22#ifndef OPM_WELLINTERFACE_IMPL_HEADER_INCLUDED
23#define OPM_WELLINTERFACE_IMPL_HEADER_INCLUDED
26#ifndef OPM_WELLINTERFACE_HEADER_INCLUDED
31#include <opm/common/Exceptions.hpp>
33#include <opm/input/eclipse/Schedule/ScheduleTypes.hpp>
34#include <opm/input/eclipse/Schedule/Well/WDFAC.hpp>
43#include <dune/common/version.hh>
51#include <fmt/format.h>
57 template<
typename TypeTag>
64 const int pvtRegionIdx,
65 const int num_conservation_quantities,
67 const int index_of_well,
75 num_conservation_quantities,
83 if (well.isInjector()) {
84 auto injectorType = this->
well_ecl_.injectorType();
85 if (injectorType == InjectorType::GAS) {
93 template<
typename TypeTag>
96 init(
const std::vector<Scalar>& ,
98 const std::vector<Scalar>& B_avg,
99 const bool changed_to_open_this_step)
101 this->gravity_ = gravity_arg;
103 this->changed_to_open_this_step_ = changed_to_open_this_step;
109 template<
typename TypeTag>
114 if constexpr (has_polymer) {
115 return this->wpolymer_();
125 template<
typename TypeTag>
130 if constexpr (has_foam) {
131 return this->wfoam_();
139 template<
typename TypeTag>
144 if constexpr (has_brine) {
145 return this->wsalt_();
151 template<
typename TypeTag>
156 if constexpr (has_micp) {
157 return this->wmicrobes_();
163 template<
typename TypeTag>
168 if constexpr (has_micp) {
169 return this->woxygen_();
175 template<
typename TypeTag>
180 if constexpr (has_micp) {
181 return this->wurea_();
187 template<
typename TypeTag>
197 if (stoppedOrZeroRateTarget(groupStateHelper)) {
201 const auto& summaryState = simulator.vanguard().summaryState();
202 const auto& schedule = simulator.vanguard().schedule();
203 const auto& well = this->well_ecl_;
204 auto& ws = well_state.
well(this->index_of_well_);
206 bool is_grup =
false;
207 if (well.isInjector()) {
208 from = WellInjectorCMode2String(ws.injection_cmode);
209 is_grup = ws.injection_cmode == Well::InjectorCMode::GRUP;
211 from = WellProducerCMode2String(ws.production_cmode);
212 is_grup = ws.production_cmode == Well::ProducerCMode::GRUP;
215 const int episodeIdx = simulator.episodeIndex();
216 const auto& iterCtx = simulator.problem().iterationContext();
217 const int nupcol = schedule[episodeIdx].nupcol();
218 const bool oscillating =
219 std::ranges::count(this->well_control_log_, from) >= this->param_.max_number_of_well_switches_;
220 if (oscillating && !is_grup) {
223 std::ranges::count(this->well_control_log_, from) == this->param_.max_number_of_well_switches_;
225 const auto msg = fmt::format(
" The control mode for well {} is oscillating. \n"
226 "We don't allow for more than {} switches after NUPCOL iterations. (NUPCOL = {}) \n"
227 "The control is kept at {}.",
228 this->name(), this->param_.max_number_of_well_switches_, nupcol, from);
229 deferred_logger.info(msg);
231 this->well_control_log_.push_back(from);
235 bool changed =
false;
236 if (iog == IndividualOrGroup::Individual) {
237 changed = this->checkIndividualConstraints(ws, summaryState, deferred_logger);
238 }
else if (iog == IndividualOrGroup::Group) {
239 changed = this->checkGroupConstraints(
240 groupStateHelper, schedule, summaryState,
true, well_state
243 assert(iog == IndividualOrGroup::Both);
244 changed = this->checkConstraints(groupStateHelper, schedule, summaryState, well_state);
250 if (well.isInjector()) {
251 to = WellInjectorCMode2String(ws.injection_cmode);
253 to = WellProducerCMode2String(ws.production_cmode);
255 std::ostringstream ss;
256 ss <<
" Switching control mode for well " << this->name()
259 if (iterCtx.inLocalSolve()) {
260 ss <<
" (NLDD domain solve)";
263 ss <<
" on rank " << cc.rank();
265 deferred_logger.debug(ss.str());
272 if (!iterCtx.inLocalSolve()) {
273 if (!iterCtx.withinNupcol(nupcol) || this->well_control_log_.empty()) {
274 this->well_control_log_.push_back(from);
277 updateWellStateWithTarget(simulator, groupStateHelper, well_state);
278 updatePrimaryVariables(groupStateHelper);
284 template<
typename TypeTag>
289 const Well::InjectionControls& inj_controls,
290 const Well::ProductionControls& prod_controls,
293 const bool fixed_control,
294 const bool fixed_status,
295 const bool solving_with_zero_rate)
299 const auto& summary_state = simulator.vanguard().summaryState();
300 const auto& schedule = simulator.vanguard().schedule();
301 auto& ws = well_state.
well(this->index_of_well_);
303 if (this->isInjector()) {
304 from = WellInjectorCMode2String(ws.injection_cmode);
306 from = WellProducerCMode2String(ws.production_cmode);
308 const bool oscillating =
309 std::ranges::count(this->well_control_log_, from) >= this->param_.max_number_of_well_switches_;
311 if (oscillating || this->wellUnderZeroRateTarget(groupStateHelper) || !(well_state.
well(this->index_of_well_).status == WellStatus::OPEN)) {
315 const Scalar sgn = this->isInjector() ? 1.0 : -1.0;
316 if (!this->wellIsStopped()){
317 if (wqTotal*sgn <= 0.0 && !fixed_status){
321 bool changed =
false;
322 if (!fixed_control) {
325 if (solving_with_zero_rate) {
327 "Well {}: solving_with_zero_rate should not be true when fixed_control is false",
328 this->name()), deferred_logger);
334 const bool hasGroupControl = this->isInjector() ? inj_controls.hasControl(Well::InjectorCMode::GRUP) :
335 prod_controls.hasControl(Well::ProducerCMode::GRUP);
336 bool isGroupControl = ws.production_cmode == Well::ProducerCMode::GRUP || ws.injection_cmode == Well::InjectorCMode::GRUP;
337 if (! (isGroupControl && !this->param_.check_group_constraints_inner_well_iterations_)) {
338 changed = this->checkIndividualConstraints(ws, summary_state, deferred_logger, inj_controls, prod_controls);
340 if (hasGroupControl && this->param_.check_group_constraints_inner_well_iterations_) {
341 changed = changed || this->checkGroupConstraints(
342 groupStateHelper, schedule, summary_state,
false, well_state
347 const bool thp_controlled = this->isInjector() ? ws.injection_cmode == Well::InjectorCMode::THP :
348 ws.production_cmode == Well::ProducerCMode::THP;
350 ws.thp = this->getTHPConstraint(summary_state);
353 updateWellStateWithTarget(simulator, groupStateHelper, well_state);
355 updatePrimaryVariables(groupStateHelper);
360 }
else if (!fixed_status){
362 const Scalar bhp = well_state.
well(this->index_of_well_).bhp;
363 Scalar prod_limit = prod_controls.bhp_limit;
364 Scalar inj_limit = inj_controls.bhp_limit;
365 const bool has_thp = this->wellHasTHPConstraints(summary_state);
367 std::vector<Scalar> rates(this->num_conservation_quantities_);
368 if (this->isInjector()){
370 calculateBhpFromThp(well_state, rates,
373 this->getRefDensity(),
375 inj_limit = std::min(bhp_thp,
static_cast<Scalar>(inj_controls.bhp_limit));
380 calculateMinimumBhpFromThp(well_state,
383 this->getRefDensity());
384 prod_limit = std::max(bhp_min,
static_cast<Scalar>(prod_controls.bhp_limit));
387 const Scalar bhp_diff = (this->isInjector())? inj_limit - bhp: bhp - prod_limit;
390 well_state.
well(this->index_of_well_).bhp = (this->isInjector())? inj_limit : prod_limit;
392 well_state.
well(this->index_of_well_).thp = this->getTHPConstraint(summary_state);
403 template<
typename TypeTag>
407 const double simulation_time,
410 WellTestState& well_test_state,
412 std::map<std::string, double>& open_times)
416 const auto& group_state = groupStateHelper.
groupState();
417 deferred_logger.info(
" well " + this->name() +
" is being tested");
424 auto guard = groupStateHelper_copy.
pushWellState(well_state_copy);
425 auto& ws = well_state_copy.
well(this->indexOfWell());
427 const auto& summary_state = simulator.vanguard().summaryState();
428 const bool has_thp_limit = this->wellHasTHPConstraints(summary_state);
429 if (this->isProducer()) {
430 ws.production_cmode = has_thp_limit ? Well::ProducerCMode::THP : Well::ProducerCMode::BHP;
432 ws.injection_cmode = has_thp_limit ? Well::InjectorCMode::THP : Well::InjectorCMode::BHP;
437 scaleSegmentRatesAndPressure(well_state_copy);
438 calculateExplicitQuantities(simulator, groupStateHelper_copy);
439 updatePrimaryVariables(groupStateHelper_copy);
441 if (this->isProducer()) {
442 const auto& schedule = simulator.vanguard().schedule();
443 const auto report_step = simulator.episodeIndex();
444 const auto& glo = schedule.glo(report_step);
446 gliftBeginTimeStepWellTestUpdateALQ(simulator,
454 WellTestState welltest_state_temp;
456 bool testWell =
true;
461 const std::size_t original_number_closed_completions = welltest_state_temp.num_closed_completions();
462 bool converged = solveWellForTesting(simulator, groupStateHelper_copy, well_state_copy);
464 const auto msg = fmt::format(
"WTEST: Well {} is not solvable (physical)", this->name());
465 deferred_logger.debug(msg);
470 updateWellOperability(simulator, well_state_copy, groupStateHelper_copy);
471 if ( !this->isOperableAndSolvable() ) {
472 const auto msg = fmt::format(
"WTEST: Well {} is not operable (physical)", this->name());
473 deferred_logger.debug(msg);
476 std::vector<Scalar> potentials;
478 computeWellPotentials(simulator, well_state_copy, groupStateHelper_copy, potentials);
479 }
catch (
const std::exception& e) {
480 const std::string msg = fmt::format(
"well {}: computeWellPotentials() "
481 "failed during testing for re-opening: ",
482 this->name(), e.what());
483 deferred_logger.info(msg);
486 const int np = well_state_copy.
