mirror of
https://github.com/OPM/opm-simulators.git
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246 lines
8.7 KiB
C++
246 lines
8.7 KiB
C++
/*
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Copyright 2017 TNO - Heat Transfer & Fluid Dynamics, Modelling & Optimization of the Subsurface
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Copyright 2017 Statoil ASA.
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This file is part of the Open Porous Media project (OPM).
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OPM is free software: you can redistribute it and/or modify
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it under the terms of the GNU General Public License as published by
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the Free Software Foundation, either version 3 of the License, or
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(at your option) any later version.
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OPM is distributed in the hope that it will be useful,
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but WITHOUT ANY WARRANTY; without even the implied warranty of
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MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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GNU General Public License for more details.
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You should have received a copy of the GNU General Public License
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along with OPM. If not, see <http://www.gnu.org/licenses/>.
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*/
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#ifndef OPM_AQUIFERCT_HEADER_INCLUDED
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#define OPM_AQUIFERCT_HEADER_INCLUDED
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#include <opm/simulators/aquifers/AquiferAnalytical.hpp>
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#include <opm/output/data/Aquifer.hpp>
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#include <exception>
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#include <memory>
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#include <stdexcept>
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#include <utility>
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namespace Opm
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{
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template <typename TypeTag>
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class AquiferCarterTracy : public AquiferAnalytical<TypeTag>
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{
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public:
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using Base = AquiferAnalytical<TypeTag>;
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using typename Base::BlackoilIndices;
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using typename Base::ElementContext;
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using typename Base::Eval;
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using typename Base::FluidState;
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using typename Base::FluidSystem;
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using typename Base::IntensiveQuantities;
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using typename Base::RateVector;
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using typename Base::Scalar;
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using typename Base::Simulator;
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using typename Base::ElementMapper;
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AquiferCarterTracy(const std::vector<Aquancon::AquancCell>& connections,
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const Simulator& ebosSimulator,
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const AquiferCT::AQUCT_data& aquct_data)
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: Base(aquct_data.aquiferID, connections, ebosSimulator)
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, aquct_data_(aquct_data)
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{}
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void endTimeStep() override
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{
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for (const auto& q : this->Qai_) {
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this->W_flux_ += q * this->ebos_simulator_.timeStepSize();
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}
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this->fluxValue_ = this->W_flux_.value();
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const auto& comm = this->ebos_simulator_.vanguard().grid().comm();
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comm.sum(&this->fluxValue_, 1);
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}
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data::AquiferData aquiferData() const override
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{
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data::AquiferData data;
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data.aquiferID = this->aquiferID();
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// TODO: not sure how to get this pressure value yet
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data.pressure = this->pa0_;
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data.fluxRate = 0.;
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for (const auto& q : this->Qai_) {
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data.fluxRate += q.value();
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}
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data.volume = this->W_flux_.value();
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data.initPressure = this->pa0_;
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auto* aquCT = data.typeData.template create<data::AquiferType::CarterTracy>();
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aquCT->dimensionless_time = this->dimensionless_time_;
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aquCT->dimensionless_pressure = this->dimensionless_pressure_;
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aquCT->influxConstant = this->aquct_data_.influxConstant();
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if (!this->co2store_()) {
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aquCT->timeConstant = this->aquct_data_.timeConstant();
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aquCT->waterDensity = this->aquct_data_.waterDensity();
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aquCT->waterViscosity = this->aquct_data_.waterViscosity();
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} else {
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aquCT->waterDensity = this->rhow_;
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aquCT->timeConstant = this->Tc_;
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const auto x = this->aquct_data_.porosity * this->aquct_data_.total_compr * this->aquct_data_.inner_radius * this->aquct_data_.inner_radius;
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aquCT->waterViscosity = this->Tc_ * this->aquct_data_.permeability / x;
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}
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return data;
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}
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protected:
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// Variables constants
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AquiferCT::AQUCT_data aquct_data_;
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Scalar beta_; // Influx constant
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// TODO: it is possible it should be a AD variable
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Scalar fluxValue_{0}; // value of flux
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Scalar dimensionless_time_{0};
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Scalar dimensionless_pressure_{0};
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void assignRestartData(const data::AquiferData& xaq) override
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{
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this->fluxValue_ = xaq.volume;
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this->rhow_ = this->aquct_data_.waterDensity();
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}
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std::pair<Scalar, Scalar>
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getInfluenceTableValues(const Scalar td_plus_dt)
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{
