mirror of
https://github.com/OPM/opm-simulators.git
synced 2024-11-25 10:40:21 -06:00
addressing the second part of comments form PR#1680
This commit is contained in:
parent
c4254240e2
commit
76edcc0d91
@ -42,14 +42,6 @@ SET_BOOL_PROP(EclFlowOilWaterPolymerInjectivityProblem, EnablePolymerMW, true);
|
||||
//! The indices required by the model
|
||||
// For this case, there will be two primary variables introduced for the polymer
|
||||
// polymer concentration and polymer molecular weight
|
||||
// TODO: probaby it can be better to refer to the implementation of flow_ebos_oilwater, or other two phase
|
||||
// simulators. Not sure why they make it more complicated.
|
||||
/* SET_TYPE_PROP(EclFlowOilWaterPolymerProblem, Indices,
|
||||
Ewoms::BlackOilTwoPhaseIndices< 0,
|
||||
2,
|
||||
0,
|
||||
0,
|
||||
2>); */
|
||||
SET_PROP(EclFlowOilWaterPolymerInjectivityProblem, Indices)
|
||||
{
|
||||
private:
|
||||
@ -71,7 +63,7 @@ public:
|
||||
namespace Opm {
|
||||
/* void flowEbosOilWaterPolymerInjectivitySetDeck(Deck& deck, EclipseState& eclState)
|
||||
{
|
||||
typedef TTAG(EclFlowOilWaterPolymerProblem) TypeTag;
|
||||
typedef TTAG(EclFlowOilWaterPolymerInjectivityProblem) TypeTag;
|
||||
typedef GET_PROP_TYPE(TypeTag, Vanguard) Vanguard;
|
||||
|
||||
Vanguard::setExternalDeck(&deck, &eclState);
|
||||
|
@ -19,12 +19,9 @@
|
||||
|
||||
#include <opm/parser/eclipse/Deck/Deck.hpp>
|
||||
#include <opm/parser/eclipse/EclipseState/EclipseState.hpp>
|
||||
#include <opm/parser/eclipse/EclipseState/Schedule/Schedule.hpp>
|
||||
#include <opm/parser/eclipse/EclipseState/SummaryConfig/SummaryConfig.hpp>
|
||||
|
||||
|
||||
namespace Opm {
|
||||
// void flowEbosOilWaterPolymerInjectivitySetDeck(Deck& deck, EclipseState& eclState, Schedule& schedule, SummaryConfig& summary_config);
|
||||
// void flowEbosOilWaterPolymerInjectivitySetDeck(Deck& deck, EclipseState& eclState);
|
||||
int flowEbosOilWaterPolymerInjectivityMain(int argc, char** argv);
|
||||
}
|
||||
|
||||
|
@ -94,10 +94,6 @@ namespace Opm
|
||||
// TODO: we should have indices for the well equations and well primary variables separately
|
||||
static const int Bhp = numStaticWellEq - numWellControlEq;
|
||||
|
||||
// total number of the well equations and primary variables
|
||||
// there might be extra equations be used, numWellEq will be updated during the initialization
|
||||
int numWellEq = numStaticWellEq;
|
||||
|
||||
using typename Base::Scalar;
|
||||
|
||||
|
||||
@ -226,6 +222,10 @@ namespace Opm
|
||||
using Base::perf_length_;
|
||||
using Base::bore_diameters_;
|
||||
|
||||
// total number of the well equations and primary variables
|
||||
// there might be extra equations be used, numWellEq will be updated during the initialization
|
||||
int numWellEq_ = numStaticWellEq;
|
||||
|
||||
// densities of the fluid in each perforation
|
||||
std::vector<double> perf_densities_;
|
||||
// pressure drop between different perforations
|
||||
@ -421,17 +421,23 @@ namespace Opm
|
||||
const double simulation_time, const int report_step, const bool terminal_output,
|
||||
WellState& well_state, WellTestState& welltest_state, wellhelpers::WellSwitchingLogger& logger) override;
|
||||
|
||||
EvalWell pskin(const double througput,
|
||||
// calculate the skin pressure based on water velocity, throughput and polymer concentration.
|
||||
// throughput is used to describe the formation damage during water/polymer injection.
|
||||
// calculated skin pressure will be applied to the drawdown during perforation rate calculation
|
||||
// to handle the effect from formation damage.
|
||||
EvalWell pskin(const double throuhgput,
|
||||
const EvalWell& water_velocity,
|
||||
const EvalWell& poly_inj_conc) const;
|
||||
|
||||
EvalWell pskinwater(const double througput,
|
||||
// calculate the skin pressure based on water velocity, throughput during water injection.
