/*!
* \brief Implement the temperature part of the water PVT properties.
*/
void initFromDeck(DeckConstPtr deck,
EclipseStateConstPtr eclState)
{
//////
// initialize the isothermal part
//////
isothermalPvt_ = new IsothermalPvt;
isothermalPvt_->initFromDeck(deck, eclState);
//////
// initialize the thermal part
//////
auto tables = eclState->getTableManager();
enableThermalDensity_ = deck->hasKeyword("WATDENT");
enableThermalViscosity_ = deck->hasKeyword("VISCREF");
unsigned numRegions = isothermalPvt_->numRegions();
setNumRegions(numRegions);
if (enableThermalDensity_) {
const auto& watdentKeyword = deck->getKeyword("WATDENT");
assert(watdentKeyword.size() == numRegions);
for (unsigned regionIdx = 0; regionIdx < numRegions; ++regionIdx) {
const auto& watdentRecord = watdentKeyword.getRecord(regionIdx);
watdentRefTemp_[regionIdx] = watdentRecord.getItem("REFERENCE_TEMPERATURE").getSIDouble(0);
watdentCT1_[regionIdx] = watdentRecord.getItem("EXPANSION_COEFF_LINEAR").getSIDouble(0);
watdentCT2_[regionIdx] = watdentRecord.getItem("EXPANSION_COEFF_QUADRATIC").getSIDouble(0);
}
}
if (enableThermalViscosity_) {
const auto& viscrefKeyword = deck->getKeyword("VISCREF");
const auto& watvisctTables = tables->getWatvisctTables();
assert(watvisctTables.size() == numRegions);
assert(viscrefKeyword.size() == numRegions);
for (unsigned regionIdx = 0; regionIdx < numRegions; ++ regionIdx) {
const auto& T = watvisctTables[regionIdx].getColumn("Temperature").vectorCopy();
const auto& mu = watvisctTables[regionIdx].getColumn("Viscosity").vectorCopy();
watvisctCurves_[regionIdx].setXYContainers(T, mu);
const auto& viscrefRecord = viscrefKeyword.getRecord(regionIdx);
viscrefPress_[regionIdx] = viscrefRecord.getItem("REFERENCE_PRESSURE").getSIDouble(0);
}
}
}
/*!
* \brief Initialize the parameters for dry gas using an ECL deck.
*
* This method assumes that the deck features valid DENSITY and PVDG keywords.
*/
void initFromDeck(DeckConstPtr deck, EclipseStateConstPtr eclState)
{
const auto& pvdgTables = eclState->getTableManager()->getPvdgTables();
const auto& densityKeyword = deck->getKeyword("DENSITY");
assert(pvdgTables.size() == densityKeyword.size());
size_t numRegions = pvdgTables.size();
setNumRegions(numRegions);
for (unsigned regionIdx = 0; regionIdx < numRegions; ++ regionIdx) {
Scalar rhoRefO = densityKeyword.getRecord(regionIdx).getItem("OIL").getSIDouble(0);
Scalar rhoRefG = densityKeyword.getRecord(regionIdx).getItem("GAS").getSIDouble(0);
Scalar rhoRefW = densityKeyword.getRecord(regionIdx).getItem("WATER").getSIDouble(0);
setReferenceDensities(regionIdx, rhoRefO, rhoRefG, rhoRefW);
// determine the molar masses of the components
Scalar p = 1.01325e5; // surface pressure, [Pa]
Scalar T = 273.15 + 15.56; // surface temperature, [K]
Scalar MO = 175e-3; // [kg/mol]
Scalar MG = Opm::Constants<Scalar>::R*T*rhoRefG / p; // [kg/mol], consequence of the ideal gas law
Scalar MW = 18.0e-3; // [kg/mol]
// TODO (?): the molar mass of the components can possibly specified
// explicitly in the deck.
setMolarMasses(regionIdx, MO, MG, MW);
const auto& pvdgTable = pvdgTables.getTable<PvdgTable>(regionIdx);
// say 99.97% of all time: "premature optimization is the root of all
// evil". Eclipse does this "optimization" for apparently no good reason!
std::vector<Scalar> invB(pvdgTable.numRows());
const auto& Bg = pvdgTable.getFormationFactorColumn();
for (unsigned i = 0; i < Bg.size(); ++ i) {
invB[i] = 1.0/Bg[i];
}
size_t numSamples = invB.size();
inverseGasB_[regionIdx].setXYArrays(numSamples, pvdgTable.getPressureColumn(), invB);
gasMu_[regionIdx].setXYArrays(numSamples, pvdgTable.getPressureColumn(), pvdgTable.getViscosityColumn());
}
initEnd();
}
/*!
* \brief Implement the temperature part of the gas PVT properties.
