/* Copyright 2017 SINTEF Digital, Mathematics and Cybernetics. Copyright 2017 Statoil ASA. Copyright 2018 IRIS 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 . */ #include #include #include #include #include namespace Opm { template WellInterface:: WellInterface(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& perf_data) : WellInterfaceIndices(well, pw_info, time_step, rate_converter, pvtRegionIdx, num_components, num_phases, index_of_well, perf_data) , param_(param) { connectionRates_.resize(this->number_of_perforations_); if constexpr (has_solvent || has_zFraction) { if (well.isInjector()) { auto injectorType = this->well_ecl_.injectorType(); if (injectorType == InjectorType::GAS) { this->wsolvent_ = this->well_ecl_.getSolventFraction(); } } } } template void WellInterface:: init(const PhaseUsage* phase_usage_arg, const std::vector& /* depth_arg */, const double gravity_arg, const int /* num_cells */, const std::vector< Scalar >& B_avg, const bool changed_to_open_this_step) { this->phase_usage_ = phase_usage_arg; this->gravity_ = gravity_arg; B_avg_ = B_avg; this->changed_to_open_this_step_ = changed_to_open_this_step; } template double WellInterface:: wpolymer() const { if constexpr (has_polymer) { auto injectorType = this->well_ecl_.injectorType(); if (injectorType == InjectorType::WATER) { WellPolymerProperties polymer = this->well_ecl_.getPolymerProperties(); const double polymer_injection_concentration = polymer.m_polymerConcentration; return polymer_injection_concentration; } else { // Not a water injection well => no polymer. return 0.0; } } return 0.0; } template double WellInterface:: wfoam() const { if constexpr (has_foam) { auto injectorType = this->well_ecl_.injectorType(); if (injectorType == InjectorType::GAS) { WellFoamProperties fprop = this->well_ecl_.getFoamProperties(); return fprop.m_foamConcentration; } else { // Not a gas injection well => no foam. return 0.0; } } return 0.0; } template double WellInterface:: wsalt() const { if constexpr (has_brine) { auto injectorType = this->well_ecl_.injectorType(); if (injectorType == InjectorType::WATER) { WellBrineProperties fprop = this->well_ecl_.getBrineProperties(); return fprop.m_saltConcentration; } else { // Not a water injection well => no salt (?). return 0.0; } } return 0.0; } template double WellInterface:: wmicrobes() const { if constexpr (has_micp) { auto injectorType = this->well_ecl_.injectorType(); if (injectorType == InjectorType::WATER) { WellMICPProperties microbes = this->well_ecl_.getMICPProperties(); const double microbial_injection_concentration = microbes.m_microbialConcentration; return microbial_injection_concentration; } else { // Not a water injection well => no microbes. return 0.0; } } return 0.0; } template double WellInterface:: woxygen() const { if constexpr (has_micp) { auto injectorType = this->well_ecl_.injectorType(); if (injectorType == InjectorType::WATER) { WellMICPProperties oxygen = this->well_ecl_.getMICPProperties(); const double oxygen_injection_concentration = oxygen.m_oxygenConcentration; return oxygen_injection_concentration; } else { // Not a water injection well => no oxygen. return 0.0; } } return 0.0; } // The urea injection concentration is scaled down by a factor of 10, since its value // can be much bigger than 1 (not doing this slows the simulations). The // corresponding values are scaled accordingly in blackoilmicpmodules.hh when computing // the reactions and also when writing the output files (vtk and eclipse format, i.e., // vtkblackoilmicpmodule.hh and ecloutputblackoilmodel.hh respectively). template double WellInterface:: wurea() const { if constexpr (has_micp) { auto injectorType = this->well_ecl_.injectorType(); if (injectorType == InjectorType::WATER) { WellMICPProperties urea = this->well_ecl_.getMICPProperties(); const double urea_injection_concentration = urea.m_ureaConcentration / 10.; //Dividing by scaling factor 10 return