|
||||
EvalWell pskinwater(const double throughput,
|
||||
const EvalWell& water_velocity) const;
|
||||
|
||||
// return the injecting polymer molecular weight
|
||||
// calculate the injecting polymer molecular weight based on the througput and water velocity
|
||||
EvalWell wpolymermw(const double throughput,
|
||||
const EvalWell& water_velocity) const;
|
||||
|
||||
// handle the extra equations for polymer injectivity study
|
||||
void handleInjectivityRateAndEquations(const IntensiveQuantities& int_quants,
|
||||
const WellState& well_state,
|
||||
const int perf,
|
||||
|
@ -67,14 +67,14 @@ namespace Opm
|
||||
// counting/updating primary variable numbers
|
||||
if (this->has_polymermw && well_type_ == INJECTOR) {
|
||||
// adding a primary variable for water perforation rate per connection
|
||||
numWellEq += number_of_perforations_;
|
||||
numWellEq_ += number_of_perforations_;
|
||||
// adding a primary variable for skin pressure per connection
|
||||
numWellEq += number_of_perforations_;
|
||||
numWellEq_ += number_of_perforations_;
|
||||
}
|
||||
|
||||
// with the updated numWellEq, we can initialize the primary variables and matrices now
|
||||
primary_variables_.resize(numWellEq, 0.0);
|
||||
primary_variables_evaluation_.resize(numWellEq, {numWellEq + numEq, 0.0});
|
||||
// with the updated numWellEq_, we can initialize the primary variables and matrices now
|
||||
primary_variables_.resize(numWellEq_, 0.0);
|
||||
primary_variables_evaluation_.resize(numWellEq_, EvalWell{numWellEq_ + numEq, 0.0});
|
||||
|
||||
// setup sparsity pattern for the matrices
|
||||
//[A C^T [x = [ res
|
||||
@ -89,7 +89,7 @@ namespace Opm
|
||||
row.insert(row.index());
|
||||
}
|
||||
// the block size is run-time determined now
|
||||
invDuneD_[0][0].resize(numWellEq, numWellEq);
|
||||
invDuneD_[0][0].resize(numWellEq_, numWellEq_);
|
||||
|
||||
for (auto row = duneB_.createbegin(), end = duneB_.createend(); row!=end; ++row) {
|
||||
for (int perf = 0 ; perf < number_of_perforations_; ++perf) {
|
||||
@ -101,7 +101,7 @@ namespace Opm
|
||||
for (int perf = 0 ; perf < number_of_perforations_; ++perf) {
|
||||
const int cell_idx = well_cells_[perf];
|
||||
// the block size is run-time determined now
|
||||
duneB_[0][cell_idx].resize(numWellEq, numEq);
|
||||
duneB_[0][cell_idx].resize(numWellEq_, numEq);
|
||||
}
|
||||
|
||||
// make the C^T matrix
|
||||
@ -114,22 +114,22 @@ namespace Opm
|
||||
|
||||
for (int perf = 0; perf < number_of_perforations_; ++perf) {
|
||||
const int cell_idx = well_cells_[perf];
|
||||
duneC_[0][cell_idx].resize(numWellEq, numEq);
|
||||
duneC_[0][cell_idx].resize(numWellEq_, numEq);
|
||||
}
|
||||
|
||||
resWell_.resize(1);
|
||||
// the block size of resWell_ is also run-time determined now
|
||||
resWell_[0].resize(numWellEq);
|
||||
resWell_[0].resize(numWellEq_);
|
||||
|
||||
// resize temporary class variables
|
||||
Bx_.resize( duneB_.N() );
|
||||
for (unsigned i = 0; i < duneB_.N(); ++i) {
|
||||
Bx_[i].resize(numWellEq);
|
||||
Bx_[i].resize(numWellEq_);
|
||||
}
|
||||
|
||||
invDrw_.resize( invDuneD_.N() );
|
||||
for (unsigned i = 0; i < invDuneD_.N(); ++i) {
|
||||
invDrw_[i].resize(numWellEq);
|
||||
invDrw_[i].resize(numWellEq_);
|
||||
}
|
||||
}
|
||||
|
||||
@ -141,9 +141,9 @@ namespace Opm
|
||||
void StandardWellV<TypeTag>::
|
||||
initPrimaryVariablesEvaluation() const
|
||||
{
|
||||
for (int eqIdx = 0; eqIdx < numWellEq; ++eqIdx) {
|
||||
for (int eqIdx = 0; eqIdx < numWellEq_; ++eqIdx) {
|
||||
primary_variables_evaluation_[eqIdx] =
|
||||
EvalWell::createVariable(numWellEq + numEq, primary_variables_[eqIdx], numEq + eqIdx);
|
||||
EvalWell::createVariable(numWellEq_ + numEq, primary_variables_[eqIdx], numEq + eqIdx);
|
||||
}
|
||||
}
|
||||
|
||||
@ -249,7 +249,7 @@ namespace Opm
|
||||
}
|
||||
|
||||
// Oil fraction
|
||||
EvalWell well_fraction(numWellEq + numEq, 1.0);
|
||||
EvalWell well_fraction(numWellEq_ + numEq, 1.0);
|
||||