numPhases();
487 for (
int p = 0; p < np; ++p) {
488 ws.well_potentials[p] = std::max(
Scalar{0.0}, potentials[p]);
490 const bool under_zero_target = this->wellUnderZeroGroupRateTarget(groupStateHelper_copy);
491 this->updateWellTestState(well_state_copy.
well(this->indexOfWell()),
497 simulator.vanguard().eclState().getUnits(),
498 simulator.vanguard().schedule().getStartTime(),
500 this->closeCompletions(welltest_state_temp);
506 if ( welltest_state_temp.num_closed_wells() > 0 ||
507 (original_number_closed_completions == welltest_state_temp.num_closed_completions()) ) {
513 if (!welltest_state_temp.well_is_closed(this->name())) {
514 well_test_state.open_well(this->name());
516 std::string msg = std::string(
"well ") + this->name() + std::string(
" is re-opened");
517 deferred_logger.info(msg);
520 for (
const auto& completion : this->well_ecl_.getCompletions()) {
521 if (!welltest_state_temp.completion_is_closed(this->name(), completion.first))
522 well_test_state.open_completion(this->name(), completion.first);
524 well_state = well_state_copy;
525 open_times.try_emplace(this->name(), well_test_state.lastTestTime(this->name()));
532 template<
typename TypeTag>
543 const auto& summary_state = simulator.vanguard().summaryState();
544 const auto inj_controls = this->well_ecl_.isInjector() ? this->well_ecl_.injectionControls(summary_state) : Well::InjectionControls(0);
545 const auto prod_controls = this->well_ecl_.isProducer() ? this->well_ecl_.productionControls(summary_state) : Well::ProductionControls(0);
546 const auto& ws = well_state.
well(this->indexOfWell());
547 const auto pmode_orig = ws.production_cmode;
548 const auto imode_orig = ws.injection_cmode;
549 bool converged =
false;
552 if (!this->param_.local_well_solver_control_switching_){
553 converged = this->iterateWellEqWithControl(simulator, dt, inj_controls, prod_controls, groupStateHelper, well_state);
555 if (this->param_.use_implicit_ipr_ && this->well_ecl_.isProducer() && (well_state.
well(this->index_of_well_).status == WellStatus::OPEN)) {
556 converged = solveWellWithOperabilityCheck(
557 simulator, dt, inj_controls, prod_controls, groupStateHelper, well_state
560 converged = this->iterateWellEqWithSwitching(
561 simulator, dt, inj_controls, prod_controls, groupStateHelper, well_state,
567 }
catch (NumericalProblem& e ) {
568 const std::string msg =
"Inner well iterations failed for well " + this->name() +
" Treat the well as unconverged. ";
569 deferred_logger.warning(
"INNER_ITERATION_FAILED", msg);
574 if (ws.production_cmode != pmode_orig || ws.injection_cmode != imode_orig) {
576 if (this->isInjector()) {
577 from = WellInjectorCMode2String(imode_orig);
578 to = WellInjectorCMode2String(ws.injection_cmode);
580 from = WellProducerCMode2String(pmode_orig);
581 to = WellProducerCMode2String(ws.production_cmode);
583 const auto msg = fmt::format(
" Well {} switched from {} to {} during local solve", this->name(), from, to);
584 deferred_logger.debug(msg);
585 const int episodeIdx = simulator.episodeIndex();
586 const auto& iterCtx = simulator.problem().iterationContext();
587 const auto& schedule = simulator.vanguard().schedule();
588 const int nupcol = schedule[episodeIdx].nupcol();
592 if (!iterCtx.withinNupcol(nupcol) || this->well_control_log_.empty()) {
593 this->well_control_log_.push_back(from);
598 if (this->isProducer() && ws.production_cmode == Well::ProducerCMode::GRUP && ws.use_group_target_fallback) {
599 assert(ws.group_target && ws.group_target_fallback);
600 const std::string cmode = Group::ProductionCMode2String(ws.group_target->production_cmode);
601 const std::string cmode_fallback = Group::ProductionCMode2String(ws.group_target_fallback->production_cmode);
602 const auto msg = fmt::format(
" Well {} was solved using group target fallback mode {} as current group mode {} was not feasible.",
603 this->name(), cmode_fallback, cmode);
604 deferred_logger.debug(msg);
610 template<
typename TypeTag>
615 const Well::InjectionControls& inj_controls,
616 const Well::ProductionControls& prod_controls,
623 const auto& summary_state = simulator.vanguard().summaryState();
624 bool converged =
true;
625 auto& ws = well_state.
well(this->index_of_well_);
627 if (this->wellIsStopped()) {
629 const bool use_vfpexplicit = this->operability_status_.use_vfpexplicit;
630 this->operability_status_.use_vfpexplicit =
true;
631 auto bhp_target = estimateOperableBhp(simulator, dt, groupStateHelper, summary_state, well_state);
632 if (!bhp_target.has_value()) {
634 const auto msg = fmt::format(
"estimateOperableBhp: Did not find operable BHP for well {}", this->name());
635 deferred_logger.debug(msg);
638 converged = solveWellWithZeroRate(simulator, dt, groupStateHelper, well_state);
640 this->operability_status_.can_obtain_bhp_with_thp_limit =
false;
641 this->operability_status_.obey_thp_limit_under_bhp_limit =
false;
645 ws.thp = this->getTHPConstraint(summary_state);
646 const Scalar bhp = std::max(bhp_target.value(),
647 static_cast<Scalar>(prod_controls.bhp_limit));
648 solveWellWithBhp(simulator, dt, bhp, groupStateHelper, well_state);
649 this->operability_status_.use_vfpexplicit = use_vfpexplicit;
653 converged = this->iterateWellEqWithSwitching(
654 simulator, dt, inj_controls, prod_controls, groupStateHelper, well_state,
659 const bool isThp = ws.production_cmode == Well::ProducerCMode::THP;
661 if (converged && !stoppedOrZeroRateTarget(groupStateHelper) && isThp) {
662 auto rates = well_state.
well(this->index_of_well_).surface_rates;
663 this->adaptRatesForVFP(rates);
664 this->updateIPRImplicit(simulator, groupStateHelper, well_state);
668 this->operability_status_.use_vfpexplicit =
true;
671 const Scalar reltol = 1e-3;
672 const Scalar cur_bhp = ws.bhp;
673 if (bhp_stable.has_value() && cur_bhp - bhp_stable.value() > cur_bhp*reltol){
674 const auto msg = fmt::format(
"Well {} converged to an unstable solution, re-solving", this->name());
675 deferred_logger.debug(msg);
677 simulator, dt, bhp_stable.value(), groupStateHelper, well_state
680 ws.thp = this->getTHPConstraint(summary_state);
681 converged = this->iterateWellEqWithSwitching(
682 simulator, dt, inj_controls, prod_controls, groupStateHelper, well_state,
691 this->operability_status_.use_vfpexplicit =
true;
693 auto bhp_target = estimateOperableBhp(
694 simulator, dt, groupStateHelper, summary_state, well_state
696 if (!bhp_target.has_value()) {
699 converged = solveWellWithZeroRate(simulator, dt, groupStateHelper, well_state);
701 this->operability_status_.can_obtain_bhp_with_thp_limit =
false;
702 this->operability_status_.obey_thp_limit_under_bhp_limit =
false;
706 const Scalar bhp = std::max(bhp_target.value(),
707 static_cast<Scalar>(prod_controls.bhp_limit));
709 simulator, dt, bhp, groupStateHelper, well_state
711 ws.thp = this->getTHPConstraint(summary_state);
712 const auto msg = fmt::format(
"Well {} did not converge, re-solving with explicit fractions for VFP caculations.", this->name());
713 deferred_logger.debug(msg);
714 converged = this->iterateWellEqWithSwitching(simulator, dt,
725 this->operability_status_.can_obtain_bhp_with_thp_limit = !this->wellIsStopped();
726 this->operability_status_.obey_thp_limit_under_bhp_limit = !this->wellIsStopped();
730 template<
typename TypeTag>
731 std::optional<typename WellInterface<TypeTag>::Scalar>
736 const SummaryState& summary_state,
739 if (!this->wellHasTHPConstraints(summary_state)) {
741 const bool converged = solveWellWithBhp(
742 simulator, dt, bhp_limit, groupStateHelper, well_state
744 if (!converged || this->wellIsStopped()) {
755 const bool converged = solveWellWithBhp(
756 simulator, dt, bhp_min, groupStateHelper, well_state
758 if (!converged || this->wellIsStopped()) {
761 this->updateIPRImplicit(simulator, groupStateHelper, well_state);
762 auto rates = well_state.
well(this->index_of_well_).surface_rates;
763 this->adaptRatesForVFP(rates);
767 template<
typename TypeTag>
784 auto group_guard = groupStateHelper_copy.
pushGroupState(group_state);
786 auto inj_controls = Well::InjectionControls(0);
787 auto prod_controls = Well::ProductionControls(0);
788 auto& ws = well_state.
