/* Copyright 2019 Norce. Copyright 2020 Equinor ASA. This file is part of the Open Porous Media project (OPM). OPM is free software: you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation, either version 3 of the License, or (at your option) any later version. OPM is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with OPM. If not, see . */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include namespace { Opm::GuideRate::RateVector getGuideRateVector(const std::vector& rates, const Opm::PhaseUsage& pu) { using Opm::BlackoilPhases; double oilRate = 0.0; if (pu.phase_used[BlackoilPhases::Liquid]) oilRate = rates[pu.phase_pos[BlackoilPhases::Liquid]]; double gasRate = 0.0; if (pu.phase_used[BlackoilPhases::Vapour]) gasRate = rates[pu.phase_pos[BlackoilPhases::Vapour]]; double waterRate = 0.0; if (pu.phase_used[BlackoilPhases::Aqua]) waterRate = rates[pu.phase_pos[BlackoilPhases::Aqua]]; return {oilRate, gasRate, waterRate}; } double sumWellPhaseRates(bool res_rates, const Opm::Group& group, const Opm::Schedule& schedule, const Opm::WellState& wellState, const int reportStepIdx, const int phasePos, const bool injector) { double rate = 0.0; for (const std::string& groupName : group.groups()) { const auto& groupTmp = schedule.getGroup(groupName, reportStepIdx); const auto& gefac = groupTmp.getGroupEfficiencyFactor(); rate += gefac * sumWellPhaseRates(res_rates, groupTmp, schedule, wellState, reportStepIdx, phasePos, injector); } for (const std::string& wellName : group.wells()) { const auto& well_index = wellState.index(wellName); if (!well_index.has_value()) continue; if (! wellState.wellIsOwned(well_index.value(), wellName) ) // Only sum once { continue; } const auto& wellEcl = schedule.getWell(wellName, reportStepIdx); // only count producers or injectors if ((wellEcl.isProducer() && injector) || (wellEcl.isInjector() && !injector)) continue; if (wellEcl.getStatus() == Opm::Well::Status::SHUT) continue; double factor = wellEcl.getEfficiencyFactor(); const auto& ws = wellState.well(well_index.value()); if (res_rates) { const auto& well_rates = ws.reservoir_rates; if (injector) rate += factor * well_rates[phasePos]; else rate -= factor * well_rates[phasePos]; } else { const auto& well_rates = ws.surface_rates; if (injector) rate += factor * well_rates[phasePos]; else rate -= factor * well_rates[phasePos]; } } return rate; } } // namespace Anonymous namespace Opm { namespace WellGroupHelpers { void setCmodeGroup(const Group& group, const Schedule& schedule, const SummaryState& summaryState, const int reportStepIdx, WellState& wellState, GroupState& group_state) { for (const std::string& groupName : group.groups()) { setCmodeGroup(schedule.getGroup(groupName, reportStepIdx), schedule, summaryState, reportStepIdx, wellState, group_state); } // use NONE as default control const Phase all[] = {Phase::WATER, Phase::OIL, Phase::GAS}; for (Phase phase : all) { if (!group_state.has_injection_control(group.name(), phase)) { group_state.injection_control(group.name(), phase, Group::InjectionCMode::NONE); } } if (!group_state.has_production_control(group.name())) { group_state.production_control(group.name(), Group::ProductionCMode::NONE); } const auto& events = schedule[reportStepIdx].wellgroup_events(); if (group.isInjectionGroup() && events.hasEvent(group.name(), ScheduleEvents::GROUP_INJECTION_UPDATE)) { for (Phase phase : all) { if (!group.hasInjectionControl(phase)) continue; const auto& controls = group.injectionControls(phase, summaryState); group_state.injection_control(group.name(), phase, controls.cmode); } } if (group.isProductionGroup() && events.hasEvent(group.name(), ScheduleEvents::GROUP_PRODUCTION_UPDATE)) { const auto controls = group.productionControls(summaryState); group_state.production_control(group.name(), controls.cmode); } if (group.has_gpmaint_control(Group::ProductionCMode::RESV)) { group_state.production_control(group.name(), Group::ProductionCMode::RESV); } for (Phase phase : all) { if (group.has_gpmaint_control(phase, Group::InjectionCMode::RATE)) { group_state.injection_control(group.name(), phase, Group::InjectionCMode::RATE); } else if (group.has_gpmaint_control(phase, Group::InjectionCMode::RESV)) { group_state.injection_control(group.name(), phase, Group::InjectionCMode::RESV); } } if (schedule[reportStepIdx].gconsale().has(group.name())) { group_state.injection_control(group.name(), Phase::GAS, Group::InjectionCMode::SALE); } } void accumulateGroupEfficiencyFactor(const Group& group, const Schedule& schedule, const int reportStepIdx, double& factor) { factor *= group.getGroupEfficiencyFactor(); if (group.parent() != "FIELD" && !group.parent().empty()) accumulateGroupEfficiencyFactor( schedule.getGroup(group.parent(), reportStepIdx), schedule, reportStepIdx, factor); } double sumWellSurfaceRates(const Group& group, const Schedule& schedule, const WellState& wellState, const int reportStepIdx, const int phasePos, const bool injector) { return sumWellPhaseRates(false, group, schedule, wellState, reportStepIdx, phasePos, injector); } double sumWellResRates(const Group& group, const Schedule& schedule, const WellState& wellState, const int reportStepIdx, const int phasePos, const bool injector) { return sumWellPhaseRates(true, group, schedule, wellState, reportStepIdx, phasePos, injector); } double sumSolventRates(const Group& group, const Schedule& schedule, const WellState& wellState, const int reportStepIdx, const bool injector) { double rate = 0.0; for (const std::string& groupName : group.groups()) { const Group& groupTmp = schedule.getGroup(groupName, reportStepIdx); const auto& gefac = groupTmp.getGroupEfficiencyFactor(); rate += gefac * sumSolventRates(groupTmp, schedule, wellState, reportStepIdx, injector); } for (const std::string& wellName : group.wells()) { const auto& well_index = wellState.index(wellName); if (!well_index.has_value()) continue; if (! wellState.wellIsOwned(well_index.value(), wellName) ) // Only sum once { continue; } const auto& wellEcl = schedule.getWell(wellName, reportStepIdx); // only count producers or injectors if ((wellEcl.isProducer() && injector) || (wellEcl.isInjector() && !injector)) continue; if (wellEcl.getStatus() == Well::Status::SHUT) continue; const auto& ws = wellState.well(well_index.value()); double factor = wellEcl.getEfficiencyFactor(); if (injector) rate += factor * ws.sum_solvent_rates(); else rate -= factor * ws.sum_solvent_rates(); } return rate; } void updateGuideRatesForInjectionGroups(const Group& group, const Schedule& schedule, const SummaryState& summaryState, const Opm::PhaseUsage& pu, const int reportStepIdx, const WellState& wellState, const GroupState& group_state, GuideRate* guideRate, Opm::DeferredLogger& deferred_logger) { for (const std::string& groupName : group.groups()) { const Group& groupTmp = schedule.getGroup(groupName, reportStepIdx); updateGuideRatesForInjectionGroups(groupTmp, schedule, summaryState, pu, reportStepIdx, wellState, group_state, guideRate, deferred_logger); } const Phase all[] = {Phase::WATER, Phase::OIL, Phase::GAS}; for (Phase phase : all) { if(!group.hasInjectionControl(phase)) continue; double guideRateValue = 0.0; const auto& controls = group.injectionControls(phase, summaryState); switch (controls.guide_rate_def){ case Group::GuideRateInjTarget::RATE: break; case Group::GuideRateInjTarget::VOID: { guideRateValue = group_state.injection_vrep_rate(group.name()); break; } case Group::GuideRateInjTarget::NETV: { guideRateValue = group_state.injection_vrep_rate(group.name()); const std::vector& injRES = group_state.injection_reservoir_rates(group.name()); if (phase != Phase::OIL && pu.phase_used[BlackoilPhases::Liquid]) guideRateValue -= injRES[pu.phase_pos[BlackoilPhases::Liquid]]; if (phase != Phase::GAS && pu.phase_used[BlackoilPhases::Vapour]) guideRateValue -= injRES[pu.phase_pos[BlackoilPhases::Vapour]]; if (phase != Phase::WATER && pu.phase_used[BlackoilPhases::Aqua]) guideRateValue -= injRES[pu.phase_pos[BlackoilPhases::Aqua]]; break; } case Group::GuideRateInjTarget::RESV: OPM_DEFLOG_THROW(std::runtime_error, "GUIDE PHASE RESV not implemented. Group " + group.name(), deferred_logger); case Group::GuideRateInjTarget::POTN: break; case Group::GuideRateInjTarget::NO_GUIDE_RATE: break; default: OPM_DEFLOG_THROW(std::logic_error, "Invalid GuideRateInjTarget in updateGuideRatesForInjectionGroups", deferred_logger); } const UnitSystem& unit_system = schedule.getUnits(); guideRateValue = unit_system.from_si(UnitSystem::measure::rate, guideRateValue); guideRate->compute(group.name(), phase, reportStepIdx, guideRateValue); } } void updateGroupTargetReduction(const Group& group, const Schedule& schedule, const int reportStepIdx, const bool isInjector, const PhaseUsage& pu, const GuideRate& guide_rate, const WellState& wellState, GroupState& group_state, std::vector& groupTargetReduction) { const int np = wellState.numPhases(); for (const std::string& subGroupName : group.groups()) { std::vector subGroupTargetReduction(np, 0.0); const Group& subGroup = schedule.getGroup(subGroupName, reportStepIdx); updateGroupTargetReduction(subGroup, schedule, reportStepIdx, isInjector, pu, guide_rate, wellState, group_state, subGroupTargetReduction); const double subGroupEfficiency = subGroup.getGroupEfficiencyFactor(); // accumulate group contribution from sub group if (isInjector) { const Phase all[] = {Phase::WATER, Phase::OIL, Phase::GAS}; for (Phase phase : all) { int phase_pos = -1; switch (phase) { case Phase::GAS: if (pu.phase_used[BlackoilPhases::Vapour]) { phase_pos = pu.phase_pos[BlackoilPhases::Vapour]; } break; case Phase::OIL: if (pu.phase_used[BlackoilPhases::Liquid]) { phase_pos = pu.phase_pos[BlackoilPhases::Liquid]; } break; case Phase::WATER: if (pu.phase_used[BlackoilPhases::Aqua]) { phase_pos = pu.phase_pos[BlackoilPhases::Aqua]; } break; default: // just to avoid warning throw std::invalid_argument("unhandled phase enum"); } // the phase is not present if (phase_pos == -1) continue; const Group::InjectionCMode& currentGroupControl = group_state.injection_control(subGroup.name(), phase); const bool individual_control = (currentGroupControl != Group::InjectionCMode::FLD && currentGroupControl != Group::InjectionCMode::NONE); const int num_group_controlled_wells = groupControlledWells(schedule, wellState, group_state, reportStepIdx, subGroupName, "", !isInjector, phase); if (individual_control || num_group_controlled_wells == 0) { groupTargetReduction[phase_pos] += subGroupEfficiency * sumWellSurfaceRates(subGroup, schedule, wellState, reportStepIdx, phase_pos, isInjector); } else { // Accumulate from this subgroup only if no group guide rate is set for it. if (!guide_rate.has(subGroupName, phase)) { groupTargetReduction[phase_pos] += subGroupEfficiency * subGroupTargetReduction[phase_pos]; } } } } else { const Group::ProductionCMode& currentGroupControl = group_state.production_control(subGroupName); const bool individual_control = (currentGroupControl != Group::ProductionCMode::FLD && currentGroupControl != Group::ProductionCMode::NONE); const int num_group_controlled_wells = groupControlledWells(schedule, wellState, group_state, reportStepIdx, subGroupName, "", !isInjector, /*injectionPhaseNotUsed*/Phase::OIL); if (individual_control || num_group_controlled_wells == 0) { for (int phase = 0; phase < np; phase++) { groupTargetReduction[phase] += subGroupEfficiency * sumWellSurfaceRates(subGroup, schedule, wellState, reportStepIdx, phase, isInjector); } } else { // The subgroup may participate in group control. if (!guide_rate.has(subGroupName)) { // Accumulate from this subgroup only if no group guide rate is set for it. for (int phase = 0; phase < np; phase++) { groupTargetReduction[phase] += subGroupEfficiency * subGroupTargetReduction[phase]; } } } } } for (const std::string& wellName : group.wells()) { const auto& wellTmp = schedule.getWell(wellName, reportStepIdx); if (wellTmp.isProducer() && isInjector) continue; if (wellTmp.isInjector() && !isInjector) continue; if (wellTmp.getStatus() == Well::Status::SHUT) continue; const auto& well_index = wellState.index(wellName); if (!well_index.has_value()) continue; if (! wellState.wellIsOwned(well_index.value(), wellName) ) // Only sum once { continue; } const double efficiency = wellTmp.getEfficiencyFactor(); // add contributino from wells not under group control const auto& ws = wellState.well(well_index.value()); if (isInjector) { if (ws.injection_cmode != Well::InjectorCMode::GRUP) for (int phase = 0; phase < np; phase++) { groupTargetReduction[phase] += ws.surface_rates[phase] * efficiency; } } else { if (ws.production_cmode != Well::ProducerCMode::GRUP) for (int phase = 0; phase < np; phase++) { groupTargetReduction[phase] -= ws.surface_rates[phase] * efficiency; } } } if (isInjector) group_state.update_injection_reduction_rates(group.name(), groupTargetReduction); else group_state.update_production_reduction_rates(group.name(), groupTargetReduction); } void updateWellRatesFromGroupTargetScale(const double scale, const Group& group, const Schedule& schedule, const int reportStepIdx, bool isInjector, const GroupState& group_state, WellState& wellState) { for (const std::string& groupName : group.groups()) { bool individual_control = false; if (isInjector) { const Phase all[] = {Phase::WATER, Phase::OIL, Phase::GAS}; for (Phase phase : all) { const Group::InjectionCMode& currentGroupControl = group_state.injection_control(groupName, phase); individual_control = individual_control || (currentGroupControl != Group::InjectionCMode::FLD && currentGroupControl != Group::InjectionCMode::NONE); } } else { const Group::ProductionCMode& currentGroupControl = group_state.production_control(groupName); individual_control = (currentGroupControl != Group::ProductionCMode::FLD && currentGroupControl != Group::ProductionCMode::NONE); } if (!individual_control) { const Group& groupTmp = schedule.getGroup(groupName, reportStepIdx); updateWellRatesFromGroupTargetScale(scale, groupTmp, schedule, reportStepIdx, isInjector, group_state, wellState); } } const int np = wellState.numPhases(); for (const std::string& wellName : group.wells()) { const auto& wellTmp = schedule.getWell(wellName, reportStepIdx); if (wellTmp.isProducer() && isInjector) continue; if (wellTmp.isInjector() && !isInjector) continue; if (wellTmp.getStatus() == Well::Status::SHUT) continue; const auto& well_index = wellState.index(wellName); if (!well_index.has_value()) continue; if (! wellState.wellIsOwned(well_index.value(), wellName) ) // Only sum once { continue; } // scale rates auto& ws = wellState.well(well_index.value()); if (isInjector) { if (ws.injection_cmode == Well::InjectorCMode::GRUP) for (int phase = 0; phase < np; phase++) { ws.surface_rates[phase] *= scale; } } else { if (ws.production_cmode == Well::ProducerCMode::GRUP) for (int phase = 0; phase < np; phase++) { ws.surface_rates[phase] *= scale; } } } } void updateVREPForGroups(const Group& group, const Schedule& schedule, const int reportStepIdx, const WellState& wellState, GroupState& group_state) { for (const std::string& groupName : group.groups()) { const Group& groupTmp = schedule.getGroup(groupName, reportStepIdx); updateVREPForGroups(groupTmp, schedule, reportStepIdx, wellState, group_state); } const int np = wellState.numPhases(); double resv = 0.0; for (int phase = 0; phase < np; ++phase) { resv += sumWellPhaseRates(true, group, schedule, wellState, reportStepIdx, phase, /*isInjector*/ false); } group_state.update_injection_vrep_rate(group.name(), resv); } void updateReservoirRatesInjectionGroups(const Group& group, const Schedule& schedule, const int reportStepIdx, const WellState& wellState, GroupState& group_state) { for (const std::string& groupName : group.groups()) { const Group& groupTmp = schedule.getGroup(groupName, reportStepIdx); updateReservoirRatesInjectionGroups(groupTmp, schedule, reportStepIdx, wellState, group_state); } const int np = wellState.numPhases(); std::vector resv(np, 0.0); for (int phase = 0; phase < np; ++phase) { resv[phase] = sumWellPhaseRates(true, group, schedule, wellState, reportStepIdx, phase, /*isInjector*/ true); } group_state.update_injection_reservoir_rates(group.name(), resv); } void updateSurfaceRatesInjectionGroups(const Group& group, const Schedule& schedule, const int reportStepIdx, const WellState& wellState, GroupState& group_state) { for (const std::string& groupName : group.groups()) { const Group& groupTmp = schedule.getGroup(groupName, reportStepIdx); updateSurfaceRatesInjectionGroups(groupTmp, schedule, reportStepIdx, wellState, group_state); } const int np = wellState.numPhases(); std::vector rates(np, 0.0); for (int phase = 0; phase < np; ++phase) { rates[phase] = sumWellPhaseRates(false, group, schedule, wellState, reportStepIdx, phase, /*isInjector*/ true); } group_state.update_injection_surface_rates(group.name(), rates); } void updateWellRates(const Group& group, const Schedule& schedule, const int reportStepIdx, const WellState& wellStateNupcol, WellState& wellState) { for (const std::string& groupName : group.groups()) { const Group& groupTmp = schedule.getGroup(groupName, reportStepIdx); updateWellRates(groupTmp, schedule, reportStepIdx, wellStateNupcol, wellState); } const int np = wellState.numPhases(); for (const std::string& wellName : group.wells()) { std::vector rates(np, 0.0); const auto& well_index = wellState.index(wellName); if (well_index.has_value()) { // the well is found on this node const auto& wellTmp = schedule.getWell(wellName, reportStepIdx); int sign = 1; // production wellRates are negative. The users of currentWellRates uses the convention in // opm-common that production and injection rates are positive. if (!wellTmp.isInjector()) sign = -1; const auto& ws = wellStateNupcol.well(well_index.value()); for (int phase = 0; phase < np; ++phase) { rates[phase] = sign * ws.surface_rates[phase]; } } wellState.setCurrentWellRates(wellName, rates); } } void updateGroupProductionRates(const Group& group, const Schedule& schedule, const int reportStepIdx, const WellState& wellState, GroupState& group_state) { for (const std::string& groupName : group.groups()) { const Group& groupTmp = schedule.getGroup(groupName, reportStepIdx); updateGroupProductionRates(groupTmp, schedule, reportStepIdx, wellState, group_state); } const int np = wellState.numPhases(); std::vector rates(np, 0.0); for (int phase = 0; phase < np; ++phase) { rates[phase] = sumWellPhaseRates(false, group, schedule, wellState, reportStepIdx, phase, /*isInjector*/ false); } group_state.update_production_rates(group.name(), rates); } void updateREINForGroups(const Group& group, const Schedule& schedule, const int reportStepIdx, const PhaseUsage& pu, const SummaryState& st, const WellState& wellState, GroupState& group_state) { const int np = wellState.numPhases(); for (const std::string& groupName : group.groups()) { const Group& groupTmp = schedule.getGroup(groupName, reportStepIdx); updateREINForGroups(groupTmp, schedule, reportStepIdx, pu, st, wellState, group_state); } std::vector rein(np, 0.0); for (int phase = 0; phase < np; ++phase) { rein[phase] = sumWellPhaseRates(false, group, schedule, wellState, reportStepIdx, phase, /*isInjector*/ false); } // add import rate and subtract consumption rate for group for gas if (schedule[reportStepIdx].gconsump().has(group.name())) { const auto& gconsump = schedule[reportStepIdx].gconsump().get(group.name(), st); if (pu.phase_used[BlackoilPhases::Vapour]) { rein[pu.phase_pos[BlackoilPhases::Vapour]] += gconsump.import_rate; rein[pu.phase_pos[BlackoilPhases::Vapour]] -= gconsump.consumption_rate; } } group_state.update_injection_rein_rates(group.name(), rein); } template void updateGpMaintTargetForGroups(const Group& group, const Schedule& schedule, const RegionalValues& regional_values, const int reportStepIdx, const double dt, const WellState& well_state, GroupState& group_state) { for (const std::string& groupName : group.groups()) { const Group& groupTmp = schedule.getGroup(groupName, reportStepIdx); updateGpMaintTargetForGroups(groupTmp, schedule, regional_values, reportStepIdx, dt, well_state, group_state); } const auto& gpm = group.gpmaint(); if (!gpm) return; const auto& region = gpm->region(); if (!region) return; const auto [name, number] = *region; const