if (FluidSystem::phaseIsActive(FluidSystem::waterPhaseIdx)) {
|
||||
well_fraction -= primary_variables_evaluation_[WFrac];
|
||||
}
|
||||
@ -273,7 +273,7 @@ namespace Opm
|
||||
wellSurfaceVolumeFraction(const int compIdx) const
|
||||
{
|
||||
|
||||
EvalWell sum_volume_fraction_scaled(numWellEq + numEq, 0.);
|
||||
EvalWell sum_volume_fraction_scaled(numWellEq_ + numEq, 0.);
|
||||
for (int idx = 0; idx < num_components_; ++idx) {
|
||||
sum_volume_fraction_scaled += wellVolumeFractionScaled(idx);
|
||||
}
|
||||
@ -292,7 +292,7 @@ namespace Opm
|
||||
StandardWellV<TypeTag>::
|
||||
extendEval(const Eval& in) const
|
||||
{
|
||||
EvalWell out(numWellEq + numEq, in.value());
|
||||
EvalWell out(numWellEq_ + numEq, in.value());
|
||||
for(int eqIdx = 0; eqIdx < numEq;++eqIdx) {
|
||||
out.setDerivative(eqIdx, in.derivative(eqIdx));
|
||||
}
|
||||
@ -320,7 +320,7 @@ namespace Opm
|
||||
const EvalWell pressure = extendEval(fs.pressure(FluidSystem::oilPhaseIdx));
|
||||
const EvalWell rs = extendEval(fs.Rs());
|
||||
const EvalWell rv = extendEval(fs.Rv());
|
||||
std::vector<EvalWell> b_perfcells_dense(num_components_, {numWellEq + numEq, 0.0});
|
||||
std::vector<EvalWell> b_perfcells_dense(num_components_, EvalWell{numWellEq_ + numEq, 0.0});
|
||||
for (unsigned phaseIdx = 0; phaseIdx < FluidSystem::numPhases; ++phaseIdx) {
|
||||
if (!FluidSystem::phaseIsActive(phaseIdx)) {
|
||||
continue;
|
||||
@ -392,13 +392,13 @@ namespace Opm
|
||||
const EvalWell cqt_i = - Tw * (total_mob_dense * drawdown);
|
||||
|
||||
// surface volume fraction of fluids within wellbore
|
||||
std::vector<EvalWell> cmix_s(num_components_, EvalWell{numWellEq + numEq});
|
||||
std::vector<EvalWell> cmix_s(num_components_, EvalWell{numWellEq_ + numEq});
|
||||
for (int componentIdx = 0; componentIdx < num_components_; ++componentIdx) {
|
||||
cmix_s[componentIdx] = wellSurfaceVolumeFraction(componentIdx);
|
||||
}
|
||||
|
||||
// compute volume ratio between connection at standard conditions
|
||||
EvalWell volumeRatio(numWellEq + numEq, 0.);
|
||||
EvalWell volumeRatio(numWellEq_ + numEq, 0.);
|
||||
if (FluidSystem::phaseIsActive(FluidSystem::waterPhaseIdx)) {
|
||||
const unsigned waterCompIdx = Indices::canonicalToActiveComponentIndex(FluidSystem::waterCompIdx);
|
||||
volumeRatio += cmix_s[waterCompIdx] / b_perfcells_dense[waterCompIdx];
|
||||
@ -412,7 +412,7 @@ namespace Opm
|
||||
const unsigned oilCompIdx = Indices::canonicalToActiveComponentIndex(FluidSystem::oilCompIdx);
|
||||
const unsigned gasCompIdx = Indices::canonicalToActiveComponentIndex(FluidSystem::gasCompIdx);
|
||||
// Incorporate RS/RV factors if both oil and gas active
|
||||
const EvalWell d = EvalWell(numWellEq + numEq, 1.0) - rv * rs;
|
||||
const EvalWell d = EvalWell(numWellEq_ + numEq, 1.0) - rv * rs;
|
||||
|
||||
if (d.value() == 0.0) {
|
||||
OPM_THROW(Opm::NumericalIssue, "Zero d value obtained for well " << name() << " during flux calcuation"
|
||||
@ -513,10 +513,10 @@ namespace Opm
|
||||
|
||||
const int cell_idx = well_cells_[perf];
|
||||
const auto& intQuants = *(ebosSimulator.model().cachedIntensiveQuantities(cell_idx, /*timeIdx=*/ 0));
|
||||
std::vector<EvalWell> mob(num_components_, {numWellEq + numEq, 0.});
|
||||
std::vector<EvalWell> mob(num_components_, {numWellEq_ + numEq, 0.});
|
||||
getMobility(ebosSimulator, perf, mob);
|
||||
|
||||
std::vector<EvalWell> cq_s(num_components_, {numWellEq + numEq, 0.});
|
||||
std::vector<EvalWell> cq_s(num_components_, {numWellEq_ + numEq, 0.});
|
||||
double perf_dis_gas_rate = 0.;
|
||||
double perf_vap_oil_rate = 0.;
|
||||
computePerfRate(intQuants, mob, bhp, perf, allow_cf,
|
||||
@ -547,7 +547,7 @@ namespace Opm
|
||||
resWell_[0][componentIdx] -= cq_s_effective.value();
|
||||
|
||||
// assemble the jacobians
|
||||
for (int pvIdx = 0; pvIdx < numWellEq; ++pvIdx) {
|
||||
for (int pvIdx = 0; pvIdx < numWellEq_; ++pvIdx) {
|
||||
// also need to consider the efficiency factor when manipulating the jacobians.