well(this->index_of_well_);
789 auto cmode_inj = ws.injection_cmode;
790 auto cmode_prod = ws.production_cmode;
791 if (this->isInjector()) {
792 inj_controls.addControl(Well::InjectorCMode::BHP);
793 inj_controls.bhp_limit = bhp;
794 inj_controls.cmode = Well::InjectorCMode::BHP;
795 ws.injection_cmode = Well::InjectorCMode::BHP;
797 prod_controls.addControl(Well::ProducerCMode::BHP);
798 prod_controls.bhp_limit = bhp;
799 prod_controls.cmode = Well::ProducerCMode::BHP;
800 ws.production_cmode = Well::ProducerCMode::BHP;
805 const bool converged = this->iterateWellEqWithSwitching(
806 simulator, dt, inj_controls, prod_controls, groupStateHelper_copy,
812 ws.injection_cmode = cmode_inj;
813 ws.production_cmode = cmode_prod;
817 template<
typename TypeTag>
828 const auto well_status_orig = this->wellStatus_;
831 auto inj_controls = Well::InjectionControls(0);
832 auto prod_controls = Well::ProductionControls(0);
837 const bool converged = this->iterateWellEqWithSwitching(
838 simulator, dt, inj_controls, prod_controls,
845 this->wellStatus_ = well_status_orig;
849 template<
typename TypeTag>
859 const double dt = simulator.timeStepSize();
861 const auto& summary_state = simulator.vanguard().summaryState();
862 auto inj_controls = this->well_ecl_.isInjector() ? this->well_ecl_.injectionControls(summary_state) : Well::InjectionControls(0);
863 auto prod_controls = this->well_ecl_.isProducer() ? this->well_ecl_.productionControls(summary_state) : Well::ProductionControls(0);
864 this->onlyKeepBHPandTHPcontrols(summary_state, well_state, inj_controls, prod_controls);
866 bool converged =
false;
869 if (!this->param_.local_well_solver_control_switching_){
870 converged = this->iterateWellEqWithControl(
871 simulator, dt, inj_controls, prod_controls, groupStateHelper, well_state
874 if (this->param_.use_implicit_ipr_ && this->well_ecl_.isProducer() && (well_state.
well(this->index_of_well_).status == WellStatus::OPEN)) {
875 converged = this->solveWellWithOperabilityCheck(
876 simulator, dt, inj_controls, prod_controls, groupStateHelper, well_state
879 converged = this->iterateWellEqWithSwitching(
880 simulator, dt, inj_controls, prod_controls, groupStateHelper, well_state,
888 }
catch (NumericalProblem& e ) {
889 const std::string msg =
"Inner well iterations failed for well " + this->name() +
" Treat the well as unconverged. ";
890 deferred_logger.warning(
"INNER_ITERATION_FAILED", msg);
895 deferred_logger.debug(
"WellTest: Well equation for well " + this->name() +
" converged");
898 const int max_iter = this->param_.max_welleq_iter_;
899 deferred_logger.debug(
"WellTest: Well equation for well " + this->name() +
" failed converging in "
905 template<
typename TypeTag>
914 if (!this->isOperableAndSolvable() && !this->wellIsStopped())
919 const double dt = simulator.timeStepSize();
920 bool converged = iterateWellEquations(simulator, dt, groupStateHelper, well_state);
930 auto& ws = well_state.
well(this->indexOfWell());
931 bool thp_control =
false;
932 if (this->well_ecl_.isInjector()) {
933 thp_control = ws.injection_cmode == Well::InjectorCMode::THP;
935 ws.injection_cmode = Well::InjectorCMode::BHP;
936 if (this->well_control_log_.empty()) {
937 this->well_control_log_.push_back(WellInjectorCMode2String(Well::InjectorCMode::THP));
941 thp_control = ws.production_cmode == Well::ProducerCMode::THP;
943 ws.production_cmode = Well::ProducerCMode::BHP;
944 if (this->well_control_log_.empty()) {
945 this->well_control_log_.push_back(WellProducerCMode2String(Well::ProducerCMode::THP));
950 const std::string msg = std::string(
"The newly opened well ") + this->name()
951 + std::string(
" with THP control did not converge during inner iterations, we try again with bhp control");
952 deferred_logger.debug(msg);
953 converged = this->iterateWellEquations(simulator, dt, groupStateHelper, well_state);
958 const int max_iter = this->param_.max_welleq_iter_;
959 deferred_logger.debug(
"Compute initial well solution for well " + this->name() +
". Failed to converge in "
961 well_state = well_state0;
967 template <
typename TypeTag>
976 prepareWellBeforeAssembling(simulator, dt, groupStateHelper, well_state);
977 assembleWellEqWithoutIteration(simulator, groupStateHelper, dt, well_state,
983 template <
typename TypeTag>
990 const bool solving_with_zero_rate)
993 const auto& summary_state = simulator.vanguard().summaryState();
994 const auto inj_controls = this->well_ecl_.isInjector() ? this->well_ecl_.injectionControls(summary_state) : Well::InjectionControls(0);
995 const auto prod_controls = this->well_ecl_.isProducer() ? this->well_ecl_.productionControls(summary_state) : Well::ProductionControls(0);
998 assembleWellEqWithoutIteration(simulator, groupStateHelper, dt, inj_controls, prod_controls, well_state, solving_with_zero_rate);
1003 template<
typename TypeTag>
1010 std::vector<Scalar> scaled_well_fractions(FluidSystem::numPhases, 0.0);
1011 this->getScaledWellFractions(scaled_well_fractions, deferred_logger);
1013 this->Base::updateGroupTargetFallbackFlag(well_state, scaled_well_fractions, deferred_logger);
1018 template<
typename TypeTag>
1028 const bool old_well_operable = this->operability_status_.isOperableAndSolvable();
1030 if (this->param_.check_well_operability_iter_)
1031 checkWellOperability(simulator, well_state, groupStateHelper);
1034 const auto& iterCtx = simulator.problem().iterationContext();
1035 if (iterCtx.shouldRunInnerWellIterations(this->param_.max_niter_inner_well_iter_)) {
1036 const auto& ws = well_state.
well(this->indexOfWell());
1037 const bool nonzero_rate_original =
1038 std::any_of(ws.surface_rates.begin(),
1039 ws.surface_rates.begin() + well_state.
numPhases(),
1040 [](
Scalar rate) { return rate != Scalar(0.0); });
1042 this->operability_status_.solvable =
true;
1043 if (number_of_well_reopenings_ >= this->param_.max_well_status_switch_) {
1045 if (number_of_well_reopenings_ == this->param_.max_well_status_switch_) {
1046 const std::string msg = fmt::format(
"well {} is oscillating between open and stop. \n"
1047 "We don't allow for more than {} re-openings "
1048 "and the well is therefore kept stopped.",
1049 this->name(), number_of_well_reopenings_);
1050 deferred_logger.debug(msg);
1051 changed_to_stopped_this_step_ = old_well_operable;
1053 changed_to_stopped_this_step_ =
false;
1056 bool converged_zero_rate = this->solveWellWithZeroRate(
1057 simulator, dt, groupStateHelper, well_state
1059 if (this->param_.shut_unsolvable_wells_ && !converged_zero_rate ) {
1060 this->operability_status_.solvable =
false;
1062 this->operability_status_.can_obtain_bhp_with_thp_limit =
false;
1063 this->operability_status_.obey_thp_limit_under_bhp_limit =
false;
1066 number_of_well_reopenings_++;
1069 bool converged = this->iterateWellEquations(
1070 simulator, dt, groupStateHelper, well_state
1074 const bool zero_target = this->wellUnderZeroRateTarget(groupStateHelper);
1075 if (this->wellIsStopped() && !zero_target && nonzero_rate_original) {
1079 this->operability_status_.resetOperability();
1081 deferred_logger.debug(
" " + this->name() +
" is re-opened after being stopped during local solve");
1082 number_of_well_reopenings_++;
1086 if (this->param_.shut_unsolvable_wells_) {
1087 this->operability_status_.solvable =
false;
1091 if (this->operability_status_.has_negative_potentials) {
1092 auto well_state_copy = well_state;
1093 std::vector<Scalar> potentials;
1095 computeWellPotentials(simulator, well_state_copy, groupStateHelper, potentials);
1096 }
catch (
const std::exception& e) {
1097 const std::string msg = fmt::format(
"well {}: computeWellPotentials() failed "
1098 "during attempt to recompute potentials for well: ",
1099 this->name(), e.what());
1100 deferred_logger.info(msg);
1101 this->operability_status_.has_negative_potentials =
true;
1103 auto& ws = well_state.
well(this->indexOfWell());
1105 for (
int p = 0; p < np; ++p) {
1106 ws.well_potentials[p] = std::max(
Scalar{0.0}, potentials[p]);
1109 this->changed_to_open_this_step_ =
false;
1110 changed_to_stopped_this_step_ =
false;
1112 const bool well_operable = this->operability_status_.isOperableAndSolvable();
1113 if (!well_operable) {
1116 this->solveWellWithZeroRate(
1117 simulator, dt, groupStateHelper, well_state
1119 }
catch (
const std::exception& e) {
1120 const std::string msg = fmt::format(
"well {}: solveWellWithZeroRate() failed "
1121 "during attempt to solve with zero rate for well: ",
1122 this->name(), e.what());
1123 deferred_logger.info(msg);
1125 auto& ws = well_state.
well(this->indexOfWell());
1127 for (
int p = 0; p < np; ++p) {
1128 ws.surface_rates[p] =
Scalar{0.0};
1131 if (old_well_operable) {
1132 const std::string ctx = iterCtx.inLocalSolve() ?
" (NLDD domain solve)" :
"";
1133 deferred_logger.debug(
" well " + this->name() +
" gets STOPPED during iteration" + ctx);
1134 changed_to_stopped_this_step_ =
true;
1136 }
else if (well_state.
isOpen(this->name())) {
1138 if (!old_well_operable) {
1139 const std::string ctx = iterCtx.inLocalSolve() ?
