + numEq, throughput);
EvalWell molecular_weight(this->numWellEq_ + numEq, 0.);
if (wpolymer() == 0.) { // not injecting polymer
return molecular_weight;
}
molecular_weight = table_func.eval(throughput_eval, abs(water_velocity));
return molecular_weight;
} else {
OPM_DEFLOG_THROW(std::runtime_error, "Polymermw is not activated, "
"while injecting polymer molecular weight is requested for well " << name(), deferred_logger);
}
}
template<typename TypeTag>
void
StandardWell<TypeTag>::
updateWaterThroughput(const double dt, WellState &well_state) const
{
if constexpr (Base::has_polymermw) {
if (this->isInjector()) {
auto& perf_water_throughput = well_state.perfData(this->index_of_well_).water_throughput;
for (int perf = 0; perf < number_of_perforations_; ++perf) {
const double perf_water_vel = this->primary_variables_[Bhp + 1 + perf];
// we do not consider the formation damage due to water flowing from reservoir into wellbore
if (perf_water_vel > 0.) {
perf_water_throughput[perf] += perf_water_vel * dt;
}
}
}
}
}
template<typename TypeTag>
void
StandardWell<TypeTag>::
handleInjectivityRate(const Simulator& ebosSimulator,
const int perf,
std::vector<EvalWell>& cq_s) const
{
const int cell_idx = well_cells_[perf];
const auto& int_quants = *(ebosSimulator.model().cachedIntensiveQuantities(cell_idx, /*timeIdx=*/ 0));
const auto& fs = int_quants.fluidState();
const EvalWell b_w = this->extendEval(fs.invB(FluidSystem::waterPhaseIdx));
const double area = M_PI * bore_diameters_[perf] * perf_length_[perf];
const int wat_vel_index = Bhp + 1 + perf;
const unsigned water_comp_idx = Indices::canonicalToActiveComponentIndex(FluidSystem::waterCompIdx);
// water rate is update to use the form from water velocity, since water velocity is
// a primary variable now
cq_s[water_comp_idx] = area * this->primary_variables_evaluation_[wat_vel_index] * b_w;
}
template<typename TypeTag>
void
StandardWell<TypeTag>::
handleInjectivityEquations(const Simulator& ebosSimulator,
const WellState& well_state,
const int perf,
const EvalWell& water_flux_s,
DeferredLogger& deferred_logger)
{
const int cell_idx = well_cells_[perf];
const auto& int_quants = *(ebosSimulator.model().cachedIntensiveQuantities(cell_idx, /*timeIdx=*/ 0));
const auto& fs = int_quants.fluidState();
const EvalWell b_w = this->extendEval(fs.invB(FluidSystem::waterPhaseIdx));
const EvalWell water_flux_r = water_flux_s / b_w;
const double area = M_PI * bore_diameters_[perf] * perf_length_[perf];
const EvalWell water_velocity = water_flux_r / area;
const int wat_vel_index = Bhp + 1 + perf;
// equation for the water velocity
const EvalWell eq_wat_vel = this->primary_variables_evaluation_[wat_vel_index] - water_velocity;
this->resWell_[0][wat_vel_index] = eq_wat_vel.value();
const auto& perf_data = well_state.perfData(this->index_of_well_);
const auto& perf_water_throughput = perf_data.water_throughput;
const double throughput = perf_water_throughput[perf];
const int pskin_index = Bhp + 1 + number_of_perforations_ + perf;
EvalWell poly_conc(this->numWellEq_ + numEq, 0.0);
poly_conc.setValue(wpolymer());
// equation for the skin pressure
const EvalWell eq_pskin = this->primary_variables_evaluation_[pskin_index]
- pskin(throughput, this->primary_variables_evaluation_[wat_vel_index], poly_conc, deferred_logger);
this->resWell_[0][pskin_index] = eq_pskin.value();
for (int pvIdx = 0; pvIdx < this->numWellEq_; ++pvIdx) {
this->invDuneD_[0][0][wat_vel_index][pvIdx] = eq_wat_vel.derivative(pvIdx+numEq);
this->invDuneD_[0][0][pskin_index][pvIdx] = eq_pskin.derivative(pvIdx+numEq);
}
// the water velocity is impacted by the reservoir primary varaibles. It needs to enter matrix B
for (int pvIdx = 0; pvIdx < numEq; ++pvIdx) {
this->duneB_[0][cell_idx][wat_vel_index][pvIdx] = eq_wat_vel.derivative(pvIdx);
}
}
template<typename TypeTag>
void
StandardWell<TypeTag>::
checkConvergenceExtraEqs(const std::vector<double>& res,
ConvergenceReport& report) const
{
// if different types of extra equations are involved, this function needs to be refactored further
// checking the convergence of the extra equations related to polymer injectivity
if constexpr (Base::has_polymermw) {
this->checkConvergencePolyMW(res, report, param_.max_residual_allowed_);
}
}
template<typename TypeTag>