|
||||
duneC_[0][cell_idx][pvIdx][componentIdx] -= cq_s_effective.derivative(pvIdx+numEq); // intput in transformed matrix
|
||||
invDuneD_[0][0][componentIdx][pvIdx] -= cq_s_effective.derivative(pvIdx+numEq);
|
||||
@ -576,7 +576,7 @@ namespace Opm
|
||||
|
||||
const unsigned activeCompIdx = Indices::canonicalToActiveComponentIndex(FluidSystem::solventComponentIndex(phaseIdx));
|
||||
// convert to reservoar conditions
|
||||
EvalWell cq_r_thermal(numWellEq + numEq, 0.);
|
||||
EvalWell cq_r_thermal(numWellEq_ + numEq, 0.);
|
||||
if (FluidSystem::phaseIsActive(FluidSystem::oilPhaseIdx) && FluidSystem::phaseIsActive(FluidSystem::gasPhaseIdx)) {
|
||||
|
||||
if(FluidSystem::waterPhaseIdx == phaseIdx)
|
||||
@ -635,7 +635,7 @@ namespace Opm
|
||||
|
||||
if (this->has_polymermw && well_type_ == INJECTOR) {
|
||||
// the source term related to transport of molecular weight
|
||||
// TODO: should molecular weight be a Evalution type?
|
||||
// TODO: should molecular weight be a Evalution type?
|
||||
EvalWell cq_s_polymw = cq_s_poly;
|
||||
if (well_type_ == INJECTOR) {
|
||||
const int wat_vel_index = Bhp + 1 + perf;
|
||||
@ -678,7 +678,7 @@ namespace Opm
|
||||
for (int componentIdx = 0; componentIdx < numWellConservationEq; ++componentIdx) {
|
||||
EvalWell resWell_loc = (wellSurfaceVolumeFraction(componentIdx) - F0_[componentIdx]) * volume / dt;
|
||||
resWell_loc += getQs(componentIdx) * well_efficiency_factor_;
|
||||
for (int pvIdx = 0; pvIdx < numWellEq; ++pvIdx) {
|
||||
for (int pvIdx = 0; pvIdx < numWellEq_; ++pvIdx) {
|
||||
invDuneD_[0][0][componentIdx][pvIdx] += resWell_loc.derivative(pvIdx+numEq);
|
||||
}
|
||||
resWell_[0][componentIdx] += resWell_loc.value();
|
||||
@ -708,11 +708,11 @@ namespace Opm
|
||||
StandardWellV<TypeTag>::
|
||||
assembleControlEq()
|
||||
{
|
||||
EvalWell control_eq(numWellEq + numEq, 0.);
|
||||
EvalWell control_eq(numWellEq_ + numEq, 0.);
|
||||
switch (well_controls_get_current_type(well_controls_)) {
|
||||
case THP:
|
||||
{
|
||||
std::vector<EvalWell> rates(3, {numWellEq + numEq, 0.});
|
||||
std::vector<EvalWell> rates(3, {numWellEq_ + numEq, 0.});
|
||||
if (FluidSystem::phaseIsActive(FluidSystem::waterPhaseIdx)) {
|
||||
rates[ Water ] = getQs(flowPhaseToEbosCompIdx(Water));
|
||||
}
|
||||
@ -741,7 +741,7 @@ namespace Opm
|
||||
control_eq = getWQTotal() - target_rate;
|
||||
} else if (well_type_ == PRODUCER) {
|
||||
if (target_rate != 0.) {
|
||||
EvalWell rate_for_control(numWellEq + numEq, 0.);
|
||||
EvalWell rate_for_control(numWellEq_ + numEq, 0.);
|
||||
const EvalWell& g_total = getWQTotal();
|
||||
// a variable to check if we are producing any targeting fluids
|
||||
double sum_fraction = 0.;
|
||||
@ -792,7 +792,7 @@ namespace Opm
|
||||
}
|
||||
} else {
|
||||
const EvalWell& g_total = getWQTotal();
|
||||
EvalWell rate_for_control(numWellEq + numEq, 0.); // reservoir rate
|
||||
EvalWell rate_for_control(numWellEq_ + numEq, 0.); // reservoir rate