" (NLDD domain solve)" :
"";
1140 deferred_logger.debug(
" well " + this->name() +
" gets REVIVED during iteration" + ctx);
1141 this->changed_to_open_this_step_ =
true;
1146 template<
typename TypeTag>
1150 if(!this->operability_status_.solvable)
1153 for (
int perfIdx = 0; perfIdx < this->number_of_local_perforations_; ++perfIdx) {
1154 const auto cellIdx = this->cells()[perfIdx];
1155 const auto it = cellRates_.find(cellIdx);
1156 RateVector rates = (it == cellRates_.end()) ? 0.0 : it->second;
1157 for (
auto i=0*RateVector::dimension; i < RateVector::dimension; ++i)
1159 rates[i] += connectionRates_[perfIdx][i];
1161 cellRates_.insert_or_assign(cellIdx, rates);
1165 template<
typename TypeTag>
1169 for (
int perfIdx = 0; perfIdx < this->number_of_local_perforations_; ++perfIdx) {
1170 if (this->cells()[perfIdx] == cellIdx) {
1171 const unsigned activeCompIdx = FluidSystem::canonicalToActiveCompIdx(FluidSystem::solventComponentIndex(phaseIdx));
1172 return connectionRates_[perfIdx][activeCompIdx].value();
1176 OPM_THROW(std::invalid_argument,
"The well with name " + this->name()
1184 template<
typename TypeTag>
1193 if (!this->param_.check_well_operability_) {
1197 if (this->wellIsStopped() && !changed_to_stopped_this_step_) {
1201 updateWellOperability(simulator, well_state, groupStateHelper);
1202 if (!this->operability_status_.isOperableAndSolvable()) {
1203 this->operability_status_.use_vfpexplicit =
true;
1204 deferred_logger.debug(
"EXPLICIT_LOOKUP_VFP",
1205 "well not operable, trying with explicit vfp lookup: " + this->name());
1206 updateWellOperability(simulator, well_state, groupStateHelper);
1212 template<
typename TypeTag>
1222 const auto& summary_state = simulator.vanguard().summaryState();
1223 const auto& well_name = this->name();
1224 if (!this->wellHasTHPConstraints(summary_state)) {
1225 const std::string msg = fmt::format(
"GLIFT WTEST: Well {} does not have THP constraints", well_name);
1226 deferred_logger.
info(msg);
1229 const auto& schedule = simulator.vanguard().schedule();
1230 const auto report_step_idx = simulator.episodeIndex();
1231 const auto& glo = schedule.glo(report_step_idx);
1232 if (!glo.has_well(well_name)) {
1233 const std::string msg = fmt::format(
1234 "GLIFT WTEST: Well {} : Gas lift not activated: "
1235 "WLIFTOPT is probably missing. Skipping.", well_name);
1236 deferred_logger.
info(msg);
1239 const auto& gl_well = glo.well(well_name);
1242 std::unique_ptr<GasLiftSingleWell> glift =
1243 initializeGliftWellTest_<GasLiftSingleWell>(simulator,
1248 auto [wtest_alq, success] = glift->wellTestALQ();
1250 const auto& unit_system = schedule.getUnits();
1252 well_state.
well(well_name).alq_state.set(wtest_alq);
1254 "GLIFT WTEST: Well {} : Setting ALQ to optimized value = {}",
1255 well_name, unit_system.from_si(UnitSystem::measure::gas_surface_rate, wtest_alq));
1258 if (!gl_well.use_glo()) {
1260 "GLIFT WTEST: Well {} : Gas lift optimization deactivated. Setting ALQ to WLIFTOPT item 3 = {}",
1262 unit_system.from_si(UnitSystem::measure::gas_surface_rate, well_state.
well(well_name).alq_state.get()));
1267 "GLIFT WTEST: Well {} : Gas lift optimization failed, no ALQ set.",
1271 deferred_logger.
info(msg);
1274 template<
typename TypeTag>
1283 if (this->param_.local_well_solver_control_switching_) {
1284 const bool success = updateWellOperabilityFromWellEq(simulator, groupStateHelper);
1286 this->operability_status_.solvable =
false;
1287 deferred_logger.debug(
"Operability check using well equations did not converge for well "
1288 + this->name() +
". Mark the well as unsolvable." );
1292 this->operability_status_.resetOperability();
1294 bool thp_controlled = this->isInjector() ? well_state.
well(this->index_of_well_).injection_cmode == Well::InjectorCMode::THP:
1295 well_state.
well(this->index_of_well_).production_cmode == Well::ProducerCMode::THP;
1296 bool bhp_controlled = this->isInjector() ? well_state.
well(this->index_of_well_).injection_cmode == Well::InjectorCMode::BHP:
1297 well_state.
well(this->index_of_well_).production_cmode == Well::ProducerCMode::BHP;
1301 bool check_thp = thp_controlled || this->operability_status_.thp_limit_violated_but_not_switched;
1302 if (check_thp || bhp_controlled) {
1303 updateIPR(simulator, deferred_logger);
1304 checkOperabilityUnderBHPLimit(well_state, simulator, deferred_logger);
1308 checkOperabilityUnderTHPLimit(simulator, well_state, groupStateHelper);
1312 template<
typename TypeTag>
1320 assert(this->param_.local_well_solver_control_switching_);
1321 this->operability_status_.resetOperability();
1324 const double dt = simulator.timeStepSize();
1328 auto guard = groupStateHelper_copy.
pushWellState(well_state_copy);
1330 bool converged = iterateWellEquations(simulator, dt, groupStateHelper_copy, well_state_copy);
1334 template<
typename TypeTag>
1342 template<
typename TypeTag>
1352 const auto& well = this->well_ecl_;
1353 const int well_index = this->index_of_well_;
1354 auto& ws = well_state.
well(well_index);
1356 const auto& summaryState = simulator.vanguard().summaryState();
1357 const auto& schedule = simulator.vanguard().schedule();
1361 ws.primaryvar.resize(0);
1363 if (this->wellIsStopped()) {
1364 for (
int p = 0; p<np; ++p) {
1365 ws.surface_rates[p] = 0;
1371 if (this->isInjector() )
1373 const auto& controls = well.injectionControls(summaryState);
1375 InjectorType injectorType = controls.injector_type;
1377 switch (injectorType) {
1378 case InjectorType::WATER:
1380 phasePos = FluidSystem::canonicalToActivePhaseIdx(FluidSystem::waterPhaseIdx);
1383 case InjectorType::OIL:
1385 phasePos = FluidSystem::canonicalToActivePhaseIdx(FluidSystem::oilPhaseIdx);
1388 case InjectorType::GAS:
1390 phasePos = FluidSystem::canonicalToActivePhaseIdx(FluidSystem::gasPhaseIdx);
1394 OPM_DEFLOG_THROW(std::runtime_error,
"Expected WATER, OIL or GAS as type for injectors " + this->name(), deferred_logger );
1397 const auto current = ws.injection_cmode;
1400 case Well::InjectorCMode::RATE:
1402 ws.surface_rates[phasePos] = (1.0 - this->rsRvInj()) * controls.surface_rate;
1403 if(this->rsRvInj() > 0) {
1404 if (injectorType == InjectorType::OIL && FluidSystem::phaseIsActive(FluidSystem::gasPhaseIdx)) {
1405 const int gas_pos = FluidSystem::canonicalToActivePhaseIdx(FluidSystem::gasPhaseIdx);
1406 ws.surface_rates[gas_pos] = controls.surface_rate * this->rsRvInj();
1407 }
else if (injectorType == InjectorType::GAS && FluidSystem::phaseIsActive(FluidSystem::oilPhaseIdx)) {
1408 const int oil_pos = FluidSystem::canonicalToActivePhaseIdx(FluidSystem::oilPhaseIdx);
1409 ws.surface_rates[oil_pos] = controls.surface_rate * this->rsRvInj();
1411 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 );
1417 case Well::InjectorCMode::RESV:
1419 std::vector<Scalar> convert_coeff(this->number_of_phases_, 1.0);
1420 this->rateConverter_.calcCoeff( 0, this->pvtRegionIdx_, convert_coeff);
1421 const Scalar coeff = convert_coeff[phasePos];
1422 ws.surface_rates[phasePos] = controls.reservoir_rate/coeff;
1426 case Well::InjectorCMode::THP:
1428 auto rates = ws.surface_rates;
1433 this->getRefDensity(),
1436 ws.thp = this->getTHPConstraint(summaryState);
1441 Scalar total_rate = std::accumulate(rates.begin(), rates.end(), 0.0);
1442 if (total_rate <= 0.0)
1443 ws.surface_rates = ws.well_potentials;
1447 case Well::InjectorCMode::BHP:
1449 ws.bhp = controls.bhp_limit;
1451 for (
int p = 0; p<np; ++p) {
1452 total_rate += ws.surface_rates[p];
1457 if (total_rate <= 0.0)
1458 ws.surface_rates = ws.well_potentials;
1462 case Well::InjectorCMode::GRUP:
1464 assert(well.isAvailableForGroupControl());
1465 const auto& group = schedule.getGroup(well.groupName(), this->currentStep());
1466 const Scalar efficiencyFactor = well.getEfficiencyFactor() *
1467 well_state[well.name()].efficiency_scaling_factor;
1468 std::optional<Scalar> target =
1469 this->getGroupInjectionTargetRate(group,
1474 ws.surface_rates[phasePos] = *target;
1477 case Well::InjectorCMode::CMODE_UNDEFINED:
1479 OPM_DEFLOG_THROW(std::runtime_error,
"Well control must be specified for well " + this->name(), deferred_logger );
1489 ws.surface_rates[phasePos] = std::max(
Scalar{1.e-7}, ws.surface_rates[phasePos]);
1492 ws.bhp = controls.bhp_limit;
1498 const auto current = ws.production_cmode;
1499 const auto& controls = well.productionControls(summaryState);
1501 case Well::ProducerCMode::ORAT:
1503 const int oil_pos = FluidSystem::canonicalToActivePhaseIdx(FluidSystem::oilPhaseIdx);
1504 Scalar current_rate = -ws.surface_rates[oil_pos];
1507 if (current_rate > 0.0) {
1508 for (
int p = 0; p<np; ++p) {
1509 ws.surface_rates[p] *= controls.oil_rate/current_rate;