urea_injection_concentration; } else { // Not a water injection well => no urea. return 0.0; } } return 0.0; } template bool WellInterface:: updateWellControl(const Simulator& ebos_simulator, const IndividualOrGroup iog, WellState& well_state, const GroupState& group_state, DeferredLogger& deferred_logger) /* const */ { if (!this->isOperableAndSolvable() || this->wellIsStopped()) { return false; } const auto& summaryState = ebos_simulator.vanguard().summaryState(); const auto& schedule = ebos_simulator.vanguard().schedule(); const auto& well = this->well_ecl_; auto& ws = well_state.well(this->index_of_well_); std::string from; if (well.isInjector()) { from = Well::InjectorCMode2String(ws.injection_cmode); } else { from = Well::ProducerCMode2String(ws.production_cmode); } bool oscillating = std::count(this->well_control_log_.begin(), this->well_control_log_.end(), from) >= param_.max_number_of_well_switches_; if (oscillating) { // only output frist time bool output = std::count(this->well_control_log_.begin(), this->well_control_log_.end(), from) == param_.max_number_of_well_switches_; if (output) { std::ostringstream ss; ss << " The control model for well " << this->name() << " is oscillating\n" << " We don't allow for more than " << param_.max_number_of_well_switches_ << " switches. The control is kept at " << from; deferred_logger.info(ss.str()); // add one more to avoid outputting the same info again this->well_control_log_.push_back(from); } return false; } bool changed = false; if (iog == IndividualOrGroup::Individual) { changed = this->checkIndividualConstraints(ws, summaryState, deferred_logger); } else if (iog == IndividualOrGroup::Group) { changed = this->checkGroupConstraints(well_state, group_state, schedule, summaryState, deferred_logger); } else { assert(iog == IndividualOrGroup::Both); changed = this->checkConstraints(well_state, group_state, schedule, summaryState, deferred_logger); } Parallel::Communication cc = ebos_simulator.vanguard().grid().comm(); // checking whether control changed if (changed) { std::string to; if (well.isInjector()) { to = Well::InjectorCMode2String(ws.injection_cmode); } else { to = Well::ProducerCMode2String(ws.production_cmode); } std::ostringstream ss; ss << " Switching control mode for well " << this->name() << " from " << from << " to " << to; if (cc.size() > 1) { ss << " on rank " << cc.rank(); } deferred_logger.debug(ss.str()); this->well_control_log_.push_back(from); updateWellStateWithTarget(ebos_simulator, group_state, well_state, deferred_logger); updatePrimaryVariables(well_state, deferred_logger); } return changed; } template void WellInterface:: wellTesting(const Simulator& simulator, const double simulation_time, /* const */ WellState& well_state, const GroupState& group_state, WellTestState& well_test_state, DeferredLogger& deferred_logger) { deferred_logger.info(" well " + this->name() + " is being tested"); WellState well_state_copy = well_state; auto& ws = well_state_copy.well(this->indexOfWell()); updateWellStateWithTarget(simulator, group_state, well_state_copy, deferred_logger); calculateExplicitQuantities(simulator, well_state_copy, deferred_logger); updatePrimaryVariables(well_state_copy, deferred_logger); initPrimaryVariablesEvaluation(); if (this->isProducer()) { gliftBeginTimeStepWellTestUpdateALQ(simulator, well_state_copy, deferred_logger); } WellTestState welltest_state_temp; bool testWell = true; // if a well is closed because all completions are closed, we need to check each completion // individually. We first open all completions, then we close one by one by calling updateWellTestState // untill the number of closed completions do not increase anymore. while (testWell) { const size_t original_number_closed_completions = welltest_state_temp.num_closed_completions(); bool converged = solveWellForTesting(simulator, well_state_copy, group_state, deferred_logger); if (!converged) { const auto msg = fmt::format("WTEST: Well {} is not solvable (physical)", this->name()); deferred_logger.debug(msg); return; } updateWellOperability(simulator, well_state_copy, deferred_logger); if ( !this->isOperableAndSolvable() ) { const auto msg = fmt::format("WTEST: Well {} is not operable (physical)", this->name()); deferred_logger.debug(msg); return; } std::vector potentials; try { computeWellPotentials(simulator, well_state_copy, potentials, deferred_logger); } catch (const std::exception& e) { const std::string msg = std::string("well ") + this->name() + std::string(": computeWellPotentials() failed during testing for re-opening: ") + e.what(); deferred_logger.info(msg); return; } const int np = well_state_copy.numPhases(); for (int p = 0; p < np; ++p) { ws.well_potentials[p] = std::max(0.0, potentials[p]); } this->updateWellTestState(well_state_copy.well(this->indexOfWell()), simulation_time, /*writeMessageToOPMLog=*/ false, welltest_state_temp, deferred_logger); this->closeCompletions(welltest_state_temp); // Stop testing if the well is closed or shut due to all completions shut // Also check if number of completions has increased. If the number of closed completions do not increased // we stop the testing. // TODO: it can be tricky here, if the well is shut/closed due to other reasons if ( welltest_state_temp.num_closed_wells() > 0 || (original_number_closed_completions == welltest_state_temp.num_closed_completions()) ) { testWell = false; // this terminates the while loop } } // update wellTestState if the well test succeeds if (!welltest_state_temp.well_is_closed(this->name())) { well_test_state.open_well(this->name()); std::string msg = std::string("well ") + this->name() + std::string(" is re-opened"); deferred_logger.info(msg); // also reopen completions for (auto& completion : this->well_ecl_.getCompletions()) { if (!welltest_state_temp.completion_is_closed(this->name(), completion.first)) well_test_state.open_completion(this->name(), completion.first); } // set the status of the well_state to open ws.open(); well_state = well_state_copy; } } template bool WellInterface:: iterateWellEquations(const Simulator& ebosSimulator, const double dt, WellState& well_state, const GroupState& group_state, DeferredLogger& deferred_logger) { const auto& summary_state = ebosSimulator.vanguard().summaryState(); const auto inj_controls = this->well_ecl_.isInjector() ? this->well_ecl_.injectionControls(summary_state) : Well::InjectionControls(0); const auto prod_controls = this->well_ecl_.isProducer() ? this->well_ecl_.productionControls(summary_state) : Well::ProductionControls(0); bool converged = false; try { converged = this->iterateWellEqWithControl(ebosSimulator, dt, inj_controls, prod_controls, well_state, group_state, deferred_logger); } catch (NumericalIssue& e ) { const std::string msg = "Inner well iterations failed for well " + this->name() + " Treat the well as unconverged. "; deferred_logger.warning("INNER_ITERATION_FAILED", msg); converged = false; } return converged; } template bool WellInterface:: solveWellForTesting(const Simulator& ebosSimulator, WellState& well_state, const GroupState& group_state, DeferredLogger& deferred_logger) { // keep a copy of the original well state const WellState well_state0 = well_state; const double dt = ebosSimulator.timeStepSize(); const auto& summary_state = ebosSimulator.vanguard().summaryState(); const bool has_thp_limit = this->wellHasTHPConstraints(summary_state); if (has_thp_limit) well_state.well(this->indexOfWell()).production_cmode = Well::ProducerCMode::THP; else well_state.well(this->indexOfWell()).production_cmode = Well::ProducerCMode::BHP; const bool converged = iterateWellEquations(ebosSimulator, dt, well_state, group_state, deferred_logger); if (converged) { deferred_logger.debug("WellTest: Well equation for well " + this->name() + " converged"); return true; } const int max_iter = param_.max_welleq_iter_; deferred_logger.debug("WellTest: Well equation