*/
void initFromDeck(DeckConstPtr deck,
EclipseStateConstPtr eclState)
{
//////
// initialize the isothermal part
//////
isothermalPvt_ = new IsothermalPvt;
isothermalPvt_->initFromDeck(deck, eclState);
//////
// initialize the thermal part
//////
auto tables = eclState->getTableManager();
enableThermalDensity_ = deck->hasKeyword("TREF");
enableThermalViscosity_ = deck->hasKeyword("GASVISCT");
unsigned numRegions = isothermalPvt_->numRegions();
setNumRegions(numRegions);
// viscosity
if (enableThermalViscosity_) {
const auto& gasvisctTables = tables->getGasvisctTables();
Opm::DeckKeywordConstPtr viscrefKeyword = deck->getKeyword("VISCREF");
int gasCompIdx = deck->getKeyword("GCOMPIDX")->getRecord(0)->getItem("GAS_COMPONENT_INDEX")->getInt(0) - 1;
std::string gasvisctColumnName = "Viscosity"+std::to_string(static_cast<long long>(gasCompIdx));
for (unsigned regionIdx = 0; regionIdx < numRegions; ++regionIdx) {
const auto& T = gasvisctTables[regionIdx].getColumn("Temperature").vectorCopy();
const auto& mu = gasvisctTables[regionIdx].getColumn(gasvisctColumnName).vectorCopy();
gasvisctCurves_[regionIdx].setXYContainers(T, mu);
}
}
// quantities required for density. note that we just always use the values
// for the first EOS. (since EOS != PVT region.)
refTemp_ = 0.0;
if (enableThermalDensity_) {
refTemp_ = deck->getKeyword("TREF")->getRecord(0)->getItem("TEMPERATURE")->getSIDouble(0);
}
}
/*!
* \brief Implement the temperature part of the oil PVT properties.
*/
void initFromDeck(DeckConstPtr deck,
EclipseStateConstPtr eclState)
{
//////
// initialize the isothermal part
//////
isothermalPvt_ = new IsothermalPvt;
isothermalPvt_->initFromDeck(deck, eclState);
//////
// initialize the thermal part
//////
auto tables = eclState->getTableManager();
enableThermalDensity_ = deck->hasKeyword("THERMEX1");
enableThermalViscosity_ = deck->hasKeyword("VISCREF");
unsigned numRegions = isothermalPvt_->numRegions();
setNumRegions(numRegions);
// viscosity
if (deck->hasKeyword("VISCREF")) {
const auto& oilvisctTables = tables->getOilvisctTables();
Opm::DeckKeywordConstPtr viscrefKeyword = deck->getKeyword("VISCREF");
assert(oilvisctTables.size() == numRegions);
assert(viscrefKeyword->size() == numRegions);
for (unsigned regionIdx = 0; regionIdx < numRegions; ++regionIdx) {
const auto& TCol = oilvisctTables[regionIdx].getColumn("Temperature").vectorCopy();
const auto& muCol = oilvisctTables[regionIdx].getColumn("Viscosity").vectorCopy();
oilvisctCurves_[regionIdx].setXYContainers(TCol, muCol);
DeckRecordConstPtr viscrefRecord = viscrefKeyword->getRecord(regionIdx);
viscrefPress_[regionIdx] = viscrefRecord->getItem("REFERENCE_PRESSURE")->getSIDouble(0);
viscrefRs_[regionIdx] = viscrefRecord->getItem("REFERENCE_RS")->getSIDouble(0);
// temperature used to calculate the reference viscosity [K]. the
// value does not really matter if the underlying PVT object really
// is isothermal...
Scalar Tref = 273.15 + 20;
// compute the reference viscosity using the isothermal PVT object.
viscRef_[regionIdx] =
isothermalPvt_->viscosity(regionIdx,
Tref,
viscrefPress_[regionIdx],
viscrefRs_[regionIdx]);
}
}
// quantities required for density. note that we just always use the values
// for the first EOS. (since EOS != PVT region.)
refTemp_ = 0.0;
if (deck->hasKeyword("THERMEX1")) {
int oilCompIdx = deck->getKeyword("OCOMPIDX")->getRecord(0)->getItem("OIL_COMPONENT_INDEX")->getInt(0) - 1;
// always use the values of the first EOS
refTemp_ = deck->getKeyword("TREF")->getRecord(0)->getItem("TEMPERATURE")->getSIDouble(oilCompIdx);
refPress_ = deck->getKeyword("PREF")->getRecord(0)->getItem("PRESSURE")->getSIDouble(oilCompIdx);
refC_ = deck->getKeyword("CREF")->getRecord(0)->getItem("COMPRESSIBILITY")->getSIDouble(oilCompIdx);
thermex1_ = deck->getKeyword("THERMEX1")->getRecord(0)->getItem("EXPANSION_COEFF")->getSIDouble(oilCompIdx);
}
}
SolventPropsAdFromDeck::SolventPropsAdFromDeck(DeckConstPtr deck,
EclipseStateConstPtr eclState,
const int number_of_cells,
const int* global_cell)
{
if (deck->hasKeyword("SOLVENT")) {
// retrieve the cell specific PVT table index from the deck
// and using the grid...