|
||||
for (int phase = 0; phase < number_of_phases_; ++phase) {
|
||||
rate_for_control += g_total * wellVolumeFraction( flowPhaseToEbosCompIdx(phase) );
|
||||
}
|
||||
@ -807,7 +807,7 @@ namespace Opm
|
||||
// using control_eq to update the matrix and residuals
|
||||
// TODO: we should use a different index system for the well equations
|
||||
resWell_[0][Bhp] = control_eq.value();
|
||||
for (int pv_idx = 0; pv_idx < numWellEq; ++pv_idx) {
|
||||
for (int pv_idx = 0; pv_idx < numWellEq_; ++pv_idx) {
|
||||
invDuneD_[0][0][Bhp][pv_idx] = control_eq.derivative(pv_idx + numEq);
|
||||
}
|
||||
}
|
||||
@ -960,12 +960,8 @@ namespace Opm
|
||||
|
||||
const double relaxation_factor = 0.9;
|
||||
const double dx_wat_vel = dwells[0][wat_vel_index];
|
||||
|
||||
|
||||
primary_variables_[wat_vel_index] -= relaxation_factor * dx_wat_vel;
|
||||
|
||||
|
||||
|
||||
const double dx_pskin = dwells[0][pskin_index];
|
||||
primary_variables_[pskin_index] -= relaxation_factor * dx_pskin;
|
||||
}
|
||||
@ -1304,7 +1300,7 @@ namespace Opm
|
||||
std::fill(ipr_b_.begin(), ipr_b_.end(), 0.);
|
||||
|
||||
for (int perf = 0; perf < number_of_perforations_; ++perf) {
|
||||
std::vector<EvalWell> mob(num_components_, {numWellEq + numEq, 0.0});
|
||||
std::vector<EvalWell> mob(num_components_, {numWellEq_ + numEq, 0.0});
|
||||
// TODO: mabye we should store the mobility somewhere, so that we only need to calculate it one per iteration
|
||||
getMobility(ebos_simulator, perf, mob);
|
||||
|
||||
@ -1464,7 +1460,7 @@ namespace Opm
|
||||
// option 2: stick with the above IPR curve
|
||||
// we use IPR here
|
||||
std::vector<double> well_rates_bhp_limit;
|
||||
computeWellRatesWithBhp(ebos_simulator, EvalWell(numWellEq + numEq, bhp_limit), well_rates_bhp_limit);
|
||||
computeWellRatesWithBhp(ebos_simulator, EvalWell(numWellEq_ + numEq, bhp_limit), well_rates_bhp_limit);
|
||||
|
||||
const double thp = calculateThpFromBhp(well_rates_bhp_limit, bhp_limit);
|
||||
const double thp_limit = this->getTHPConstraint();
|
||||
@ -1649,7 +1645,7 @@ namespace Opm
|
||||
initPrimaryVariablesEvaluation();
|
||||
|
||||
std::vector<double> rates;
|
||||
computeWellRatesWithBhp(ebos_simulator, EvalWell(numWellEq + numEq, bhp), rates);
|
||||
computeWellRatesWithBhp(ebos_simulator, EvalWell(numWellEq_ + numEq, bhp), rates);
|
||||
|
||||
// TODO: double checke the obtained rates
|
||||
// this is another places we might obtain negative rates
|
||||
@ -1973,8 +1969,8 @@ namespace Opm
|
||||
const double tol_wells = param_.tolerance_wells_;
|
||||
const double maxResidualAllowed = param_.max_residual_allowed_;
|
||||
|
||||
std::vector<double> res(numWellEq);
|
||||
for (int eq_idx = 0; eq_idx < numWellEq; ++eq_idx) {
|
||||
std::vector<double> res(numWellEq_);
|
||||
for (int eq_idx = 0; eq_idx < numWellEq_; ++eq_idx) {
|
||||
// magnitude of the residual matters
|
||||