void
StandardWell<TypeTag>::
updateConnectionRatePolyMW(const EvalWell& cq_s_poly,
const IntensiveQuantities& int_quants,
const WellState& well_state,
const int perf,
std::vector<RateVector>& connectionRates,
DeferredLogger& deferred_logger) const
{
// the source term related to transport of molecular weight
EvalWell cq_s_polymw = cq_s_poly;
if (this->isInjector()) {
const int wat_vel_index = Bhp + 1 + perf;
const EvalWell water_velocity = this->primary_variables_evaluation_[wat_vel_index];
if (water_velocity > 0.) { // injecting
const auto& perf_water_throughput = well_state.perfData(this->index_of_well_).water_throughput;
const double throughput = perf_water_throughput[perf];
const EvalWell molecular_weight = wpolymermw(throughput, water_velocity, deferred_logger);
cq_s_polymw *= molecular_weight;
} else {
// we do not consider the molecular weight from the polymer
// going-back to the wellbore through injector
cq_s_polymw *= 0.;
}
} else if (this->isProducer()) {
if (cq_s_polymw < 0.) {
cq_s_polymw *= this->extendEval(int_quants.polymerMoleWeight() );
} else {
// we do not consider the molecular weight from the polymer
// re-injecting back through producer
cq_s_polymw *= 0.;
}
}
connectionRates[perf][this->contiPolymerMWEqIdx] = Base::restrictEval(cq_s_polymw);
}
template<typename TypeTag>
std::optional<double>
StandardWell<TypeTag>::
computeBhpAtThpLimitProd(const WellState& well_state,
const Simulator& ebos_simulator,
const SummaryState& summary_state,
DeferredLogger& deferred_logger) const
{
return computeBhpAtThpLimitProdWithAlq(ebos_simulator,
summary_state,
deferred_logger,
getALQ(well_state));
}
template<typename TypeTag>
std::optional<double>
StandardWell<TypeTag>::
computeBhpAtThpLimitProdWithAlq(const Simulator& ebos_simulator,
const SummaryState& summary_state,
DeferredLogger& deferred_logger,
double alq_value) const
{
// Make the frates() function.
auto frates = [this, &ebos_simulator, &deferred_logger](const double bhp) {
// Not solving the well equations here, which means we are
// calculating at the current Fg/Fw values of the
// well. This does not matter unless the well is
// crossflowing, and then it is likely still a good
// approximation.
std::vector<double> rates(3);
computeWellRatesWithBhp(ebos_simulator, bhp, rates, deferred_logger);
return rates;
};
return this->StandardWellGeneric<Scalar>::computeBhpAtThpLimitProdWithAlq(frates,
summary_state,
deferred_logger,
alq_value);
}
template<typename TypeTag>
std::optional<double>
StandardWell<TypeTag>::
computeBhpAtThpLimitInj(const Simulator& ebos_simulator,
const SummaryState& summary_state,
DeferredLogger& deferred_logger) const
{
// Make the frates() function.
auto frates = [this, &ebos_simulator, &deferred_logger](const double bhp) {
// Not solving the well equations here, which means we are
// calculating at the current Fg/Fw values of the
// well. This does not matter unless the well is
// crossflowing, and then it is likely still a good
// approximation.
std::vector<double> rates(3);
computeWellRatesWithBhp(ebos_simulator, bhp, rates, deferred_logger);
return rates;
};
return this->StandardWellGeneric<Scalar>::computeBhpAtThpLimitInj(frates,
summary_state,
deferred_logger);
}
template<typename TypeTag>
bool
StandardWell<TypeTag>::
iterateWellEqWithControl(const Simulator& ebosSimulator,
const double dt,
const Well::InjectionControls& inj_controls,
const Well::ProductionControls& prod_controls,
WellState& well_state,
const GroupState& group_state,
DeferredLogger& deferred_logger)
{
const int max_iter = param_.max_inner_iter_wells_;
int it = 0;
bool converged;
do {
assembleWellEqWithoutIteration(ebosSimulator, dt, inj_controls, prod_controls, well_state, group_state, deferred_logger);
auto report = getWellConvergence(well_state, Base::B_avg_, deferred_logger);
converged = report.converged();
if (converged) {
break;
}
++it;
solveEqAndUpdateWellState(well_state, deferred_logger);
// TODO: when this function is used for well testing purposes, will need to check the controls, so that we will obtain convergence
// under the most restrictive control. Based on this converged results, we can check whether to re-open the well. Either we refactor
// this function or we use different functions for the well testing purposes.