double error = gpm->pressure_target() - regional_values.at(name)->pressure(number); double current_rate = 0.0; const auto& pu = well_state.phaseUsage(); double sign = 1.0; switch (gpm->flow_target()) { case GPMaint::FlowTarget::RESV_PROD: { current_rate = -group_state.injection_vrep_rate(group.name()); sign = -1.0; break; } case GPMaint::FlowTarget::RESV_OINJ: { if (pu.phase_used[BlackoilPhases::Liquid]) current_rate = group_state.injection_reservoir_rates(group.name())[pu.phase_pos[BlackoilPhases::Liquid]]; break; } case GPMaint::FlowTarget::RESV_WINJ: { if (pu.phase_used[BlackoilPhases::Aqua]) current_rate = group_state.injection_reservoir_rates(group.name())[pu.phase_pos[BlackoilPhases::Aqua]]; break; } case GPMaint::FlowTarget::RESV_GINJ: { if (pu.phase_used[BlackoilPhases::Vapour]) current_rate = group_state.injection_reservoir_rates(group.name())[pu.phase_pos[BlackoilPhases::Vapour]]; break; } case GPMaint::FlowTarget::SURF_OINJ: { if (pu.phase_used[BlackoilPhases::Liquid]) current_rate = group_state.injection_surface_rates(group.name())[pu.phase_pos[BlackoilPhases::Liquid]]; break; } case GPMaint::FlowTarget::SURF_WINJ: { if (pu.phase_used[BlackoilPhases::Aqua]) current_rate = group_state.injection_surface_rates(group.name())[pu.phase_pos[BlackoilPhases::Aqua]]; break; } case GPMaint::FlowTarget::SURF_GINJ: { if (pu.phase_used[BlackoilPhases::Vapour]) current_rate = group_state.injection_surface_rates(group.name())[pu.phase_pos[BlackoilPhases::Vapour]]; break; } default: throw std::invalid_argument("Invalid Flow target type in GPMAINT"); } auto& gpmaint_state = group_state.gpmaint(group.name()); double rate = gpm->rate(gpmaint_state, current_rate, error, dt); group_state.update_gpmaint_target(group.name(), std::max(0.0, sign * rate)); } std::map computeNetworkPressures(const Opm::Network::ExtNetwork& network, const WellState& well_state, const GroupState& group_state, const VFPProdProperties& vfp_prod_props, const Schedule& schedule, const int report_time_step) { // TODO: Only dealing with production networks for now. if (!network.active()) { return {}; } // Fixed pressure nodes of the network are the roots of trees. // Leaf nodes must correspond to groups in the group structure. // Let us first find all leaf nodes of the network. We also // create a vector of all nodes, ordered so that a child is // always after its parent. std::stack children; std::set leaf_nodes; std::vector root_to_child_nodes; children.push(network.root().name()); while (!children.empty()) { const auto node = children.top(); children.pop(); root_to_child_nodes.push_back(node); auto branches = network.downtree_branches(node); if (branches.empty()) { leaf_nodes.insert(node); } for (const auto& branch : branches) { children.push(branch.downtree_node()); } } assert(children.empty()); // Starting with the leaf nodes of the network, get the flow rates // from the corresponding groups. std::map> node_inflows; for (const auto& node : leaf_nodes) { node_inflows[node] = group_state.production_rates(node); // Add the ALQ amounts to the gas rates if requested. if (network.node(node).add_gas_lift_gas()) { const auto& group = schedule.getGroup(node, report_time_step); for (const std::string& wellname : group.wells()) { const Well& well = schedule.getWell(wellname, report_time_step); // Here we use the efficiency unconditionally, but if WEFAC item 3 // for the well is false (it defaults to true) then we should NOT use // the efficiency factor. Fixing this requires not only changing the // code here, but also: // - Adding a member to the well for this flag, and setting it in Schedule::handleWEFAC(). // - Making the wells' maximum flows (i.e. not time-averaged by using a efficiency factor) // available and using those (for wells with WEFAC(3) true only) when accumulating group // rates, but ONLY for network calculations. const double efficiency = well.getEfficiencyFactor(); node_inflows[node][BlackoilPhases::Vapour] += well_state.getALQ(wellname) * efficiency; } } } // Accumulate in the network, towards the roots. Note that a // root (i.e. fixed pressure node) can still be contributing // flow towards other nodes in the network, i.e. a node is // the root of a subtree. auto child_to_root_nodes = root_to_child_nodes; std::reverse(child_to_root_nodes.begin(), child_to_root_nodes.end()); for (const auto& node : child_to_root_nodes) { const auto upbranch = network.uptree_branch(node); if (upbranch) { // Add downbranch rates to upbranch. std::vector& up = node_inflows[(*upbranch).uptree_node()]; const std::vector& down = node_inflows[node]; if (up.empty()) { up = down; } else { assert (up.size() == down.size()); for (size_t ii = 0; ii < up.size(); ++ii) { up[ii] += down[ii]; } } } } // Going the other way (from roots to leafs), calculate the pressure // at each node using VFP tables and rates. std::map node_pressures; for (const auto& node : root_to_child_nodes) { auto press = network.node(node).terminal_pressure(); if (press) { node_pressures[node] = *press; } else { const auto upbranch = network.uptree_branch(node); assert(upbranch); const double up_press = node_pressures[(*upbranch).uptree_node()]; const auto vfp_table = (*upbranch).vfp_table(); if (vfp_table) { // The rates are here positive, but the VFP code expects the // convention that production rates are negative, so we must // take a copy and flip signs. auto rates = node_inflows[node]; for (auto& r : rates) { r *= -1.0; } assert(rates.size() == 3); const double alq = 0.0; // TODO: Do not ignore ALQ node_pressures[node] = vfp_prod_props.bhp(*vfp_table, rates[BlackoilPhases::Aqua], rates[BlackoilPhases::Liquid], rates[BlackoilPhases::Vapour], up_press, alq, 0.0, //explicit_wfr 0.0, //explicit_gfr false); //use_expvfp we dont support explicit lookup #define EXTRA_DEBUG_NETWORK 0 #if EXTRA_DEBUG_NETWORK std::ostringstream oss; oss << "parent: " << (*upbranch).uptree_node() << " child: " << node << " rates = [ " << rates[0]*86400 << ", " << rates[1]*86400 << ", " << rates[2]*86400 << " ]" << " p(parent) = " << up_press/1e5 << " p(child) = " << node_pressures[node]/1e5 << std::endl; OpmLog::debug(oss.str()); #endif } else { // Table number specified as 9999 in the deck, no pressure loss. node_pressures[node] = up_press; } } } return node_pressures; } GuideRate::RateVector getWellRateVector(const WellState& well_state, const PhaseUsage& pu, const std::string& name) { return getGuideRateVector(well_state.currentWellRates(name), pu); } GuideRate::RateVector getProductionGroupRateVector(const GroupState& group_state, const PhaseUsage& pu, const std::string& group_name) { return getGuideRateVector(group_state.production_rates(group_name), pu); } double getGuideRate(const std::string& name, const Schedule& schedule, const WellState& wellState, const