res[eq_idx] = std::abs(resWell_[0][eq_idx]);
|
||||
}
|
||||
@ -2010,7 +2006,7 @@ namespace Opm
|
||||
}
|
||||
|
||||
// processing the residual of the well control equation
|
||||
const double well_control_residual = res[numWellEq - 1];
|
||||
const double well_control_residual = res[numWellEq_ - 1];
|
||||
// TODO: we should have better way to specify the control equation tolerance
|
||||
double control_tolerance = 0.;
|
||||
switch(well_controls_get_current_type(well_controls_)) {
|
||||
@ -2043,27 +2039,29 @@ namespace Opm
|
||||
if (this->has_polymermw && well_type_ == INJECTOR) {
|
||||
// checking the convergence of the perforation rates
|
||||
const double wat_vel_tol = 1.e-8;
|
||||
const auto wat_vel_failure_type = CR::WellFailure::Type::MassBalance;
|
||||
for (int perf = 0; perf < number_of_perforations_; ++perf) {
|
||||
const double wat_vel_residual = res[Bhp + 1 + perf];
|
||||
if (std::isnan(wat_vel_residual)) {
|
||||
report.setWellFailed({type, CR::Severity::NotANumber, dummy_component, name()});
|
||||
report.setWellFailed({wat_vel_failure_type, CR::Severity::NotANumber, dummy_component, name()});
|
||||
} else if (wat_vel_residual > maxResidualAllowed * 10.) {
|
||||
report.setWellFailed({type, CR::Severity::TooLarge, dummy_component, name()});
|
||||
report.setWellFailed({wat_vel_failure_type, CR::Severity::TooLarge, dummy_component, name()});
|
||||
} else if (wat_vel_residual > wat_vel_tol) {
|
||||
report.setWellFailed({type, CR::Severity::Normal, dummy_component, name()});
|
||||
report.setWellFailed({wat_vel_failure_type, CR::Severity::Normal, dummy_component, name()});
|
||||
}
|
||||
}
|
||||
|
||||
// checking the convergence of the skin pressure
|
||||
const double pskin_tol = 1000.; // 100 pascal
|
||||
const double pskin_tol = 1000.; // 1000 pascal
|
||||
const auto pskin_failure_type = CR::WellFailure::Type::Pressure;
|
||||
for (int perf = 0; perf < number_of_perforations_; ++perf) {
|
||||
const double pskin_residual = res[Bhp + 1 + perf + number_of_perforations_];
|
||||
if (std::isnan(pskin_residual)) {
|
||||
report.setWellFailed({type, CR::Severity::NotANumber, dummy_component, name()});
|
||||
report.setWellFailed({pskin_failure_type, CR::Severity::NotANumber, dummy_component, name()});
|
||||
} else if (pskin_residual > maxResidualAllowed * 10.) {
|
||||
report.setWellFailed({type, CR::Severity::TooLarge, dummy_component, name()});
|
||||
report.setWellFailed({pskin_failure_type, CR::Severity::TooLarge, dummy_component, name()});
|
||||
} else if (pskin_residual > pskin_tol) {
|
||||
report.setWellFailed({type, CR::Severity::Normal, dummy_component, name()});
|
||||
report.setWellFailed({pskin_failure_type, CR::Severity::Normal, dummy_component, name()});
|
||||
}
|
||||
}
|
||||
}
|
||||
@ -2139,7 +2137,7 @@ namespace Opm
|
||||
// We assemble the well equations, then we check the convergence,
|
||||
// which is why we do not put the assembleWellEq here.