// We don't allow for switching well controls while computing well potentials and testing wells
// updateWellControl(ebosSimulator, well_state, deferred_logger);
initPrimaryVariablesEvaluation();
} while (it < max_iter);
return converged;
}
template<typename TypeTag>
std::vector<double>
StandardWell<TypeTag>::
computeCurrentWellRates(const Simulator& ebosSimulator,
DeferredLogger& deferred_logger) const
{
// Calculate the rates that follow from the current primary variables.
std::vector<EvalWell> well_q_s(num_components_, {this->numWellEq_ + numEq, 0.});
const EvalWell& bhp = this->getBhp();
const bool allow_cf = getAllowCrossFlow() || openCrossFlowAvoidSingularity(ebosSimulator);
for (int perf = 0; perf < number_of_perforations_; ++perf) {
const int cell_idx = well_cells_[perf];
const auto& intQuants = *(ebosSimulator.model().cachedIntensiveQuantities(cell_idx, /*timeIdx=*/ 0));
std::vector<EvalWell> mob(num_components_, {this->numWellEq_ + numEq, 0.});
getMobility(ebosSimulator, perf, mob, deferred_logger);
std::vector<EvalWell> cq_s(num_components_, {this->numWellEq_ + numEq, 0.});
double perf_dis_gas_rate = 0.;
double perf_vap_oil_rate = 0.;
double trans_mult = ebosSimulator.problem().template rockCompTransMultiplier<double>(intQuants, cell_idx);
const double Tw = well_index_[perf] * trans_mult;
computePerfRate(intQuants, mob, bhp, Tw, perf, allow_cf,
cq_s, perf_dis_gas_rate, perf_vap_oil_rate, deferred_logger);
for (int comp = 0; comp < num_components_; ++comp) {
well_q_s[comp] += cq_s[comp];
}
}
std::vector<double> well_q_s_noderiv(well_q_s.size());
for (int comp = 0; comp < num_components_; ++comp) {
well_q_s_noderiv[comp] = well_q_s[comp].value();
}
const auto& comm = this->parallel_well_info_.communication();
if (comm.size() > 1)
{
comm.sum(well_q_s_noderiv.data(), well_q_s_noderiv.size());
}
return well_q_s_noderiv;
}
template <typename TypeTag>
void
StandardWell<TypeTag>::
computeConnLevelProdInd(const typename StandardWell<TypeTag>::FluidState& fs,
const std::function<double(const double)>& connPICalc,
const std::vector<EvalWell>& mobility,
double* connPI) const
{
const auto& pu = this->phaseUsage();
const int np = this->number_of_phases_;
for (int p = 0; p < np; ++p) {
// Note: E100's notion of PI value phase mobility includes
// the reciprocal FVF.
const auto connMob =
mobility[ flowPhaseToEbosCompIdx(p) ].value()
* fs.invB(flowPhaseToEbosPhaseIdx(p)).value();
connPI[p] = connPICalc(connMob);
}
if (FluidSystem::phaseIsActive(FluidSystem::oilPhaseIdx) &&
FluidSystem::phaseIsActive(FluidSystem::gasPhaseIdx))
{
const auto io = pu.phase_pos[Oil];
const auto ig = pu.phase_pos[Gas];
const auto vapoil = connPI[ig] * fs.Rv().value();
const auto disgas = connPI[io] * fs.Rs().value();
connPI[io] += vapoil;
connPI[ig] += disgas;
}
}
template <typename TypeTag>
void
StandardWell<TypeTag>::
computeConnLevelInjInd(const typename StandardWell<TypeTag>::FluidState& fs,
const Phase preferred_phase,
const std::function<double(const double)>& connIICalc,
const std::vector<EvalWell>& mobility,
double* connII,
DeferredLogger& deferred_logger) const
{
// Assumes single phase injection
const auto& pu = this->phaseUsage();
auto phase_pos = 0;
if (preferred_phase == Phase::GAS) {
phase_pos = pu.phase_pos[Gas];
}
else if (preferred_phase == Phase::OIL) {
phase_pos = pu.phase_pos[Oil];
}
else if (preferred_phase == Phase::WATER) {
phase_pos = pu.phase_pos[Water];
}
else {
OPM_DEFLOG_THROW(NotImplemented,
"Unsupported Injector Type ("
<< static_cast<int>(preferred_phase)
<< ") for well " << this->name()
<< " during connection I.I. calculation",
deferred_logger);
}
const auto zero = EvalWell { this->numWellEq_ + this->numEq, 0.0 };
const auto mt = std::accumulate(mobility.begin(), mobility.end(), zero);
connII[phase_pos] = connIICalc(mt.value() * fs.invB(flowPhaseToEbosPhaseIdx(phase_pos)).value());
}
} // namespace Opm