extractPvtTableIndex(cellPvtRegionIdx_, eclState, number_of_cells, global_cell);
extractTableIndex("SATNUM", eclState, number_of_cells, global_cell, cellSatNumRegionIdx_);
// surface densities
if (deck->hasKeyword("SDENSITY")) {
const auto& densityKeyword = deck->getKeyword("SDENSITY");
int numRegions = densityKeyword.size();
solvent_surface_densities_.resize(numRegions);
for (int regionIdx = 0; regionIdx < numRegions; ++regionIdx) {
solvent_surface_densities_[regionIdx]
= densityKeyword.getRecord(regionIdx).getItem("SOLVENT_DENSITY").getSIDouble(0);
}
} else {
OPM_THROW(std::runtime_error, "SDENSITY must be specified in SOLVENT runs\n");
}
auto tables = eclState->getTableManager();
// pvt
const TableContainer& pvdsTables = tables->getPvdsTables();
if (!pvdsTables.empty()) {
int numRegions = pvdsTables.size();
// resize the attributes of the object
b_.resize(numRegions);
viscosity_.resize(numRegions);
inverseBmu_.resize(numRegions);
for (int regionIdx = 0; regionIdx < numRegions; ++regionIdx) {
const Opm::PvdsTable& pvdsTable = pvdsTables.getTable<PvdsTable>(regionIdx);
const auto& press = pvdsTable.getPressureColumn();
const auto& b = pvdsTable.getFormationFactorColumn();
const auto& visc = pvdsTable.getViscosityColumn();
const int sz = b.size();
std::vector<double> inverseBmu(sz);
std::vector<double> inverseB(sz);
for (int i = 0; i < sz; ++i) {
inverseB[i] = 1.0 / b[i];
inverseBmu[i] = 1.0 / (b[i] * visc[i]);
}
b_[regionIdx] = NonuniformTableLinear<double>(press, inverseB);
viscosity_[regionIdx] = NonuniformTableLinear<double>(press, visc);
inverseBmu_[regionIdx] = NonuniformTableLinear<double>(press, inverseBmu);
}
} else {
OPM_THROW(std::runtime_error, "PVDS must be specified in SOLVENT runs\n");
}
const TableContainer& ssfnTables = tables->getSsfnTables();
// relative permeabilty multiplier
if (!ssfnTables.empty()) {
int numRegions = ssfnTables.size();
// resize the attributes of the object
krg_.resize(numRegions);
krs_.resize(numRegions);
for (int regionIdx = 0; regionIdx < numRegions; ++regionIdx) {
const Opm::SsfnTable& ssfnTable = ssfnTables.getTable<SsfnTable>(regionIdx);
// Copy data
const auto& solventFraction = ssfnTable.getSolventFractionColumn();
const auto& krg = ssfnTable.getGasRelPermMultiplierColumn();
const auto& krs = ssfnTable.getSolventRelPermMultiplierColumn();
krg_[regionIdx] = NonuniformTableLinear<double>(solventFraction, krg);
krs_[regionIdx] = NonuniformTableLinear<double>(solventFraction, krs);
}
} else {
OPM_THROW(std::runtime_error, "SSFN must be specified in SOLVENT runs\n");
}
if (deck->hasKeyword("MISCIBLE") ) {
// retrieve the cell specific Misc table index from the deck
// and using the grid...