GroupState& group_state, const int reportStepIdx, const GuideRate* guideRate, const GuideRateModel::Target target, const PhaseUsage& pu) { if (schedule.hasWell(name, reportStepIdx)) { if (guideRate->has(name) || guideRate->hasPotentials(name)) { return guideRate->get(name, target, getWellRateVector(wellState, pu, name)); } else { return 0.0; } } if (guideRate->has(name)) { return guideRate->get(name, target, getProductionGroupRateVector(group_state, pu, name)); } double totalGuideRate = 0.0; const Group& group = schedule.getGroup(name, reportStepIdx); for (const std::string& groupName : group.groups()) { const Group::ProductionCMode& currentGroupControl = group_state.production_control(groupName); if (currentGroupControl == Group::ProductionCMode::FLD || currentGroupControl == Group::ProductionCMode::NONE) { // accumulate from sub wells/groups totalGuideRate += getGuideRate(groupName, schedule, wellState, group_state, reportStepIdx, guideRate, target, pu); } } for (const std::string& wellName : group.wells()) { const auto& wellTmp = schedule.getWell(wellName, reportStepIdx); if (wellTmp.isInjector()) continue; if (wellTmp.getStatus() == Well::Status::SHUT) continue; // Only count wells under group control or the ru if (!wellState.isProductionGrup(wellName)) continue; totalGuideRate += getGuideRate(wellName, schedule, wellState, group_state, reportStepIdx, guideRate, target, pu); } return totalGuideRate; } double getGuideRateInj(const std::string& name, const Schedule& schedule, const WellState& wellState, const GroupState& group_state, const int reportStepIdx, const GuideRate* guideRate, const GuideRateModel::Target target, const Phase& injectionPhase, const PhaseUsage& pu) { if (schedule.hasWell(name, reportStepIdx)) { return getGuideRate(name, schedule, wellState, group_state, reportStepIdx, guideRate, target, pu); } if (guideRate->has(name, injectionPhase)) { return guideRate->get(name, injectionPhase); } double totalGuideRate = 0.0; const Group& group = schedule.getGroup(name, reportStepIdx); for (const std::string& groupName : group.groups()) { const Group::InjectionCMode& currentGroupControl = group_state.injection_control(groupName, injectionPhase); if (currentGroupControl == Group::InjectionCMode::FLD || currentGroupControl == Group::InjectionCMode::NONE) { // accumulate from sub wells/groups totalGuideRate += getGuideRateInj(groupName, schedule, wellState, group_state, reportStepIdx, guideRate, target, injectionPhase, pu); } } for (const std::string& wellName : group.wells()) { const auto& wellTmp = schedule.getWell(wellName, reportStepIdx); if (!wellTmp.isInjector()) continue; if (wellTmp.getStatus() == Well::Status::SHUT) continue; // Only count wells under group control or the ru if (!wellState.isInjectionGrup(wellName)) continue; totalGuideRate += guideRate->get(wellName, target, getWellRateVector(wellState, pu, wellName)); } return totalGuideRate; } int groupControlledWells(const Schedule& schedule, const WellState& well_state, const GroupState& group_state, const int report_step, const std::string& group_name, const std::string& always_included_child, const bool is_production_group, const Phase injection_phase) { const Group& group = schedule.getGroup(group_name, report_step); int num_wells = 0; for (const std::string& child_group : group.groups()) { bool included = (child_group == always_included_child); if (is_production_group) { const auto ctrl = group_state.production_control(child_group); included = included || (ctrl == Group::ProductionCMode::FLD) || (ctrl == Group::ProductionCMode::NONE); } else { const auto ctrl = group_state.injection_control(child_group, injection_phase); included = included || (ctrl == Group::InjectionCMode::FLD) || (ctrl == Group::InjectionCMode::NONE); } if (included) { num_wells += groupControlledWells(schedule, well_state, group_state, report_step, child_group, always_included_child, is_production_group, injection_phase); } } for (const std::string& child_well : group.wells()) { bool included = (child_well == always_included_child); if (is_production_group) { included = included || well_state.isProductionGrup(child_well); } else { included = included || well_state.isInjectionGrup(child_well); } if (included) { ++num_wells; } } return num_wells; } FractionCalculator::FractionCalculator(const Schedule& schedule, const WellState& well_state, const GroupState& group_state, const int report_step, const GuideRate* guide_rate, const GuideRateModel::Target target, const PhaseUsage& pu, const bool is_producer, const Phase injection_phase) : schedule_(schedule) , well_state_(well_state) , group_state_(group_state) , report_step_(report_step) , guide_rate_(guide_rate) , target_(target) , pu_(pu) , is_producer_(is_producer) , injection_phase_(injection_phase) { } double FractionCalculator::fraction(const std::string& name, const std::string& control_group_name, const bool always_include_this) { double fraction = 1.0; std::string current = name; while (current != control_group_name) { fraction *= localFraction(current, always_include_this ? name : ""); current = parent(current); } return fraction; } double FractionCalculator::localFraction(const std::string& name, const std::string& always_included_child) { const double my_guide_rate = guideRate(name, always_included_child); const Group& parent_group = schedule_.getGroup(parent(name), report_step_); const double total_guide_rate = guideRateSum(parent_group, always_included_child); // the total guide gate is the same as my_guide rate // the well/group is probably on its own, i.e. return 1 // even is its guide_rate is zero const double guide_rate_epsilon = 1e-12; if ( std::abs(my_guide_rate - total_guide_rate) < guide_rate_epsilon ) return 1.0; assert(total_guide_rate > my_guide_rate); return my_guide_rate / total_guide_rate; } std::string FractionCalculator::parent(const std::string& name) { if (schedule_.hasWell(name)) { return schedule_.getWell(name, report_step_).groupName(); } else { return schedule_.getGroup(name, report_step_).parent(); } } double FractionCalculator::guideRateSum(const Group& group, const std::string& always_included_child) { double total_guide_rate = 0.0; for (const std::string& child_group : group.groups()) { bool included = (child_group == always_included_child); if (is_producer_) { const auto ctrl = this->group_state_.production_control(child_group); included = included || (ctrl == Group::ProductionCMode::FLD) || (ctrl == Group::ProductionCMode::NONE); } else { const auto ctrl = this->group_state_.injection_control(child_group, this->injection_phase_); included = included || (ctrl == Group::InjectionCMode::FLD) || (ctrl == Group::InjectionCMode::NONE); } if (included) { total_guide_rate += guideRate(child_group, always_included_child); } } for (const std::string& child_well : group.wells()) { bool included = (child_well == always_included_child); if (is_producer_) { included = included || well_state_.isProductionGrup(child_well); } else { included = included || well_state_.isInjectionGrup(child_well); } if (included) { total_guide_rate += guideRate(child_well, always_included_child); } } return total_guide_rate; } double FractionCalculator::guideRate(const std::string& name, const std::string& always_included_child) { if (schedule_.hasWell(name, report_step_)) { return getGuideRate(name, schedule_, well_state_, group_state_, report_step_, guide_rate_, target_, pu_); } else { if (groupControlledWells(name, always_included_child) > 0) { if (is_producer_ && guide_rate_->has(name)) { return guide_rate_->get(name, target_, getGroupRateVector(name)); } else if (!is_producer_ && guide_rate_->has(name, injection_phase_)) { return guide_rate_->get(name, injection_phase_); } else { // We are a group, with default guide rate. // Compute guide rate by accumulating our children's guide rates. const Group& group = schedule_.getGroup(name, report_step_); const double eff = group.getGroupEfficiencyFactor(); return eff * guideRateSum(group, always_included_child); } } else { // No group-controlled subordinate wells. return 0.0; } } } int FractionCalculator::groupControlledWells(const std::string& group_name, const std::string& always_included_child) { return ::Opm::WellGroupHelpers::groupControlledWells( schedule_, well_state_, this->group_state_, report_step_, group_name, always_included_child, is_producer_, injection_phase_); } GuideRate::RateVector FractionCalculator::getGroupRateVector(const std::string& group_name) { assert(is_producer_); return getProductionGroupRateVector(this->group_state_, this->pu_, group_name); } std::vector groupChainTopBot(const std::string& bottom, const std::string& top, const Schedule& schedule, const int report_step) { // Get initial parent, 'bottom' can be a well or a group. std::string parent; if (schedule.hasWell(bottom, report_step)) { parent = schedule.getWell(bottom, report_step).groupName(); } else { parent = schedule.getGroup(bottom, report_step).parent(); } // Build the chain from bottom to top. std::vector chain; chain.push_back(bottom); chain.push_back(parent); while (parent != top) { parent = schedule.getGroup(parent, report_step).parent(); chain.push_back(parent); } assert(chain.back() == top); // Reverse order and return. std::reverse(chain.begin(), chain.end()); return chain; } std::pair checkGroupConstraintsProd(const std::string& name, const std::string& parent, const Group& group, const WellState& wellState, const GroupState& group_state, const int reportStepIdx, const GuideRate* guideRate, const double* rates, const PhaseUsage& pu, const double efficiencyFactor, const Schedule& schedule, const SummaryState& summaryState, const std::vector& resv_coeff, DeferredLogger& deferred_logger) { // When called for a well ('name' is a well name), 'parent' // will be the name of 'group'. But if we recurse, 'name' and // 'parent' will stay fixed while 'group' will be higher up // in the group tree. // efficiencyfactor is the well efficiency factor for the first group the well is // part of. Later it is the accumulated factor including the group efficiency factor // of the child of group. const Group::ProductionCMode& currentGroupControl = group_state.production_control(group.name()); if (currentGroupControl == Group::ProductionCMode::FLD || currentGroupControl == Group::ProductionCMode::NONE) { // Return if we are not available for parent group. if (!group.productionGroupControlAvailable()) { return std::make_pair(false, 1); } // Otherwise: check production share of parent's control. const auto& parentGroup = schedule.getGroup(group.parent(), reportStepIdx); return checkGroupConstraintsProd(name, parent, parentGroup, wellState, group_state, reportStepIdx, guideRate, rates, pu, efficiencyFactor * group.getGroupEfficiencyFactor(), schedule, summaryState, resv_coeff, deferred_logger); } // This can be false for FLD-controlled groups, we must therefore // check for FLD first (done above). if (!group.isProductionGroup()) { return std::make_pair(false, 1.0); } // If we are here, we are at the topmost group to be visited in the recursion. // This is the group containing the control we will check against. // gconsale may adjust the grat target. // the adjusted rates is send to the targetCalculator double gratTargetFromSales = 0.0; if (group_state.has_grat_sales_target(group.name())) gratTargetFromSales = group_state.grat_sales_target(group.name()); TargetCalculator tcalc(currentGroupControl, pu, resv_coeff, gratTargetFromSales, group.name(), group_state, group.has_gpmaint_control(currentGroupControl)); FractionCalculator fcalc(schedule, wellState, group_state, reportStepIdx, guideRate, tcalc.guideTargetMode(), pu, true, Phase::OIL); auto localFraction = [&](const std::string& child) { return fcalc.localFraction(child, name); }; auto localReduction = [&](const std::string& group_name) { const std::vector& groupTargetReductions = group_state.production_reduction_rates(group_name); return tcalc.calcModeRateFromRates(groupTargetReductions); }; auto localCurrentRate = [&](const std::string& group_name) { const std::vector& groupSurfaceRates = group_state.production_rates(group_name); return tcalc.calcModeRateFromRates(groupSurfaceRates); }; std::optional ctrl; if (!group.has_gpmaint_control(currentGroupControl)) ctrl = group.productionControls(summaryState); const double orig_target = tcalc.groupTarget(ctrl, deferred_logger); // Assume we have a chain of groups as follows: BOTTOM -> MIDDLE -> TOP. // Then ... // TODO finish explanation. const double current_rate = -tcalc.calcModeRateFromRates(rates); // Switch sign since 'rates' are negative for producers. const auto chain = groupChainTopBot(name, group.name(), schedule, reportStepIdx); // Because 'name' is the last of the elements, and not an ancestor, we subtract one below. const size_t num_ancestors = chain.size() - 1; // we need to find out the level where the current well is applied to the local reduction size_t local_reduction_level = 0; for (size_t ii = 1; ii < num_ancestors; ++ii) { const int num_gr_ctrl = groupControlledWells(schedule, wellState, group_state, reportStepIdx, chain[ii], "", /*is_producer*/ true, /*injectionPhaseNotUsed*/ Phase::OIL); if (guideRate->has(chain[ii]) && num_gr_ctrl > 0) { local_reduction_level = ii; } } // check whether guide rate is violated for (size_t ii = 1; ii < num_ancestors; ++ii) { if (guideRate->has(chain[ii])) { const auto& guided_group = chain[ii]; const double grefficiency = schedule.getGroup(guided_group, reportStepIdx).getGroupEfficiencyFactor(); const double currentRateFraction = grefficiency * localCurrentRate(guided_group) / (localCurrentRate(chain[ii-1])); const double guiderateFraction = localFraction(guided_group); // we add a factor here to avoid switching due to numerical instability const double factor = 1.01; if (currentRateFraction > (guiderateFraction * factor)) { return std::make_pair(true, guiderateFraction/currentRateFraction); } } } double target = orig_target; for (size_t ii = 0; ii < num_ancestors; ++ii) { if ((ii == 0) || guideRate->has(chain[ii])) { // Apply local reductions only at the control level // (top) and for levels where we have a specified // group guide rate. if (local_reduction_level >= ii ) { target -= localReduction(chain[ii]); } // Add my reduction back at the level where it is included in the local reduction if (local_reduction_level == ii ) { target += current_rate * efficiencyFactor; } } target *= localFraction(chain[ii + 1]); } // Avoid negative target rates comming from too large local reductions. const double target_rate = std::max(1e-12, target / efficiencyFactor); double scale = 1.0; if (current_rate > 1e-12) scale = target_rate / current_rate; return std::make_pair(current_rate > target_rate, scale); } std::pair checkGroupConstraintsInj(const std::string& name, const std::string& parent, const Group& group, const WellState& wellState, const GroupState& group_state, const int reportStepIdx, const GuideRate* guideRate, const double* rates, Phase injectionPhase, const PhaseUsage& pu, const double efficiencyFactor, const Schedule& schedule, const SummaryState& summaryState, const std::vector& resv_coeff, DeferredLogger& deferred_logger) { // When called for a well ('name' is a well name), 'parent' // will be the name of 'group'. But if we recurse, 'name' and // 'parent' will stay fixed while 'group' will be higher up // in the group tree. // efficiencyfactor is the well efficiency factor for the first group the well is // part of. Later it is the accumulated factor including the group efficiency factor // of the child of group. auto currentGroupControl = group_state.injection_control(group.name(), injectionPhase); if (currentGroupControl == Group::InjectionCMode::FLD || currentGroupControl == Group::InjectionCMode::NONE) { // Return if we are not available for parent group. if (!group.injectionGroupControlAvailable(injectionPhase)) { return std::make_pair(false, 1); } // Otherwise: check production share of parent's control. const auto& parentGroup = schedule.getGroup(group.parent(), reportStepIdx); return checkGroupConstraintsInj(name, parent, parentGroup, wellState, group_state, reportStepIdx, guideRate, rates, injectionPhase, pu, efficiencyFactor * group.getGroupEfficiencyFactor(), schedule, summaryState, resv_coeff, deferred_logger); } // This can be false for FLD-controlled groups, we must therefore // check for FLD first (done above). if (!group.isInjectionGroup()) { return std::make_pair(false, 1.0); } // If we are here, we are at the topmost group to be visited in the recursion. // This is the group containing the control we will check against. double sales_target = 0; if (schedule[reportStepIdx].gconsale().has(group.name())) { const auto& gconsale = schedule[reportStepIdx].gconsale().get(group.name(), summaryState); sales_target = gconsale.sales_target; } InjectionTargetCalculator tcalc(currentGroupControl, pu, resv_coeff, group.name(), sales_target, group_state, injectionPhase, group.has_gpmaint_control(injectionPhase, currentGroupControl), deferred_logger); FractionCalculator fcalc(schedule, wellState, group_state, reportStepIdx, guideRate, tcalc.guideTargetMode(), pu, false, injectionPhase); auto localFraction = [&](const std::string& child) { return fcalc.localFraction(child, name); }; auto localReduction = [&](const std::string& group_name) { const std::vector& groupTargetReductions = group_state.injection_reduction_rates(group_name); return tcalc.calcModeRateFromRates(groupTargetReductions); }; auto localCurrentRate = [&](const std::string& group_name) { const std::vector& groupSurfaceRates = group_state.injection_surface_rates(group_name); return tcalc.calcModeRateFromRates(groupSurfaceRates); }; std::optional ctrl; if (!group.has_gpmaint_control(injectionPhase, currentGroupControl)) ctrl = group.injectionControls(injectionPhase, summaryState); const double orig_target = tcalc.groupTarget(ctrl, deferred_logger); // Assume we have a chain of groups as follows: BOTTOM -> MIDDLE -> TOP. // Then ... // TODO finish explanation. const double current_rate = tcalc.calcModeRateFromRates(rates); // Switch sign since 'rates' are negative for producers. const auto chain = groupChainTopBot(name, group.name(), schedule, reportStepIdx); // Because 'name' is the last of the elements, and not an ancestor, we subtract one below. const size_t num_ancestors = chain.size() - 1; // we need to find out the level where the current well is applied to the local reduction size_t local_reduction_level = 0; for (size_t ii = 1; ii < num_ancestors; ++ii) { const int num_gr_ctrl = groupControlledWells(schedule, wellState, group_state, reportStepIdx, chain[ii], "", /*is_producer*/ false, injectionPhase); if (guideRate->has(chain[ii], injectionPhase) && num_gr_ctrl > 0) { local_reduction_level = ii; } } // check whether guide rate is violated for (size_t ii = 1; ii < num_ancestors; ++ii) { if (guideRate->has(chain[ii], injectionPhase)) { const auto& guided_group = chain[ii]; const double grefficiency = schedule.getGroup(guided_group, reportStepIdx).getGroupEfficiencyFactor(); const double currentRateFraction = grefficiency * localCurrentRate(guided_group) / (localCurrentRate(chain[ii-1])); const double guiderateFraction = localFraction(guided_group); // we add a factor here to avoid switching due to numerical instability const double factor = 1.01; if (currentRateFraction > (guiderateFraction * factor)) { return std::make_pair(true, guiderateFraction/currentRateFraction); } } } double target = orig_target; for (size_t ii = 0; ii < num_ancestors; ++ii) { if ((ii == 0) || guideRate->has(chain[ii], injectionPhase)) { // Apply local reductions only at the control level // (top) and for levels where we have a specified // group guide rate. if (local_reduction_level >= ii ) { target -= localReduction(chain[ii]); } // Add my reduction back at the level where it is included in the local reduction if (local_reduction_level == ii ) { target += current_rate * efficiencyFactor; } } target *= localFraction(chain[ii + 1]); } // Avoid negative target rates comming from too large local reductions. const double target_rate = std::max(1e-12, target / efficiencyFactor); double scale = 1.0; if (current_rate > 1e-12) scale = target_rate / current_rate; return std::make_pair(current_rate > target_rate, scale); } template