1512 const std::vector<Scalar> fractions = initialWellRateFractions(simulator, well_state);
1513 double control_fraction = fractions[oil_pos];
1514 if (control_fraction != 0.0) {
1515 for (
int p = 0; p<np; ++p) {
1516 ws.surface_rates[p] = - fractions[p] * controls.oil_rate/control_fraction;
1522 case Well::ProducerCMode::WRAT:
1524 const int water_pos = FluidSystem::canonicalToActivePhaseIdx(FluidSystem::waterPhaseIdx);
1525 Scalar current_rate = -ws.surface_rates[water_pos];
1528 if (current_rate > 0.0) {
1529 for (
int p = 0; p<np; ++p) {
1530 ws.surface_rates[p] *= controls.water_rate/current_rate;
1533 const std::vector<Scalar> fractions = initialWellRateFractions(simulator, well_state);
1534 const Scalar control_fraction = fractions[water_pos];
1535 if (control_fraction != 0.0) {
1536 for (
int p = 0; p<np; ++p) {
1537 ws.surface_rates[p] = - fractions[p] * controls.water_rate / control_fraction;
1543 case Well::ProducerCMode::GRAT:
1545 const int gas_pos = FluidSystem::canonicalToActivePhaseIdx(FluidSystem::gasPhaseIdx);
1546 Scalar current_rate = -ws.surface_rates[gas_pos];
1549 if (current_rate > 0.0) {
1550 for (
int p = 0; p<np; ++p) {
1551 ws.surface_rates[p] *= controls.gas_rate/current_rate;
1554 const std::vector<Scalar > fractions = initialWellRateFractions(simulator, well_state);
1555 const Scalar control_fraction = fractions[gas_pos];
1556 if (control_fraction != 0.0) {
1557 for (
int p = 0; p<np; ++p) {
1558 ws.surface_rates[p] = - fractions[p] * controls.gas_rate / control_fraction;
1566 case Well::ProducerCMode::LRAT:
1568 const int water_pos = FluidSystem::canonicalToActivePhaseIdx(FluidSystem::waterPhaseIdx);
1569 const int oil_pos = FluidSystem::canonicalToActivePhaseIdx(FluidSystem::oilPhaseIdx);
1570 Scalar current_rate = - ws.surface_rates[water_pos]
1571 - ws.surface_rates[oil_pos];
1574 if (current_rate > 0.0) {
1575 for (
int p = 0; p<np; ++p) {
1576 ws.surface_rates[p] *= controls.liquid_rate/current_rate;
1579 const std::vector<Scalar> fractions = initialWellRateFractions(simulator, well_state);
1580 const Scalar control_fraction = fractions[water_pos] + fractions[oil_pos];
1581 if (control_fraction != 0.0) {
1582 for (
int p = 0; p<np; ++p) {
1583 ws.surface_rates[p] = - fractions[p] * controls.liquid_rate / control_fraction;
1589 case Well::ProducerCMode::CRAT:
1592 fmt::format(
"CRAT control not supported, well {}", this->name()),
1595 case Well::ProducerCMode::RESV:
1597 std::vector<Scalar> convert_coeff(this->number_of_phases_, 1.0);
1598 this->rateConverter_.calcCoeff( 0, this->pvtRegionIdx_, ws.surface_rates, convert_coeff);
1599 Scalar total_res_rate = 0.0;
1600 for (
int p = 0; p<np; ++p) {
1601 total_res_rate -= ws.surface_rates[p] * convert_coeff[p];
1603 if (controls.prediction_mode) {
1606 if (total_res_rate > 0.0) {
1607 for (
int p = 0; p<np; ++p) {
1608 ws.surface_rates[p] *= controls.resv_rate/total_res_rate;
1611 const std::vector<Scalar> fractions = initialWellRateFractions(simulator, well_state);
1612 for (
int p = 0; p<np; ++p) {
1613 ws.surface_rates[p] = - fractions[p] * controls.resv_rate / convert_coeff[p];
1617 std::vector<Scalar> hrates(this->number_of_phases_,0.);
1618 if (FluidSystem::phaseIsActive(FluidSystem::waterPhaseIdx)) {
1619 const int phase_pos = FluidSystem::canonicalToActivePhaseIdx(FluidSystem::waterPhaseIdx);
1620 hrates[phase_pos] = controls.water_rate;
1622 if (FluidSystem::phaseIsActive(FluidSystem::oilPhaseIdx)) {
1623 const int phase_pos = FluidSystem::canonicalToActivePhaseIdx(FluidSystem::oilPhaseIdx);
1624 hrates[phase_pos] = controls.oil_rate;
1626 if (FluidSystem::phaseIsActive(FluidSystem::gasPhaseIdx)) {
1627 const int phase_pos = FluidSystem::canonicalToActivePhaseIdx(FluidSystem::gasPhaseIdx);
1628 hrates[phase_pos] = controls.gas_rate;
1630 std::vector<Scalar> hrates_resv(this->number_of_phases_,0.);
1631 this->rateConverter_.calcReservoirVoidageRates( 0, this->pvtRegionIdx_, hrates, hrates_resv);
1632 Scalar target = std::accumulate(hrates_resv.begin(), hrates_resv.end(), 0.0);
1635 if (total_res_rate > 0.0) {
1636 for (
int p = 0; p<np; ++p) {
1637 ws.surface_rates[p] *= target/total_res_rate;
1640 const std::vector<Scalar> fractions = initialWellRateFractions(simulator, well_state);
1641 for (
int p = 0; p<np; ++p) {
1642 ws.surface_rates[p] = - fractions[p] * target / convert_coeff[p];
1648 case Well::ProducerCMode::BHP:
1650 ws.bhp = controls.bhp_limit;
1652 for (
int p = 0; p<np; ++p) {
1653 total_rate -= ws.surface_rates[p];
1658 if (total_rate <= 0.0){
1659 for (
int p = 0; p<np; ++p) {
1660 ws.surface_rates[p] = -ws.well_potentials[p];
1665 case Well::ProducerCMode::THP:
1667 const bool update_success = updateWellStateWithTHPTargetProd(simulator, well_state, groupStateHelper);
1669 if (!update_success) {
1673 auto rates = ws.surface_rates;
1674 this->adaptRatesForVFP(rates);
1676 well_state, rates, well, summaryState, this->getRefDensity(), deferred_logger);
1678 ws.thp = this->getTHPConstraint(summaryState);
1682 const Scalar total_rate = -std::accumulate(rates.begin(), rates.end(), 0.0);
1683 if (total_rate <= 0.0) {
1684 for (
int p = 0; p < this->number_of_phases_; ++p) {
1685 ws.surface_rates[p] = -ws.well_potentials[p];
1691 case Well::ProducerCMode::GRUP:
1693 assert(well.isAvailableForGroupControl());
1694 this->updateGroupTargetFallbackFlag(well_state, deferred_logger);
1695 const auto& group = schedule.getGroup(well.groupName(), this->currentStep());
1696 const Scalar efficiencyFactor = well.getEfficiencyFactor() *
1697 well_state[well.name()].efficiency_scaling_factor;
1698 Scalar scale = this->getGroupProductionTargetRate(group,
1704 for (
int p = 0; p<np; ++p) {
1705 ws.surface_rates[p] *= scale;
1707 ws.trivial_group_target =
false;
1711 ws.trivial_group_target =
true;
1715 case Well::ProducerCMode::CMODE_UNDEFINED:
1718 OPM_DEFLOG_THROW(std::runtime_error,
"Well control must be specified for well " + this->name() , deferred_logger);
1724 ws.bhp = controls.bhp_limit;
1729 template<
typename TypeTag>
1735 const auto& well_state = groupStateHelper.
wellState();
1737 const bool isGroupControlled = this->wellUnderGroupControl(well_state.well(this->index_of_well_));
1738 if (!isGroupControlled) {
1740 const auto& summaryState = groupStateHelper.
summaryState();
1741 return this->wellUnderZeroRateTargetIndividual(summaryState, well_state);
1743 return this->wellUnderZeroGroupRateTarget(groupStateHelper, isGroupControlled);
1747 template <
typename TypeTag>
1750 const std::optional<bool> group_control)
const
1752 const auto& well_state = groupStateHelper.
wellState();
1754 const bool isGroupControlled = group_control.value_or(this->wellUnderGroupControl(well_state.well(this->index_of_well_)));
1755 if (isGroupControlled) {
1756 return this->zeroGroupRateTarget(groupStateHelper);
1761 template<
typename TypeTag>
1768 return this->wellIsStopped()
1769 || this->wellUnderZeroRateTarget(groupStateHelper);
1772 template<
typename TypeTag>
1773 std::vector<typename WellInterface<TypeTag>::Scalar>
1779 const int np = this->number_of_phases_;
1780 std::vector<Scalar> scaling_factor(np);
1781 const auto& ws = well_state.
well(this->index_of_well_);
1783 Scalar total_potentials = 0.0;
1784 for (
int p = 0; p<np; ++p) {
1785 total_potentials += ws.well_potentials[p];
1787 if (total_potentials > 0) {
1788 for (
int p = 0; p<np; ++p) {
1789 scaling_factor[p] = ws.well_potentials[p] / total_potentials;
1791 return scaling_factor;
1796 const int nperf = this->number_of_local_perforations_;
1797 for (
int perf = 0; perf < nperf; ++perf) {
1798 total_tw += this->well_index_[perf];
1800 total_tw = this->parallelWellInfo().communication().sum(total_tw);
1802 for (
int perf = 0; perf < nperf; ++perf) {
1803 const int cell_idx = this->well_cells_[perf];
1804 const auto& intQuants = simulator.model().intensiveQuantities(cell_idx, 0);
1805 const auto& fs = intQuants.fluidState();
1806 const Scalar well_tw_fraction = this->well_index_[perf] / total_tw;
1807 Scalar total_mobility = 0.0;
1808 for (
int p = 0; p < np; ++p) {
1809 const int canonical_phase_idx = FluidSystem::activeToCanonicalPhaseIdx(p);
1810 total_mobility += fs.invB(canonical_phase_idx).value() * intQuants.mobility(canonical_phase_idx).value();
1812 for (
int p = 0; p < np; ++p) {
1813 const int canonical_phase_idx = FluidSystem::activeToCanonicalPhaseIdx(p);
1814 scaling_factor[p] += well_tw_fraction * fs.invB(canonical_phase_idx).value() * intQuants.mobility(canonical_phase_idx).value() / total_mobility;
1817 return scaling_factor;
1822 template <
typename TypeTag>
1829 assert(this->isProducer());
1833 auto& ws = well_state.