|
||||
BVectorWell dx_well(1);
|
||||
dx_well[0].resize(numWellEq);
|
||||
dx_well[0].resize(numWellEq_);
|
||||
invDuneD_.mv(resWell_, dx_well);
|
||||
|
||||
updateWellState(dx_well, well_state);
|
||||
@ -2253,7 +2251,7 @@ namespace Opm
|
||||
if (!this->isOperable()) return;
|
||||
|
||||
BVectorWell xw(1);
|
||||
xw[0].resize(numWellEq);
|
||||
xw[0].resize(numWellEq_);
|
||||
|
||||
recoverSolutionWell(x, xw);
|
||||
updateWellState(xw, well_state);
|
||||
@ -2279,10 +2277,10 @@ namespace Opm
|
||||
const int cell_idx = well_cells_[perf];
|
||||
const auto& intQuants = *(ebosSimulator.model().cachedIntensiveQuantities(cell_idx, /*timeIdx=*/ 0));
|
||||
// flux for each perforation
|
||||
std::vector<EvalWell> mob(num_components_, {numWellEq + numEq, 0.});
|
||||
std::vector<EvalWell> mob(num_components_, {numWellEq_ + numEq, 0.});
|
||||
getMobility(ebosSimulator, perf, mob);
|
||||
|
||||
std::vector<EvalWell> cq_s(num_components_, {numWellEq + numEq, 0.});
|
||||
std::vector<EvalWell> cq_s(num_components_, {numWellEq_ + numEq, 0.});
|
||||
double perf_dis_gas_rate = 0.;
|
||||
double perf_vap_oil_rate = 0.;
|
||||
computePerfRate(intQuants, mob, bhp, perf, allow_cf,
|
||||
@ -2367,7 +2365,7 @@ namespace Opm
|
||||
|
||||
converged = std::abs(old_bhp - bhp) < bhp_tolerance;
|
||||
|
||||
computeWellRatesWithBhp(ebosSimulator, EvalWell(numWellEq + numEq, bhp), potentials);
|
||||
computeWellRatesWithBhp(ebosSimulator, EvalWell(numWellEq_ + numEq, bhp), potentials);
|
||||
|
||||
// checking whether the potentials have valid values
|
||||
for (const double value : potentials) {
|
||||
@ -2425,7 +2423,7 @@ namespace Opm
|
||||
if ( !wellHasTHPConstraints() ) {
|
||||
assert(std::abs(bhp) != std::numeric_limits<double>::max());
|
||||
|
||||
computeWellRatesWithBhp(ebosSimulator, EvalWell(numWellEq + numEq, bhp), well_potentials);
|
||||
computeWellRatesWithBhp(ebosSimulator, EvalWell(numWellEq_ + numEq, bhp), well_potentials);
|
||||
} else {
|
||||
// the well has a THP related constraint
|
||||
// checking whether a well is newly added, it only happens at the beginning of the report step
|
||||
@ -2437,7 +2435,7 @@ namespace Opm
|
||||
}
|
||||
} else {
|
||||
// We need to generate a reasonable rates to start the iteration process
|
||||
computeWellRatesWithBhp(ebosSimulator, EvalWell(numWellEq + numEq, bhp), well_potentials);
|
||||
computeWellRatesWithBhp(ebosSimulator, EvalWell(numWellEq_ + numEq, bhp), well_potentials);
|
||||
for (double& value : well_potentials) {
|
||||
// make the value a little safer in case the BHP limits are default ones
|
||||
// TODO: a better way should be a better rescaling based on the investigation of the VFP table.
|
||||
@ -2543,12 +2541,12 @@ namespace Opm
|
||||
primary_variables_[Bhp] = well_state.bhp()[index_of_well_];
|
||||
|
||||
// other primary variables related to polymer injectio
|
||||
if (this->has_polymermw && well_type_ == INJECTOR) {
|
||||
if (this->has_polymermw && well_type_ == INJECTOR) {
|
||||
for (int perf = 0; perf < number_of_perforations_; ++perf) {
|
||||
primary_variables_[Bhp + 1 + perf] = well_state.perfWaterVelocity()[first_perf_ + perf];
|
||||
primary_variables_[Bhp + 1 + number_of_perforations_ + perf] = well_state.perfSkinPressure()[first_perf_ + perf];
|
||||
}
|
||||
}
|
||||
}
|
||||
}
|
||||
|
||||
|
||||
@ -2685,7 +2683,7 @@ namespace Opm
|
||||
const bool allow_cf = getAllowCrossFlow() || openCrossFlowAvoidSingularity(ebos_simulator);
|
||||
const EvalWell& bhp = getBhp();
|
||||
|
||||
std::vector<EvalWell> cq_s(num_components_, {numWellEq + numEq, 0.});
|
||||
std::vector<EvalWell> cq_s(num_components_, {numWellEq_ + numEq, 0.});
|
||||
double perf_dis_gas_rate = 0.;
|
||||
double perf_vap_oil_rate = 0.;
|
||||
computePerfRate(int_quant, mob, bhp, perf, allow_cf,
|
||||
@ -2927,16 +2925,16 @@ namespace Opm
|
||||
{
|
||||
if (!this->has_polymermw) {
|
||||
OPM_THROW(std::runtime_error, "Polymermw is not activated, "
|
||||
"while injecting skin pressure is requested" << name());
|
||||
"while injecting skin pressure is requested for well " << name());
|
||||
}
|
||||
const int water_table_id = well_ecl_->getPolymerProperties(current_step_).m_skprwattable;