void setRegionAveragePressureCalculator(const Group& group, const Schedule& schedule, const int reportStepIdx, const FieldPropsManager& fp, const PhaseUsage& pu, std::map>& regionalAveragePressureCalculator) { for (const std::string& groupName : group.groups()) { setRegionAveragePressureCalculator( schedule.getGroup(groupName, reportStepIdx), schedule, reportStepIdx, fp, pu, regionalAveragePressureCalculator); } const auto& gpm = group.gpmaint(); if (!gpm) return; const auto& reg = gpm->region(); if (!reg) return; if (regionalAveragePressureCalculator.count(reg->first) == 0) { const std::string name = (reg->first.rfind("FIP", 0) == 0) ? reg->first : "FIP" + reg->first; const auto& fipnum = fp.get_int(name); regionalAveragePressureCalculator[reg->first] = std::make_unique(pu,fipnum); } } template void updateGuideRates(const Group& group, const Schedule& schedule, const SummaryState& summary_state, const PhaseUsage& pu, const int report_step, const double sim_time, WellState& well_state, const GroupState& group_state, const Comm& comm, GuideRate* guide_rate, std::vector& pot, Opm::DeferredLogger& deferred_logger) { guide_rate->updateGuideRateExpiration(sim_time, report_step); updateGuideRateForProductionGroups(group, schedule, pu, report_step, sim_time, well_state, group_state, comm, guide_rate, pot); updateGuideRatesForInjectionGroups(group, schedule, summary_state, pu, report_step, well_state, group_state, guide_rate, deferred_logger); updateGuideRatesForWells(schedule, pu, report_step, sim_time, well_state, comm, guide_rate); } template void updateGuideRateForProductionGroups(const Group& group, const Schedule& schedule, const PhaseUsage& pu, const int reportStepIdx, const double& simTime, WellState& wellState, const GroupState& group_state, const Comm& comm, GuideRate* guideRate, std::vector& pot) { const int np = pu.num_phases; for (const std::string& groupName : group.groups()) { std::vector thisPot(np, 0.0); const Group& groupTmp = schedule.getGroup(groupName, reportStepIdx); // Note that group effiency factors for groupTmp are applied in updateGuideRateForGroups updateGuideRateForProductionGroups(groupTmp, schedule, pu, reportStepIdx, simTime, wellState, group_state, comm, guideRate, thisPot); // accumulate group contribution from sub group unconditionally const auto currentGroupControl = group_state.production_control(groupName); if (currentGroupControl != Group::ProductionCMode::FLD && currentGroupControl != Group::ProductionCMode::NONE) { continue; } // Apply group efficiency factor for this goup auto gefac = groupTmp.getGroupEfficiencyFactor(); for (int phase = 0; phase < np; phase++) { pot[phase] += gefac*thisPot[phase]; } } for (const std::string& wellName : group.wells()) { const auto& wellTmp = schedule.getWell(wellName, reportStepIdx); const auto wefac = wellTmp.getEfficiencyFactor(); if (wellTmp.isInjector()) continue; if (wellTmp.getStatus() == Well::Status::SHUT) continue; const auto& well_index = wellState.index(wellName); if (!well_index.has_value()) // the well is not found continue; if (! wellState.wellIsOwned(well_index.value(), wellName) ) // Only sum once { continue; } const auto& ws = wellState.well(well_index.value()); // add contribution from wells unconditionally for (int phase = 0; phase < np; phase++) { pot[phase] += wefac * ws.well_potentials[phase]; } } std::array potentials{}; auto& [oilPot, gasPot, waterPot] = potentials; if (pu.phase_used[BlackoilPhases::Liquid]) oilPot = pot[pu.phase_pos[BlackoilPhases::Liquid]]; if (pu.phase_used[BlackoilPhases::Vapour]) gasPot = pot[pu.phase_pos[BlackoilPhases::Vapour]]; if (pu.phase_used[BlackoilPhases::Aqua]) waterPot = pot[pu.phase_pos[BlackoilPhases::Aqua]]; comm.sum(potentials.data(), potentials.size()); const UnitSystem& unit_system = schedule.getUnits(); oilPot = unit_system.from_si(UnitSystem::measure::liquid_surface_rate, oilPot); waterPot = unit_system.from_si(UnitSystem::measure::liquid_surface_rate, waterPot); gasPot = unit_system.from_si(UnitSystem::measure::gas_surface_rate, gasPot); guideRate->compute(group.name(), reportStepIdx, simTime, oilPot, gasPot, waterPot); } template void updateGuideRatesForWells(const Schedule& schedule, const PhaseUsage& pu, const int reportStepIdx, const double& simTime, const WellState& wellState, const Comm& comm, GuideRate* guideRate) { for (const auto& well : schedule.getWells(reportStepIdx)) { std::array potentials{}; auto& [oilpot, gaspot, waterpot] = potentials; const auto& well_index = wellState.index(well.name()); if (well_index.has_value() && wellState.wellIsOwned(well_index.value(), well.name())) { // the well is found and owned const auto& ws = wellState.well(well_index.value()); const auto& wpot = ws.well_potentials; if (pu.phase_used[BlackoilPhases::Liquid] > 0) oilpot = wpot[pu.phase_pos[BlackoilPhases::Liquid]]; if (pu.phase_used[BlackoilPhases::Vapour] > 0) gaspot = wpot[pu.phase_pos[BlackoilPhases::Vapour]]; if (pu.phase_used[BlackoilPhases::Aqua] > 0) waterpot = wpot[pu.phase_pos[BlackoilPhases::Aqua]]; } comm.sum(potentials.data(), potentials.size()); const UnitSystem& unit_system = schedule.getUnits(); oilpot = unit_system.from_si(UnitSystem::measure::liquid_surface_rate, oilpot); waterpot = unit_system.from_si(UnitSystem::measure::liquid_surface_rate, waterpot); gaspot = unit_system.from_si(UnitSystem::measure::gas_surface_rate, gaspot); guideRate->compute(well.name(), reportStepIdx, simTime, oilpot, gaspot, waterpot); } } using AvgP = RegionAverageCalculator::AverageRegionalPressure,std::vector>; using AvgPMap = std::map>; template void WellGroupHelpers::updateGpMaintTargetForGroups(const Group&, const Schedule&, const AvgPMap&, int, double, const WellState&, GroupState&); template void WellGroupHelpers::setRegionAveragePressureCalculator(const Group&, const Schedule&, const int, const FieldPropsManager&, const PhaseUsage&, AvgPMap&); template void updateGuideRateForProductionGroups(const Group& group, const Schedule& schedule, const PhaseUsage& pu, const int reportStepIdx, const double& simTime, WellState& wellState, const GroupState& group_state, const Parallel::Communication& comm, GuideRate* guideRate, std::vector& pot); template void updateGuideRatesForWells(const Schedule& schedule, const PhaseUsage& pu, const int reportStepIdx, const double& simTime, const WellState& wellState, const Parallel::Communication& comm, GuideRate* guideRate); template void updateGuideRates(const Group& group, const Schedule& schedule, const SummaryState& summary_state, const PhaseUsage& pu, const int report_step, const double sim_time, WellState& well_state, const GroupState& group_state, const Parallel::Communication& comm, GuideRate* guide_rate, std::vector& pot, DeferredLogger&); } // namespace WellGroupHelpers } // namespace Opm