well(this->index_of_well_);
1834 int nonzero_rate_index = -1;
1835 const Scalar floating_point_error_epsilon = 1e-14;
1836 for (
int p = 0; p < this->number_of_phases_; ++p) {
1837 if (std::abs(ws.surface_rates[p]) > floating_point_error_epsilon) {
1838 if (nonzero_rate_index == -1) {
1839 nonzero_rate_index = p;
1848 std::vector<Scalar> well_q_s(this->number_of_phases_, 0.0);
1849 bool rates_evaluated_at_1bar =
false;
1851 const auto& summary_state = simulator.vanguard().summaryState();
1852 const auto& prod_controls = this->well_ecl_.productionControls(summary_state);
1853 const double bhp_limit = std::max(prod_controls.bhp_limit, 1.0 * unit::barsa);
1854 this->computeWellRatesWithBhp(simulator, bhp_limit, well_q_s, deferred_logger);
1856 rates_evaluated_at_1bar = (bhp_limit < 1.1 * unit::barsa);
1858 if (std::ranges::any_of(well_q_s, [](
Scalar q) {
return q > 0.0; })) {
1860 if (!rates_evaluated_at_1bar) {
1861 this->computeWellRatesWithBhp(simulator, 1.0 * unit::barsa, well_q_s, deferred_logger);
1862 rates_evaluated_at_1bar =
true;
1865 for (
auto& q : well_q_s) {
1866 q = std::min(q,
Scalar{0.0});
1871 if (nonzero_rate_index == -1) {
1875 const Scalar factor = rates_evaluated_at_1bar ? 0.5 : 1.0;
1876 for (
int p = 0; p < this->number_of_phases_; ++p) {
1877 ws.surface_rates[p] = factor * well_q_s[p];
1886 const Scalar initial_nonzero_rate = ws.surface_rates[nonzero_rate_index];
1887 const Scalar computed_rate = well_q_s[nonzero_rate_index];
1888 if (std::abs(initial_nonzero_rate) < std::abs(computed_rate)) {
1890 const Scalar factor = initial_nonzero_rate / computed_rate;
1891 assert(factor < 1.0);
1892 for (
int p = 0; p < this->number_of_phases_; ++p) {
1894 if (p != nonzero_rate_index) {
1895 ws.surface_rates[p] = factor * well_q_s[p];
1904 for (
int p = 0; p < this->number_of_phases_; ++p) {
1905 ws.surface_rates[p] = well_q_s[p];
1909 template <
typename TypeTag>
1910 template<
class Value>
1913 getTw(std::vector<Value>& Tw,
1916 const Value& trans_mult,
1919 OPM_TIMEFUNCTION_LOCAL(Subsystem::Wells);
1922 if (
static_cast<std::size_t
>(perf) >= this->well_cells_.size()) {
1923 OPM_THROW(std::invalid_argument,
"The perforation index exceeds the size of the local containers - possibly wellIndex was called with a global instead of a local perforation index!");
1926 if constexpr (! Indices::gasEnabled) {
1930 const auto& wdfac = this->well_ecl_.getWDFAC();
1932 if (! wdfac.useDFactor() || (this->well_index_[perf] == 0.0)) {
1936 const Scalar d = this->computeConnectionDFactor(perf, intQuants, ws);
1943 const auto& connection = this->well_ecl_.getConnections()[ws.
perf_data.ecl_index[perf]];
1944 const Scalar Kh = connection.Kh();
1945 const Scalar scaling = std::numbers::pi * Kh * connection.wpimult();
1946 const unsigned gas_comp_idx = FluidSystem::canonicalToActiveCompIdx(FluidSystem::gasCompIdx);
1949 const Scalar cell_pressure = getValue(intQuants.fluidState().pressure(FluidSystem::gasPhaseIdx));
1950 const Scalar drawdown = cell_pressure - connection_pressure;
1951 const Scalar invB = getValue(intQuants.fluidState().invB(FluidSystem::gasPhaseIdx));
1952 const Scalar mob_g = getValue(intQuants.mobility(FluidSystem::gasPhaseIdx)) * invB;
1954 const Scalar b = 2 * scaling / getValue(Tw[gas_comp_idx]);
1955 const Scalar c = -2 * scaling * mob_g * drawdown;
1957 Scalar consistent_Q = -1.0e20;
1959 const Scalar r2n = b*b + 4*a*c;
1961 const Scalar rn = std::sqrt(r2n);
1962 const Scalar xn1 = (b-rn)*0.5/a;
1966 const Scalar xn2 = (b+rn)*0.5/a;
1967 if (xn2 <= 0 && xn2 > consistent_Q) {
1973 const Scalar r2p = b*b - 4*a*c;
1975 const Scalar rp = std::sqrt(r2p);
1976 const Scalar xp1 = (rp-b)*0.5/a;
1977 if (xp1 > 0 && xp1 < consistent_Q) {
1980 const Scalar xp2 = -(rp+b)*0.5/a;
1981 if (xp2 > 0 && xp2 < consistent_Q) {
1985 Tw[gas_comp_idx] = 1.0 / (1.0 / (trans_mult * this->well_index_[perf]) + (consistent_Q/2 * d / scaling));
1988 template <
typename TypeTag>
1994 if (! this->well_ecl_.getWDFAC().useDFactor()) {
1998 auto& d_factor = ws.
perf_data.connection_d_factor;
2000 for (
int perf = 0; perf < this->number_of_local_perforations_; ++perf) {
2001 const int cell_idx = this->well_cells_[perf];
2002 const auto& intQuants = simulator.model().intensiveQuantities(cell_idx, 0);
2004 d_factor[perf] = this->computeConnectionDFactor(perf, intQuants, ws);
2008 template <
typename TypeTag>
2015 auto rhoGS = [regIdx = this->pvtRegionIdx()]() {
2016 return FluidSystem::referenceDensity(FluidSystem::gasPhaseIdx, regIdx);
2020 auto gas_visc = [connection_pressure = ws.
perf_data.pressure[perf],
2022 regIdx = this->pvtRegionIdx(), &intQuants]()
2024 const auto rv = getValue(intQuants.fluidState().Rv());
2026 const auto& gasPvt = FluidSystem::gasPvt();
2031 const Scalar rv_sat = gasPvt.saturatedOilVaporizationFactor
2032 (regIdx, temperature, connection_pressure);
2034 if (! (rv < rv_sat)) {
2035 return gasPvt.saturatedViscosity(regIdx, temperature,
2036 connection_pressure);
2039 return gasPvt.viscosity(regIdx, temperature, connection_pressure,
2040 rv, getValue(intQuants.fluidState().Rvw()));
2043 const auto& connection = this->well_ecl_.getConnections()
2046 return this->well_ecl_.getWDFAC().getDFactor(rhoGS, gas_visc, connection);
2050 template <
typename TypeTag>
2056 auto connCF = [&connIx = std::as_const(ws.
perf_data.ecl_index),
2057 &conns = this->well_ecl_.getConnections()]
2060 return conns[connIx[perf]].CF();
2063 auto obtain = [](
const Eval& value)
2065 return getValue(value);
2068 auto& tmult = ws.
perf_data.connection_compaction_tmult;
2069 auto& ctf = ws.
perf_data.connection_transmissibility_factor;
2071 for (
int perf = 0; perf < this->number_of_local_perforations_; ++perf) {
2072 const int cell_idx = this->well_cells_[perf];
2074 getTransMult(trans_mult, simulator, cell_idx, obtain);
2075 tmult[perf] = trans_mult;
2077 ctf[perf] = connCF(perf) * tmult[perf];
2082 template<
typename TypeTag>
2086 if constexpr (Indices::oilEnabled) {
2087 return fs.pressure(FluidSystem::oilPhaseIdx);
2088 }
else if constexpr (Indices::gasEnabled) {
2089 return fs.pressure(FluidSystem::gasPhaseIdx);
2091 return fs.pressure(FluidSystem::waterPhaseIdx);
2095 template <
typename TypeTag>
2096 template<
class Value,
class Callback>
2102 Callback& extendEval)
const
2104 const auto& intQuants = simulator.model().intensiveQuantities(cell_idx, 0);
2105 trans_mult = simulator.problem().template wellTransMultiplier<Value>(intQuants, cell_idx, extendEval);
2108 template <
typename TypeTag>
2109 template<
class Value,
class Callback>
2113 const int local_perf_index,
2114 std::vector<Value>& mob,
2115 Callback& extendEval,
2118 auto relpermArray = []()
2120 if constexpr (std::is_same_v<Value, Scalar>) {
2121 return std::array<Scalar,3>{};
2123 return std::array<Eval,3>{};
2126 if (
static_cast<std::size_t
>(local_perf_index) >= this->well_cells_.size()) {
2127 OPM_THROW(std::invalid_argument,
"The perforation index exceeds the size of the local containers - possibly getMobility was called with a global instead of a local perforation index!");
2129 const int cell_idx = this->well_cells_[local_perf_index];
2130 assert (
int(mob.size()) == this->num_conservation_quantities_);
2131 const auto& intQuants = simulator.model().intensiveQuantities(cell_idx, 0);
2132 const auto& materialLawManager = simulator.problem().materialLawManager();
2136 const int satid = this->saturation_table_number_[local_perf_index] - 1;
2137 const int satid_elem = materialLawManager->satnumRegionIdx(cell_idx);
2138 if (satid == satid_elem) {
2139 for (
unsigned phaseIdx = 0; phaseIdx < FluidSystem::numPhases; ++phaseIdx) {
2140 if (!FluidSystem::phaseIsActive(phaseIdx)) {
2144 const unsigned activeCompIdx = FluidSystem::canonicalToActiveCompIdx(FluidSystem::solventComponentIndex(phaseIdx));
2145 mob[activeCompIdx] = extendEval(intQuants.mobility(phaseIdx));
2147 if constexpr (has_solvent) {
2148 mob[Indices::contiSolventEqIdx] = extendEval(intQuants.solventMobility());
2151 const auto& paramsCell = materialLawManager->connectionMaterialLawParams(satid, cell_idx);
2152 auto relativePerms = relpermArray();
2153 MaterialLaw::relativePermeabilities(relativePerms, paramsCell, intQuants.fluidState());
2156 materialLawManager->connectionMaterialLawParams(satid_elem, cell_idx);
2159 for (
unsigned phaseIdx = 0; phaseIdx < FluidSystem::numPhases; ++phaseIdx) {
2160 if (!FluidSystem::phaseIsActive(phaseIdx)) {
2164 const unsigned activeCompIdx = FluidSystem::canonicalToActiveCompIdx(FluidSystem::solventComponentIndex(phaseIdx));
2165 mob[activeCompIdx] = extendEval(relativePerms[phaseIdx] / intQuants.fluidState().viscosity(phaseIdx));
2168 if constexpr (has_solvent) {
2169 const auto Fsolgas = intQuants.solventSaturation() / (intQuants.solventSaturation() + intQuants.fluidState().saturation(FluidSystem::gasPhaseIdx));
2171 if (Fsolgas > SolventModule::cutOff) {
2172 const unsigned activeGasCompIdx = FluidSystem::canonicalToActiveCompIdx(FluidSystem::solventComponentIndex(FluidSystem::gasPhaseIdx));
2173 const auto& ssfnKrg = SolventModule::ssfnKrg(satid);
2174 const auto& ssfnKrs = SolventModule::ssfnKrs(satid);
2175 mob[activeGasCompIdx] *= extendEval(ssfnKrg.eval(1-Fsolgas,
true));
2176 mob[Indices::contiSolventEqIdx] = extendEval(ssfnKrs.eval(Fsolgas,
true) * relativePerms[activeGasCompIdx] / intQuants.solventViscosity());
2181 if (this->isInjector() && !this->inj_fc_multiplier_.empty()) {
2182 const auto perf_ecl_index = this->perforationData()[local_perf_index].ecl_index;
2183 const auto& connections = this->well_ecl_.getConnections();
2184 const auto& connection = connections[perf_ecl_index];
2185 if (connection.filterCakeActive()) {
2186 std::ranges::transform(mob, mob.begin(),
2187 [mult = this->inj_fc_multiplier_[local_perf_index]]
2189 { return val * mult; });
2195 template<
typename TypeTag>
2204 const auto& summary_state = simulator.vanguard().summaryState();
2206 auto bhp_at_thp_limit = computeBhpAtThpLimitProdWithAlq(
2207 simulator, groupStateHelper, summary_state, this->getALQ(well_state),
false);
2208 if (bhp_at_thp_limit) {
2209 std::vector<Scalar> rates(this->number_of_phases_, 0.0);
2210 if (thp_update_iterations) {
2211 computeWellRatesWithBhpIterations(simulator, *bhp_at_thp_limit,
2212 groupStateHelper, rates);
2214 computeWellRatesWithBhp(simulator, *bhp_at_thp_limit,
2215 rates, deferred_logger);
2217 auto& ws = well_state.