for well " + this->name() + " failed converging in " + std::to_string(max_iter) + " iterations"); well_state = well_state0; return false; } template void WellInterface:: solveWellEquation(const Simulator& ebosSimulator, WellState& well_state, const GroupState& group_state, DeferredLogger& deferred_logger) { if (!this->isOperableAndSolvable() && !this->wellIsStopped()) return; // keep a copy of the original well state const WellState well_state0 = well_state; const double dt = ebosSimulator.timeStepSize(); bool converged = iterateWellEquations(ebosSimulator, dt, well_state, group_state, deferred_logger); // Newly opened wells with THP control sometimes struggles to // converge due to bad initial guess. Or due to the simple fact // that the well needs to change to another control. // We therefore try to solve the well with BHP control to get // an better initial guess. // If the well is supposed to operate under THP control // "updateWellControl" will switch it back to THP later. if (!converged) { auto& ws = well_state.well(this->indexOfWell()); bool thp_control = false; if (this->well_ecl_.isInjector()) { thp_control = ws.injection_cmode == Well::InjectorCMode::THP; if (thp_control) { ws.injection_cmode = Well::InjectorCMode::BHP; this->well_control_log_.push_back(Well::InjectorCMode2String(Well::InjectorCMode::THP)); } } else { thp_control = ws.production_cmode == Well::ProducerCMode::THP; if (thp_control) { ws.production_cmode = Well::ProducerCMode::BHP; this->well_control_log_.push_back(Well::ProducerCMode2String(Well::ProducerCMode::THP)); } } if (thp_control) { const std::string msg = std::string("The newly opened well ") + this->name() + std::string(" with THP control did not converge during inner iterations, we try again with bhp control"); deferred_logger.debug(msg); converged = this->iterateWellEquations(ebosSimulator, dt, well_state, group_state, deferred_logger); } } if (!converged) { const int max_iter = param_.max_welleq_iter_; deferred_logger.debug("Compute initial well solution for well " + this->name() + ". Failed to converge in " + std::to_string(max_iter) + " iterations"); well_state = well_state0; } } template void WellInterface:: assembleWellEq(const Simulator& ebosSimulator, const double dt, WellState& well_state, const GroupState& group_state, DeferredLogger& deferred_logger) { const bool old_well_operable = this->operability_status_.isOperableAndSolvable(); if (param_.check_well_operability_iter_) checkWellOperability(ebosSimulator, well_state, deferred_logger); // only use inner well iterations for the first newton iterations. const int iteration_idx = ebosSimulator.model().newtonMethod().numIterations(); if (iteration_idx < param_.max_niter_inner_well_iter_ || this->well_ecl_.isMultiSegment()) { this->operability_status_.solvable = true; bool converged = this->iterateWellEquations(ebosSimulator, dt, well_state, group_state, deferred_logger); // unsolvable wells are treated as not operable and will not be solved for in this iteration. if (!converged) { if (param_.shut_unsolvable_wells_) this->operability_status_.solvable = false; } } if (this->operability_status_.has_negative_potentials) { auto well_state_copy = well_state; std::vector potentials; try { computeWellPotentials(ebosSimulator, well_state_copy, potentials, deferred_logger); } catch (const std::exception& e) { const std::string msg = std::string("well ") + this->name() + std::string(": computeWellPotentials() failed during attempt to recompute potentials for well : ") + e.what(); deferred_logger.info(msg); this->operability_status_.has_negative_potentials = true; } auto& ws = well_state.well(this->indexOfWell()); const int np = well_state.numPhases(); for (int p = 0; p < np; ++p) { ws.well_potentials[p] = std::max(0.0, potentials[p]); } } this->changed_to_open_this_step_ = false; const bool well_operable = this->operability_status_.isOperableAndSolvable(); if (!well_operable && old_well_operable) { if (this->well_ecl_.getAutomaticShutIn()) { deferred_logger.info(" well " + this->name() + " gets SHUT during iteration "); } else { if (!this->wellIsStopped()) { deferred_logger.info(" well " + this->name() + " gets STOPPED during iteration "); this->stopWell(); changed_to_stopped_this_step_ = true; } } } else if (well_operable && !old_well_operable) { deferred_logger.info(" well " + this->name() + " gets REVIVED during iteration "); this->openWell(); changed_to_stopped_this_step_ = false; this->changed_to_open_this_step_ = true; } const auto& summary_state = ebosSimulator.vanguard().summaryState(); const auto inj_controls = this->well_ecl_.isInjector() ? this->well_ecl_.injectionControls(summary_state) : Well::InjectionControls(0); const auto prod_controls = this->well_ecl_.isProducer() ? this->well_ecl_.productionControls(summary_state) : Well::ProductionControls(0); assembleWellEqWithoutIteration(ebosSimulator, dt, inj_controls, prod_controls, well_state, group_state, deferred_logger); } template bool WellInterface::isPressureControlled(const WellState& well_state) const { bool thp_controlled_well = false; bool bhp_controlled_well = false; const auto& ws = well_state.well(this->index_of_well_); if (this->isInjector()) { const Well::InjectorCMode& current = ws.injection_cmode; if (current == Well::InjectorCMode::THP) { thp_controlled_well = true; } if (current == Well::InjectorCMode::BHP) { bhp_controlled_well = true; } } else { const Well::ProducerCMode& current = ws.production_cmode; if (current == Well::ProducerCMode::THP) { thp_controlled_well = true; } if (current == Well::ProducerCMode::BHP) { bhp_controlled_well = true; } } bool ispressureControlled = (bhp_controlled_well || thp_controlled_well); return ispressureControlled; } template void WellInterface::addCellRates(RateVector& rates, int cellIdx) const { if(!this->isOperableAndSolvable() && !this->wellIsStopped()) return; for (int perfIdx = 0; perfIdx < this->number_of_perforations_; ++perfIdx) { if (this->cells()[perfIdx] == cellIdx) { for (int i = 0; i < RateVector::dimension; ++i) { rates[i] += connectionRates_[perfIdx][i]; } } } } template typename WellInterface::Scalar WellInterface::volumetricSurfaceRateForConnection(int cellIdx, int phaseIdx) const { for (int perfIdx = 0; perfIdx < this->number_of_perforations_; ++perfIdx) { if (this->cells()[perfIdx] == cellIdx) { const unsigned activeCompIdx = Indices::canonicalToActiveComponentIndex(FluidSystem::solventComponentIndex(phaseIdx)); return connectionRates_[perfIdx][activeCompIdx].value(); } } // this is not thread safe OPM_THROW(std::invalid_argument, "The well with name " + this->name() + " does not perforate cell " + std::to_string(cellIdx)); return 0.0; } template void WellInterface:: checkWellOperability(const Simulator& ebos_simulator, const WellState& well_state, DeferredLogger& deferred_logger) { if (!param_.check_well_operability_) { return; } if (this->wellIsStopped() && !changed_to_stopped_this_step_) { return; } updateWellOperability(ebos_simulator, well_state, deferred_logger); if (!this->operability_status_.isOperableAndSolvable()) { this->operability_status_.use_vfpexplicit = true; deferred_logger.debug("EXPLICIT_LOOKUP_VFP", "well not operable, trying with explicit vfp lookup: " + this->name()); updateWellOperability(ebos_simulator, well_state, deferred_logger); } } template void WellInterface:: gliftBeginTimeStepWellTestUpdateALQ(const Simulator& ebos_simulator, WellState& well_state, DeferredLogger& deferred_logger) { const auto& summary_state = ebos_simulator.vanguard().summaryState(); const auto& well_name = this->name(); if (!this->wellHasTHPConstraints(summary_state)) { const std::string msg = fmt::format("GLIFT WTEST: Well {} does not have THP constraints", well_name); deferred_logger.info(msg); return; } const auto& well_ecl = this->wellEcl(); const auto& schedule = ebos_simulator.vanguard().schedule(); auto report_step_idx = ebos_simulator.episodeIndex(); const auto& glo = schedule.glo(report_step_idx); if (!glo.has_well(well_name)) { const std::string msg = fmt::format( "GLIFT WTEST: Well {} : Gas Lift not activated: " "WLIFTOPT is probably missing. Skipping.", well_name); deferred_logger.info(msg); return; } const auto& gl_well = glo.well(well_name); auto& max_alq_optional = gl_well.max_rate(); double max_alq; if (max_alq_optional) { max_alq = *max_alq_optional; } else { const auto& controls = well_ecl.productionControls(summary_state); const auto& table = this->vfpProperties()->getProd()->getTable(controls.vfp_table_number); const auto& alq_values = table.getALQAxis(); max_alq = alq_values.back(); } well_state.setALQ(well_name, max_alq); const std::string msg = fmt::format( "GLIFT WTEST: Well {} : Setting ALQ to max value: {}", well_name, max_alq); deferred_logger.info(msg); } template void WellInterface:: updateWellOperability(const Simulator& ebos_simulator, const WellState& well_state, DeferredLogger& deferred_logger) { this->operability_status_.resetOperability(); bool thp_controled = this->isInjector() ? well_state.well(this->index_of_well_).injection_cmode == Well::InjectorCMode::THP: well_state.well(this->index_of_well_).production_cmode == Well::ProducerCMode::THP; bool bhp_controled = this->isInjector() ? well_state.well(this->index_of_well_).injection_cmode == Well::InjectorCMode::BHP: well_state.well(this->index_of_well_).production_cmode == Well::ProducerCMode::BHP; // Operability checking is not free // Only check wells under BHP and THP control bool check_thp = thp_controled || this->operability_status_.thp_limit_violated_but_not_switched; if (check_thp || bhp_controled) { updateIPR(ebos_simulator, deferred_logger); checkOperabilityUnderBHPLimit(well_state, ebos_simulator, deferred_logger); } // we do some extra checking for wells under THP control. if (check_thp) { checkOperabilityUnderTHPLimit(ebos_simulator, well_state, deferred_logger); } } template void WellInterface:: updateWellStateWithTarget(const Simulator& ebos_simulator, const GroupState& group_state, WellState& well_state, DeferredLogger& deferred_logger) const { // only bhp and wellRates are used to initilize the primaryvariables for standard wells const auto& well = this->well_ecl_; const int well_index = this->index_of_well_; auto& ws = well_state.well(well_index); const auto& pu = this->phaseUsage(); const int np = well_state.numPhases(); const auto& summaryState = ebos_simulator.vanguard().summaryState(); const auto& schedule = ebos_simulator.vanguard().schedule(); if (this->wellIsStopped()) { for (int p = 0; pisInjector() ) { const auto& controls = well.injectionControls(summaryState); InjectorType injectorType = controls.injector_type; int phasePos; switch (injectorType) { case InjectorType::WATER: { phasePos = pu.phase_pos[BlackoilPhases::Aqua]; break; } case InjectorType::OIL: { phasePos = pu.phase_pos[BlackoilPhases::Liquid]; break; } case InjectorType::GAS: { phasePos = pu.phase_pos[BlackoilPhases::Vapour]; break; } default: OPM_DEFLOG_THROW(std::runtime_error, "Expected WATER, OIL or GAS as type for injectors " + this->name(), deferred_logger ); } const auto current = ws.injection_cmode; switch(current) { case Well::InjectorCMode::RATE: { ws.surface_rates[phasePos] = (1.0 - this->rsRvInj()) * controls.surface_rate; if(this->rsRvInj() > 0) { if (injectorType == InjectorType::OIL && FluidSystem::phaseIsActive(FluidSystem::gasPhaseIdx)) { ws.surface_rates[pu.phase_pos[BlackoilPhases::Vapour]] = controls.surface_rate * this->rsRvInj(); } else if (injectorType == InjectorType::GAS && FluidSystem::phaseIsActive(FluidSystem::oilPhaseIdx)) { ws.surface_rates[pu.phase_pos[BlackoilPhases::Liquid]] = controls.surface_rate * this->rsRvInj(); } else { OPM_DEFLOG_THROW(std::runtime_error, "Expected OIL or GAS as type for injectors when RS/RV (item 10) is non-zero " + this->name(), deferred_logger ); } } break; } case Well::InjectorCMode::RESV: { std::vector convert_coeff(this->number_of_phases_, 1.0); this->rateConverter_.calcCoeff(/*fipreg*/ 0, this->pvtRegionIdx_, convert_coeff); const double coeff = convert_coeff[phasePos]; ws.surface_rates[phasePos] = controls.reservoir_rate/coeff; break; } case Well::InjectorCMode::THP: { auto rates = ws.surface_rates; double bhp = this->calculateBhpFromThp(well_state, rates, well, summaryState, this->getRefDensity(), deferred_logger); ws.bhp = bhp; ws.thp = this->getTHPConstraint(summaryState); // if the total rates are negative or zero // we try to provide a better intial well rate // using the well potentials double total_rate = std::accumulate(rates.begin(), rates.end(), 0.0); if (total_rate <= 0.0) ws.surface_rates = ws.well_potentials; break; } case Well::InjectorCMode::BHP: { ws.bhp = controls.bhp_limit; double total_rate = 0.0; for (int p = 0; pcurrentStep()); const double efficiencyFactor = well.getEfficiencyFactor(); std::optional target = this->getGroupInjectionTargetRate(group, well_state, group_state, schedule, summaryState, injectorType, efficiencyFactor, deferred_logger); if (target) ws.surface_rates[phasePos] = *target; break; } case Well::InjectorCMode::CMODE_UNDEFINED: { OPM_DEFLOG_THROW(std::runtime_error, "Well control must be specified for well " + this->name(), deferred_logger ); } } // for wells with zero injection rate, if we assign exactly zero rate, // we will have to assume some trivial composition in the wellbore. // here, we use some small value (about 0.01 m^3/day ~= 1.e-7) to initialize // the zero rate target, then we can use to retain the composition information // within the wellbore from the previous result, and hopefully it is a good // initial guess for the zero rate target. ws.surface_rates[phasePos] = std::max(1.e-7, ws.surface_rates[phasePos]); } //Producer else { const auto current = ws.production_cmode; const auto& controls = well.productionControls(summaryState); switch (current) { case Well::ProducerCMode::ORAT: { double current_rate = -ws.surface_rates[ pu.phase_pos[Oil] ]; // for trivial rates or opposite direction we don't just scale the rates // but use either the potentials or the mobility ratio to initial the well rates if (current_rate > 0.0) { for (int p = 0; p fractions = initialWellRateFractions(ebos_simulator, well_state); double control_fraction = fractions[pu.phase_pos[Oil]]; if (control_fraction != 0.0) { for (int p = 0; p 0.0) { for (int p = 0; p fractions = initialWellRateFractions(ebos_simulator, well_state); double control_fraction = fractions[pu.phase_pos[Water]]; if (control_fraction != 0.0) { for (int p = 0; p 0.0) { for (int p = 0; p fractions = initialWellRateFractions(ebos_simulator, well_state); double control_fraction = fractions[pu.phase_pos[Gas]]; if (control_fraction != 0.0) { for (int p = 0; p 0.0) { for (int p = 0; p fractions = initialWellRateFractions(ebos_simulator, well_state); double control_fraction = fractions[pu.phase_pos[Water]] + fractions[pu.phase_pos[Oil]]; if (control_fraction != 0.0) { for (int p = 0; pname(), deferred_logger); } case Well::ProducerCMode::RESV: { std::vector convert_coeff(this->number_of_phases_, 1.0); this->rateConverter_.calcCoeff(/*fipreg*/ 0, this->pvtRegionIdx_, convert_coeff); double total_res_rate = 0.0; for (int p = 0; p 0.0) { for (int p = 0; p fractions = initialWellRateFractions(ebos_simulator, well_state); for (int p = 0; p hrates(this->number_of_phases_,0.); if (FluidSystem::phaseIsActive(FluidSystem::waterPhaseIdx)) { hrates[pu.phase_pos[Water]] = controls.water_rate; } if (FluidSystem::phaseIsActive(FluidSystem::oilPhaseIdx)) { hrates[pu.phase_pos[Oil]] = controls.oil_rate; } if (FluidSystem::phaseIsActive(FluidSystem::gasPhaseIdx)) { hrates[pu.phase_pos[Gas]] = controls.gas_rate; } std::vector hrates_resv(this->number_of_phases_,0.); this->rateConverter_.calcReservoirVoidageRates(/*fipreg*/ 0, this->pvtRegionIdx_, hrates, hrates_resv); double target = std::accumulate(hrates_resv.begin(), hrates_resv.end(), 0.0); // or trivial rates or opposite direction we don't just scale the rates // but use either the potentials or the mobility ratio to initial the well rates if (total_res_rate > 0.0) { for (int p = 0; p fractions = initialWellRateFractions(ebos_simulator, well_state); for (int p = 0; padaptRatesForVFP(rates); double bhp = this->calculateBhpFromThp(well_state, rates, well, summaryState, this->getRefDensity(), deferred_logger); ws.bhp = bhp; ws.thp = this->getTHPConstraint(summaryState); // if the total rates are negative or zero // we try to provide a better intial well rate // using the well potentials double total_rate = -std::accumulate(rates.begin(), rates.end(), 0.0); if (total_rate <= 0.0){ for (int p = 0; pcurrentStep()); const double efficiencyFactor = well.getEfficiencyFactor(); double scale = this->getGroupProductionTargetRate(group, well_state, group_state, schedule, summaryState, efficiencyFactor); // we don't want to scale with zero and get zero rates. if (scale > 0) { for (int p = 0; pname() , deferred_logger); } break; } // end of switch } } template std::vector WellInterface:: initialWellRateFractions(const Simulator& ebosSimulator, const WellState& well_state) const { const int np = this->number_of_phases_; std::vector scaling_factor(np); const auto& ws = well_state.well(this->index_of_well_); double total_potentials = 0.0; for (int p = 0; p 0) { for (int p = 0; pnumber_of_perforations_; for (int perf = 0; perf < nperf; ++perf) { total_tw += this->well_index_[perf]; } for (int perf = 0; perf < nperf; ++perf) { const int cell_idx = this->well_cells_[perf]; const auto& intQuants = *(ebosSimulator.model().cachedIntensiveQuantities(cell_idx, /*timeIdx=*/0)); const auto& fs = intQuants.fluidState(); const double well_tw_fraction = this->well_index_[perf] / total_tw; double total_mobility = 0.0; for (int p = 0; p < np; ++p) { int ebosPhaseIdx = this->flowPhaseToEbosPhaseIdx(p); total_mobility += fs.invB(ebosPhaseIdx).value() * intQuants.mobility(ebosPhaseIdx).value(); } for (int p = 0; p < np; ++p) { int ebosPhaseIdx = this->flowPhaseToEbosPhaseIdx(p); scaling_factor[p] += well_tw_fraction * fs.invB(ebosPhaseIdx).value() * intQuants.mobility(ebosPhaseIdx).value() / total_mobility; } } return scaling_factor; } template void WellInterface:: updateWellStateRates(const Simulator& ebosSimulator, WellState& well_state, DeferredLogger& deferred_logger) const { // Check if the rates of this well only are single-phase, do nothing // if more than one nonzero rate. auto& ws = well_state.well(this->index_of_well_); int nonzero_rate_index = -1; const double floating_point_error_epsilon = 1e-14; for (int p = 0; p < this->number_of_phases_; ++p) { if (std::abs(ws.surface_rates[p]) > floating_point_error_epsilon) { if (nonzero_rate_index == -1) { nonzero_rate_index = p; } else { // More than one nonzero rate. return; } } } // Calculate the rates that follow from the current primary variables. std::vector well_q_s = computeCurrentWellRates(ebosSimulator, deferred_logger); if (nonzero_rate_index == -1) { // No nonzero rates. // Use the computed rate directly for (int p = 0; p < this->number_of_phases_; ++p) { ws.surface_rates[p] = well_q_s[this->flowPhaseToEbosCompIdx(p)]; } return; } // Set the currently-zero phase flows to be nonzero in proportion to well_q_s. const double initial_nonzero_rate = ws.surface_rates[nonzero_rate_index]; const int comp_idx_nz = this->flowPhaseToEbosCompIdx(nonzero_rate_index); for (int p = 0; p < this->number_of_phases_; ++p) { if (p != nonzero_rate_index) { const int comp_idx = this->flowPhaseToEbosCompIdx(p); double& rate = ws.surface_rates[p]; rate = (initial_nonzero_rate/well_q_s[comp_idx_nz]) * (well_q_s[comp_idx]); } } } template typename WellInterface::Eval WellInterface::getPerfCellPressure(const typename WellInterface::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; } } // namespace Opm