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// We use the opm-common numeric linear interpolator
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this->dimensionless_pressure_ =
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linearInterpolation(this->aquct_data_.dimensionless_time,
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this->aquct_data_.dimensionless_pressure,
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this->dimensionless_time_);
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const auto PItd =
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linearInterpolation(this->aquct_data_.dimensionless_time,
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this->aquct_data_.dimensionless_pressure,
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td_plus_dt);
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const auto PItdprime =
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linearInterpolationDerivative(this->aquct_data_.dimensionless_time,
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this->aquct_data_.dimensionless_pressure,
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td_plus_dt);
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return std::make_pair(PItd, PItdprime);
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}
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Scalar dpai(const int idx) const
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{
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const auto gdz =
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this->gravity_() * (this->cell_depth_.at(idx) - this->aquiferDepth());
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const auto dp = this->pa0_ + this->rhow_*gdz
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- this->pressure_previous_.at(idx);
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return dp;
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}
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// This function implements Eqs 5.8 and 5.9 of the EclipseTechnicalDescription
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std::pair<Scalar, Scalar>
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calculateEqnConstants(const int idx, const Simulator& simulator)
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{
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const Scalar td_plus_dt = (simulator.timeStepSize() + simulator.time()) / this->Tc_;
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this->dimensionless_time_ = simulator.time() / this->Tc_;
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const auto [PItd, PItdprime] = this->getInfluenceTableValues(td_plus_dt);
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const auto denom = this->Tc_ * (PItd - this->dimensionless_time_*PItdprime);
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const auto a = (this->beta_*dpai(idx) - this->fluxValue_*PItdprime) / denom;
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const auto b = this->beta_ / denom;
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return std::make_pair(a, b);
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}
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std::size_t pvtRegionIdx() const
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{
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return this->aquct_data_.pvttableID - 1;
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}
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// This function implements Eq 5.7 of the EclipseTechnicalDescription
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inline void calculateInflowRate(int idx, const Simulator& simulator) override
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{
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const auto [a, b] = this->calculateEqnConstants(idx, simulator);
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this->Qai_.at(idx) = this->alphai_.at(idx) *
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(a - b*(this->pressure_current_.at(idx) - this->pressure_previous_.at(idx)));
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}
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inline void calculateAquiferConstants() override
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{
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if(this->co2store_()) {
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const auto press = this->aquct_data_.initial_pressure.value();
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Scalar temp = FluidSystem::reservoirTemperature();
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if (this->aquct_data_.initial_temperature.has_value())
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temp = this->aquct_data_.initial_temperature.value();
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Scalar rs = 0.0; // no dissolved CO2
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Scalar waterViscosity = FluidSystem::oilPvt().viscosity(pvtRegionIdx(), temp, press, rs);
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const auto x = this->aquct_data_.porosity * this->aquct_data_.total_compr * this->aquct_data_.inner_radius * this->aquct_data_.inner_radius;
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this->Tc_ = waterViscosity * x / this->aquct_data_.permeability;
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} else {
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this->Tc_ = this->aquct_data_.timeConstant();
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}
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this->beta_ = this->aquct_data_.influxConstant();
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}
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inline void calculateAquiferCondition() override
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{
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if (this->solution_set_from_restart_) {
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return;
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}
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if (! this->aquct_data_.initial_pressure.has_value()) {
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this->aquct_data_.initial_pressure =
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this->calculateReservoirEquilibrium();
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const auto& tables = this->ebos_simulator_.vanguard()
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.eclState().getTableManager();
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this->aquct_data_.finishInitialisation(tables);
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}
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this->pa0_ = this->aquct_data_.initial_pressure.value();
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if (this->aquct_data_.initial_temperature.has_value())
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this->Ta0_ = this->aquct_data_.initial_temperature.value();
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if(this->co2store_()) {
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const auto press = this->aquct_data_.initial_pressure.value();
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Scalar temp = FluidSystem::reservoirTemperature();
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if (this->aquct_data_.initial_temperature.has_value())
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temp = this->aquct_data_.initial_temperature.value();
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Scalar rs = 0.0; // no dissolved CO2
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Scalar waterDensity = FluidSystem::oilPvt().inverseFormationVolumeFactor(pvtRegionIdx(), temp, press, rs)
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* FluidSystem::oilPvt().oilReferenceDensity(pvtRegionIdx());
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this->rhow_ = waterDensity;
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} else {
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this->rhow_ = this->aquct_data_.waterDensity();
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}
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}
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virtual Scalar aquiferDepth() const override
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{
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return this->aquct_data_.datum_depth;
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}
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}; // class AquiferCarterTracy
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} // namespace Opm
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#endif
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