well(this->name());
2218 ws.surface_rates = rates;
2219 ws.bhp = *bhp_at_thp_limit;
2220 ws.thp = this->getTHPConstraint(summary_state);
2227 template<
typename TypeTag>
2228 std::optional<typename WellInterface<TypeTag>::Scalar>
2233 const SummaryState& summary_state,
2238 const auto& groupStateHelper = simulator.problem().wellModel().groupStateHelper();
2240 auto well_guard = groupStateHelper_copy.
pushWellState(well_state_copy);
2241 const double dt = simulator.timeStepSize();
2242 const bool converged = this->solveWellWithBhp(
2243 simulator, dt, bhp, groupStateHelper_copy, well_state_copy
2247 auto rates = well_state_copy.
well(this->index_of_well_).surface_rates;
2249 for (std::size_t p = 0; p < rates.size(); ++p) {
2250 zero_rates &= rates[p] == 0.0;
2254 if (zero_rates || !converged) {
2255 return this->computeBhpAtThpLimitProdWithAlq(simulator, groupStateHelper_copy, summary_state, alq_value,
false);
2257 this->updateIPRImplicit(simulator, groupStateHelper_copy, well_state_copy);
2258 this->adaptRatesForVFP(rates);
2262 template <
typename TypeTag>
2267 const std::vector<Scalar>& mobility,
2270 const int np = this->number_of_phases_;
2271 for (
int p = 0; p < np; ++p) {
2274 const int canonical_phase_idx = FluidSystem::activeToCanonicalPhaseIdx(p);
2275 const auto connMob =
2276 mobility[FluidSystem::activePhaseToActiveCompIdx(p)] * fs.invB(canonical_phase_idx).value();
2278 connPI[p] = connPICalc(connMob);
2281 if (FluidSystem::phaseIsActive(FluidSystem::oilPhaseIdx) &&
2282 FluidSystem::phaseIsActive(FluidSystem::gasPhaseIdx))
2284 const auto io = FluidSystem::canonicalToActivePhaseIdx(FluidSystem::oilPhaseIdx);
2285 const auto ig = FluidSystem::canonicalToActivePhaseIdx(FluidSystem::gasPhaseIdx);
2287 const auto vapoil = connPI[ig] * fs.Rv().value();
2288 const auto disgas = connPI[io] * fs.Rs().value();
2290 connPI[io] += vapoil;
2291 connPI[ig] += disgas;
2296 template <
typename TypeTag>
2300 const Phase preferred_phase,
2302 const std::vector<Scalar>& mobility,
2307 if (preferred_phase == Phase::GAS) {
2308 phase_pos = FluidSystem::canonicalToActivePhaseIdx(FluidSystem::gasPhaseIdx);
2310 else if (preferred_phase == Phase::OIL) {
2311 phase_pos = FluidSystem::canonicalToActivePhaseIdx(FluidSystem::oilPhaseIdx);
2313 else if (preferred_phase == Phase::WATER) {
2314 phase_pos = FluidSystem::canonicalToActivePhaseIdx(FluidSystem::waterPhaseIdx);
2318 fmt::format(
"Unsupported Injector Type ({}) "
2319 "for well {} during connection I.I. calculation",
2320 static_cast<int>(preferred_phase), this->name()),
2324 const auto mt = std::accumulate(mobility.begin(), mobility.end(), 0.0);
2325 const int canonicalPhaseIdx = FluidSystem::activeToCanonicalPhaseIdx(phase_pos);
2326 connII[phase_pos] = connIICalc(mt * fs.invB(canonicalPhaseIdx).value());
2329 template<
typename TypeTag>
2330 template<
class GasLiftSingleWell>
2331 std::unique_ptr<GasLiftSingleWell>
2340 auto& comm = simulator.vanguard().grid().comm();
2341 ecl_well_map.try_emplace(this->name(), &(this->wellEcl()), this->indexOfWell());
2342 const auto& iterCtx = simulator.problem().iterationContext();
2345 simulator.vanguard().schedule(),
2346 simulator.vanguard().summaryState(),
2347 simulator.episodeIndex(),
2357 std::set<int> sync_groups;
2358 const auto& summary_state = simulator.vanguard().summaryState();
2359 return std::make_unique<GasLiftSingleWell>(*
this,
#define OPM_DEFLOG_THROW(Exception, message, deferred_logger)
Definition: DeferredLoggingErrorHelpers.hpp:45
Contains the high level supplements required to extend the black oil model by solvents.
Definition: blackoilsolventmodules.hh:69
Definition: DeferredLogger.hpp:57
void info(const std::string &tag, const std::string &message)
Definition: GasLiftGroupInfo.hpp:47
Definition: GroupStateHelper.hpp:56
GroupState< Scalar > & groupState() const
Definition: GroupStateHelper.hpp:301
const SummaryState & summaryState() const
Definition: GroupStateHelper.hpp:429
const WellState< Scalar, IndexTraits > & wellState() const
Definition: GroupStateHelper.hpp:510
DeferredLogger & deferredLogger() const
Get the deferred logger.
Definition: GroupStateHelper.hpp:233
WellStateGuard pushWellState(WellState< Scalar, IndexTraits > &well_state)
Definition: GroupStateHelper.hpp:368
GroupStateGuard pushGroupState(GroupState< Scalar > &group_state)
Definition: GroupStateHelper.hpp:345
Definition: GroupState.hpp:41
Class encapsulating some information about parallel wells.
Definition: ParallelWellInfo.hpp:198
Definition: SingleWellState.hpp:44
Scalar temperature
Definition: SingleWellState.hpp:108
PerfData< Scalar > perf_data
Definition: SingleWellState.hpp:156
Class for computing BHP limits.
Definition: WellBhpThpCalculator.hpp:41
Scalar calculateMinimumBhpFromThp(const WellState< Scalar, IndexTraits > &well_state, const Well &well, const SummaryState &summaryState, const Scalar rho) const
Scalar mostStrictBhpFromBhpLimits(const SummaryState &summaryState) const
Obtain the most strict BHP from BHP limits.