|
||||
const int water_table_id = well_ecl_->getPolymerProperties(current_step_).m_skprwattable;
|
||||
if (water_table_id <= 0) {
|
||||
OPM_THROW(std::runtime_error, "Unused SKPRWAT table id used for well " << name());
|
||||
}
|
||||
const auto& water_table_func = PolymerModule::getSkprwatTable(water_table_id);
|
||||
const EvalWell throughput_eval(numWellEq + numEq, throughput);
|
||||
const EvalWell throughput_eval(numWellEq_ + numEq, throughput);
|
||||
// the skin pressure when injecting water, which also means the polymer concentration is zero
|
||||
EvalWell pskin_water(numWellEq + numEq, 0.0);
|
||||
EvalWell pskin_water(numWellEq_ + numEq, 0.0);
|
||||
water_table_func.eval(throughput_eval, water_velocity, pskin_water);
|
||||
return pskin_water;
|
||||
}
|
||||
@ -2954,11 +2952,11 @@ namespace Opm
|
||||
{
|
||||
if (!this->has_polymermw) {
|
||||
OPM_THROW(std::runtime_error, "Polymermw is not activated, "
|
||||
"while injecting skin pressure is requested" << name());
|
||||
"while injecting skin pressure is requested for well " << name());
|
||||
}
|
||||
const double sign = water_velocity >= 0. ? 1.0 : -1.0;
|
||||
const EvalWell water_velocity_abs = Opm::abs(water_velocity);
|
||||
if (poly_inj_conc == 0.) {
|
||||
if (poly_inj_conc == 0.) {
|
||||
return sign * pskinwater(throughput, water_velocity_abs);
|
||||
}
|
||||
const int polymer_table_id = well_ecl_->getPolymerProperties(current_step_).m_skprpolytable;
|
||||
@ -2967,9 +2965,9 @@ namespace Opm
|
||||
}
|
||||
const auto& skprpolytable = PolymerModule::getSkprpolyTable(polymer_table_id);
|
||||
const double reference_concentration = skprpolytable.refConcentration;
|
||||
const EvalWell throughput_eval(numWellEq + numEq, throughput);
|
||||
const EvalWell throughput_eval(numWellEq_ + numEq, throughput);
|
||||
// the skin pressure when injecting water, which also means the polymer concentration is zero
|
||||
EvalWell pskin_poly(numWellEq + numEq, 0.0);
|
||||
EvalWell pskin_poly(numWellEq_ + numEq, 0.0);
|
||||
skprpolytable.table_func.eval(throughput_eval, water_velocity_abs, pskin_poly);
|
||||
if (poly_inj_conc == reference_concentration) {
|
||||
return sign * pskin_poly;
|
||||
@ -2992,16 +2990,16 @@ namespace Opm
|
||||
{
|
||||
if (!this->has_polymermw) {
|
||||
OPM_THROW(std::runtime_error, "Polymermw is not activated, "
|
||||
"while injecting polymer molecular weight is requested" << name());
|
||||
"while injecting polymer molecular weight is requested for well " << name());
|
||||
}
|
||||
const int table_id = well_ecl_->getPolymerProperties(current_step_).m_plymwinjtable;
|
||||
const auto& table_func = PolymerModule::getPlymwinjTable(table_id);
|
||||
const EvalWell throughput_eval(numWellEq + numEq, throughput);
|
||||
EvalWell molecular_weight(numWellEq + numEq, 0.);
|
||||
const EvalWell throughput_eval(numWellEq_ + numEq, throughput);
|
||||
EvalWell molecular_weight(numWellEq_ + numEq, 0.);
|
||||
if (wpolymer() == 0.) { // not injecting polymer
|
||||
return molecular_weight;
|
||||
}
|
||||
table_func.eval(throughput_eval, Opm::abs(water_velocity), molecular_weight);
|
||||
table_func.eval(throughput_eval, Opm::abs(water_velocity), molecular_weight);
|
||||
return molecular_weight;
|
||||
}
|
||||
|
||||
@ -3053,7 +3051,7 @@ namespace Opm
|
||||
const double throughput = well_state.perfThroughput()[first_perf_ + perf];
|
||||
const int pskin_index = Bhp + 1 + number_of_perforations_ + perf;
|
||||
|
||||
EvalWell poly_conc(numWellEq + numEq, 0.0);
|
||||
EvalWell poly_conc(numWellEq_ + numEq, 0.0);
|
||||
poly_conc.setValue(wpolymer());
|
||||
|
||||
// equation for the skin pressure
|
||||
@ -3061,7 +3059,7 @@ namespace Opm
|
||||
- pskin(throughput, primary_variables_evaluation_[wat_vel_index], poly_conc);
|
||||
|
||||
resWell_[0][pskin_index] = eq_pskin.value();
|
||||
for (int pvIdx = 0; pvIdx < numWellEq; ++pvIdx) {
|
||||
for (int pvIdx = 0; pvIdx < numWellEq_; ++pvIdx) {
|
||||
invDuneD_[0][0][wat_vel_index][pvIdx] = eq_wat_vel.derivative(pvIdx+numEq);
|
||||
invDuneD_[0][0][pskin_index][pvIdx] = eq_pskin.derivative(pvIdx+numEq);
|
||||
}
|
||||
|
Loading…
Reference in New Issue
Block a user