bool isStableSolution(const WellState< Scalar, IndexTraits > &well_state, const Well &well, const std::vector< Scalar > &rates, const SummaryState &summaryState) const
EvalWell calculateBhpFromThp(const WellState< Scalar, IndexTraits > &well_state, const std::vector< EvalWell > &rates, const Well &well, const SummaryState &summaryState, const Scalar rho, DeferredLogger &deferred_logger) const
std::optional< Scalar > estimateStableBhp(const WellState< Scalar, IndexTraits > &well_state, const Well &well, const std::vector< Scalar > &rates, const Scalar rho, const SummaryState &summaryState) const
Well well_ecl_
Definition: WellInterfaceGeneric.hpp:318
int number_of_local_perforations_
Definition: WellInterfaceGeneric.hpp:356
FluidSystem::Scalar wsolvent_
Definition: WellInterfaceGeneric.hpp:396
Definition: WellInterfaceIndices.hpp:34
bool stoppedOrZeroRateTarget(const GroupStateHelperType &groupStateHelper) const
Definition: WellInterface_impl.hpp:1764
bool updateWellOperabilityFromWellEq(const Simulator &simulator, const GroupStateHelperType &groupStateHelper)
Definition: WellInterface_impl.hpp:1315
void checkWellOperability(const Simulator &simulator, const WellStateType &well_state, const GroupStateHelperType &groupStateHelper)
Definition: WellInterface_impl.hpp:1187
void updateWellOperability(const Simulator &simulator, const WellStateType &well_state, const GroupStateHelperType &groupStateHelper)
Definition: WellInterface_impl.hpp:1277
bool solveWellWithOperabilityCheck(const Simulator &simulator, const double dt, const Well::InjectionControls &inj_controls, const Well::ProductionControls &prod_controls, const GroupStateHelperType &groupStateHelper, WellStateType &well_state)
Definition: WellInterface_impl.hpp:613
Scalar woxygen() const
Definition: WellInterface_impl.hpp:166
IndividualOrGroup
Definition: WellInterface.hpp:254
GetPropType< TypeTag, Properties::Simulator > Simulator
Definition: WellInterface.hpp:83
void assembleWellEqWithoutIteration(const Simulator &simulator, const GroupStateHelperType &groupStateHelper, const double dt, WellStateType &well_state, const bool solving_with_zero_rate)
Definition: WellInterface_impl.hpp:986
Scalar computeConnectionDFactor(const int perf, const IntensiveQuantities &intQuants, const SingleWellStateType &ws) const
Definition: WellInterface_impl.hpp:2011
typename WellInterfaceFluidSystem< FluidSystem >::RateConverterType RateConverterType
Definition: WellInterface.hpp:106
Scalar wfoam() const
Definition: WellInterface_impl.hpp:128
bool updateWellControlAndStatusLocalIteration(const Simulator &simulator, const GroupStateHelperType &groupStateHelper, const Well::InjectionControls &inj_controls, const Well::ProductionControls &prod_controls, const Scalar WQTotal, WellStateType &well_state, const bool fixed_control, const bool fixed_status, const bool solving_with_zero_rate)
Definition: WellInterface_impl.hpp:287
void getTransMult(Value &trans_mult, const Simulator &simulator, const int cell_idx, Callback &extendEval) const
Definition: WellInterface_impl.hpp:2099
std::vector< RateVector > connectionRates_
Definition: WellInterface.hpp:389
bool solveWellForTesting(const Simulator &simulator, const GroupStateHelperType &groupStateHelper, WellStateType &well_state)
Definition: WellInterface_impl.hpp:852
void computeConnLevelProdInd(const FluidState &fs, const std::function< Scalar(const Scalar)> &connPICalc, const std::vector< Scalar > &mobility, Scalar *connPI) const
Definition: WellInterface_impl.hpp:2265
void gliftBeginTimeStepWellTestUpdateALQ(const Simulator &simulator, WellStateType &well_state, const GroupState< Scalar > &group_state, GLiftEclWells &ecl_well_map, DeferredLogger &deferred_logger)
Definition: WellInterface_impl.hpp:1215
Scalar volumetricSurfaceRateForConnection(int cellIdx, int phaseIdx) const
Definition: WellInterface_impl.hpp:1167
virtual void init(const std::vector< Scalar > &depth_arg, const Scalar gravity_arg, const std::vector< Scalar > &B_avg, const bool changed_to_open_this_step)
Definition: WellInterface_impl.hpp:96
std::optional< Scalar > computeBhpAtThpLimitProdWithAlqUsingIPR(const Simulator &simulator, const WellStateType &well_state, Scalar bhp, const SummaryState &summary_state, const Scalar alq_value)
Definition: WellInterface_impl.hpp:2230
void getTw(std::vector< Value > &wi, const int perf, const IntensiveQuantities &intQuants, const Value &trans_mult, const SingleWellStateType &ws) const
Definition: WellInterface_impl.hpp:1913
void getMobility(const Simulator &simulator, const int local_perf_index, std::vector< Value > &mob, Callback &extendEval, DeferredLogger &deferred_logger) const
Definition: WellInterface_impl.hpp:2112
GetPropType< TypeTag, Properties::IntensiveQuantities > IntensiveQuantities
Definition: WellInterface.hpp:88
GetPropType< TypeTag, Properties::Scalar > Scalar
Definition: WellInterface.hpp:84
std::vector< Scalar > initialWellRateFractions(const Simulator &ebosSimulator, const WellStateType &well_state) const
Definition: WellInterface_impl.hpp:1775
void solveWellEquation(const Simulator &simulator, const GroupStateHelperType &groupStateHelper, WellStateType &well_state)
Definition: WellInterface_impl.hpp:908
void updateConnectionDFactor(const Simulator &simulator, SingleWellStateType &ws) const
Definition: WellInterface_impl.hpp:1991
Eval getPerfCellPressure(const FluidState &fs) const
Definition: WellInterface_impl.hpp:2084
void initializeProducerWellState(const Simulator &simulator, WellStateType &well_state, DeferredLogger &deferred_logger) const
Definition: WellInterface_impl.hpp:1825
virtual void updateWellStateWithTarget(const Simulator &simulator, const GroupStateHelperType &groupStateHelper, WellStateType &well_state) const
Definition: WellInterface_impl.hpp:1345
void addCellRates(std::map< int, RateVector > &cellRates_) const
Definition: WellInterface_impl.hpp:1148
typename Base::ModelParameters ModelParameters
Definition: WellInterface.hpp:112
GetPropType< TypeTag, Properties::FluidSystem > FluidSystem
Definition: WellInterface.hpp:85
static constexpr bool has_solvent
Definition: WellInterface.hpp:114
bool wellUnderZeroRateTarget(const GroupStateHelperType &groupStateHelper) const
Definition: WellInterface_impl.hpp:1732
GetPropType< TypeTag, Properties::RateVector > RateVector
Definition: WellInterface.hpp:91
void updateConnectionTransmissibilityFactor(const Simulator &simulator, SingleWellStateType &ws) const
Definition: WellInterface_impl.hpp:2053
void computeConnLevelInjInd(const FluidState &fs, const Phase preferred_phase, const std::function< Scalar(const Scalar)> &connIICalc, const std::vector< Scalar > &mobility, Scalar *connII, DeferredLogger &deferred_logger) const
Definition: WellInterface_impl.hpp:2299
typename GasLiftGroupInfo< Scalar, IndexTraits >::GLiftEclWells GLiftEclWells
Definition: WellInterface.hpp:93
std::unique_ptr< GasLiftSingleWell > initializeGliftWellTest_(const Simulator &simulator, WellStateType &well_state, const GroupState< Scalar > &group_state, GLiftEclWells &ecl_well_map, DeferredLogger &deferred_logger)
Definition: WellInterface_impl.hpp:2333
BlackOilFluidStateType< Eval > FluidState
Definition: WellInterface.hpp:144
std::optional< Scalar > estimateOperableBhp(const Simulator &ebos_simulator, const double dt, const GroupStateHelperType &groupStateHelper, const SummaryState &summary_state, WellStateType &well_state)
Definition: WellInterface_impl.hpp:733
Scalar wsalt() const
Definition: WellInterface_impl.hpp:142
bool solveWellWithZeroRate(const Simulator &simulator, const double dt, const GroupStateHelperType &groupStateHelper, WellStateType &well_state)
Definition: WellInterface_impl.hpp:820
bool wellUnderZeroGroupRateTarget(const GroupStateHelperType &groupStateHelper, const std::optional< bool > group_control=std::nullopt) const
Definition: WellInterface_impl.hpp:1749
bool solveWellWithBhp(const Simulator &simulator, const double dt, const Scalar bhp, const GroupStateHelperType &groupStateHelper, WellStateType &well_state)
Definition: WellInterface_impl.hpp:770
void prepareWellBeforeAssembling(const Simulator &simulator, const double dt, const GroupStateHelperType &groupStateHelper, WellStateType &well_state)
Definition: WellInterface_impl.hpp:1021
void wellTesting(const Simulator &simulator, const double simulation_time, const GroupStateHelperType &groupStateHelper, WellStateType &well_state, WellTestState &welltest_state, GLiftEclWells &ecl_well_map, std::map< std::string, double > &open_times)
Definition: WellInterface_impl.hpp:406
typename Base::Eval Eval
Definition: WellInterface.hpp:97
WellInterface(const Well &well, const ParallelWellInfo< Scalar > &pw_info, const int time_step, const ModelParameters ¶m, const RateConverterType &rate_converter, const int pvtRegionIdx, const int num_conservation_quantities, const int num_phases, const int index_of_well, const std::vector< PerforationData< Scalar > > &perf_data)
Constructor.
Definition: WellInterface_impl.hpp:59
bool updateWellStateWithTHPTargetProd(const Simulator &simulator, WellStateType &well_state, const GroupStateHelperType &groupStateHelper) const
Definition: WellInterface_impl.hpp:2198
bool iterateWellEquations(const Simulator &simulator, const double dt, const GroupStateHelperType &groupStateHelper, WellStateType &well_state)
Definition: WellInterface_impl.hpp:535
Scalar wpolymer() const
Definition: WellInterface_impl.hpp:112
GetPropType< TypeTag, Properties::Indices > Indices
Definition: WellInterface.hpp:87
bool updateWellControl(const Simulator &simulator, const IndividualOrGroup iog, const GroupStateHelperType &groupStateHelper, WellStateType &well_state)
Definition: WellInterface_impl.hpp:190
Scalar wurea() const
Definition: WellInterface_impl.hpp:178
void updateGroupTargetFallbackFlag(WellStateType &well_state, DeferredLogger &deferred_logger) const
Definition: WellInterface_impl.hpp:1006
void assembleWellEq(const Simulator &simulator, const double dt, const GroupStateHelperType &groupStateHelper, WellStateType &well_state)
Definition: WellInterface_impl.hpp:970
Scalar wmicrobes() const
Definition: WellInterface_impl.hpp:154
virtual void scaleSegmentRatesAndPressure(WellStateType &well_state) const
Definition: WellInterface_impl.hpp:1337
static constexpr bool has_zFraction
Definition: WellInterface.hpp:115
Definition: WellState.hpp:66
constexpr int numPhases() const
The number of phases present.
Definition: WellState.hpp:269
const SingleWellState< Scalar, IndexTraits > & well(std::size_t well_index) const
Definition: WellState.hpp:310
bool isOpen(const std::string &name) const
Definition: WellState.hpp:217
@ NONE
Definition: DeferredLogger.hpp:46
Dune::Communication< MPIComm > Communication
Definition: ParallelCommunication.hpp:30
Phase
Phase indices for reservoir coupling, we currently only support black-oil phases (oil,...
Definition: ReservoirCoupling.hpp:165
Definition: blackoilbioeffectsmodules.hh:45
std::string to_string(const ConvergenceReport::ReservoirFailure::Type t)
Static data associated with a well perforation.
Definition: PerforationData.hpp:30