extractTableIndex("MISCNUM", eclState, number_of_cells, global_cell, cellMiscRegionIdx_);
// misicible hydrocabon relative permeability wrt water
const TableContainer& sof2Tables = tables->getSof2Tables();
if (!sof2Tables.empty()) {
int numRegions = sof2Tables.size();
// resize the attributes of the object
krn_.resize(numRegions);
for (int regionIdx = 0; regionIdx < numRegions; ++regionIdx) {
const Opm::Sof2Table& sof2Table = sof2Tables.getTable<Sof2Table>(regionIdx);
// Copy data
// Sn = So + Sg + Ss;
const auto& sn = sof2Table.getSoColumn();
const auto& krn = sof2Table.getKroColumn();
krn_[regionIdx] = NonuniformTableLinear<double>(sn, krn);
}
} else {
OPM_THROW(std::runtime_error, "SOF2 must be specified in MISCIBLE (SOLVENT) runs\n");
}
const TableContainer& miscTables = tables->getMiscTables();
if (!miscTables.empty()) {
int numRegions = miscTables.size();
// resize the attributes of the object
misc_.resize(numRegions);
for (int regionIdx = 0; regionIdx < numRegions; ++regionIdx) {
const Opm::MiscTable& miscTable = miscTables.getTable<MiscTable>(regionIdx);
// Copy data
// solventFraction = Ss / (Ss + Sg);
const auto& solventFraction = miscTable.getSolventFractionColumn();
const auto& misc = miscTable.getMiscibilityColumn();
misc_[regionIdx] = NonuniformTableLinear<double>(solventFraction, misc);
}
} else {
OPM_THROW(std::runtime_error, "MISC must be specified in MISCIBLE (SOLVENT) runs\n");
}
const TableContainer& pmiscTables = tables->getPmiscTables();
if (!pmiscTables.empty()) {
int numRegions = pmiscTables.size();
// resize the attributes of the object
pmisc_.resize(numRegions);
for (int regionIdx = 0; regionIdx < numRegions; ++regionIdx) {
const Opm::PmiscTable& pmiscTable = pmiscTables.getTable<PmiscTable>(regionIdx);
// Copy data
const auto& po = pmiscTable.getOilPhasePressureColumn();
const auto& pmisc = pmiscTable.getMiscibilityColumn();
pmisc_[regionIdx] = NonuniformTableLinear<double>(po, pmisc);
}
}
// miscible relative permeability multipleiers
const TableContainer& msfnTables = tables->getMsfnTables();
if (!msfnTables.empty()) {
int numRegions = msfnTables.size();
// resize the attributes of the object
mkrsg_.resize(numRegions);
mkro_.resize(numRegions);
for (int regionIdx = 0; regionIdx < numRegions; ++regionIdx) {
const Opm::MsfnTable& msfnTable = msfnTables.getTable<MsfnTable>(regionIdx);
// Copy data
// Ssg = Ss + Sg;
const auto& Ssg = msfnTable.getGasPhaseFractionColumn();
const auto& krsg = msfnTable.getGasSolventRelpermMultiplierColumn();
const auto& kro = msfnTable.getOilRelpermMultiplierColumn();
mkrsg_[regionIdx] = NonuniformTableLinear<double>(Ssg, krsg);
mkro_[regionIdx] = NonuniformTableLinear<double>(Ssg, kro);
}
}
const TableContainer& sorwmisTables = tables->getSorwmisTables();
if (!sorwmisTables.empty()) {
int numRegions = sorwmisTables.size();
// resize the attributes of the object
sorwmis_.resize(numRegions);
for (int regionIdx = 0; regionIdx < numRegions; ++regionIdx) {
const Opm::SorwmisTable& sorwmisTable = sorwmisTables.getTable<SorwmisTable>(regionIdx);
// Copy data
const auto& sw = sorwmisTable.getWaterSaturationColumn();
const auto& sorwmis = sorwmisTable.getMiscibleResidualOilColumn();
sorwmis_[regionIdx] = NonuniformTableLinear<double>(sw, sorwmis);
}
}
const TableContainer& sgcwmisTables = tables->getSgcwmisTables();
if (!sgcwmisTables.empty()) {
int numRegions = sgcwmisTables.size();
// resize the attributes of the object
sgcwmis_.resize(numRegions);
for (int regionIdx = 0; regionIdx < numRegions; ++regionIdx) {
const Opm::SgcwmisTable& sgcwmisTable = sgcwmisTables.getTable<SgcwmisTable>(regionIdx);
// Copy data
const auto& sw = sgcwmisTable.getWaterSaturationColumn();
const auto& sgcwmis = sgcwmisTable.getMiscibleResidualGasColumn();
sgcwmis_[regionIdx] = NonuniformTableLinear<double>(sw, sgcwmis);
}
}
if (deck->hasKeyword("TLMIXPAR")) {
const int numRegions = deck->getKeyword("TLMIXPAR").size();
// resize the attributes of the object
mix_param_viscosity_.resize(numRegions);
mix_param_density_.resize(numRegions);
for (int regionIdx = 0; regionIdx < numRegions; ++regionIdx) {
const auto& tlmixparRecord = deck->getKeyword("TLMIXPAR").getRecord(regionIdx);
const auto& mix_params_viscosity = tlmixparRecord.getItem("TL_VISCOSITY_PARAMETER").getSIDoubleData();
mix_param_viscosity_[regionIdx] = mix_params_viscosity[0];
const auto& mix_params_density = tlmixparRecord.getItem("TL_DENSITY_PARAMETER").getSIDoubleData();
const int numDensityItems = mix_params_density.size();
if (numDensityItems == 0) {
mix_param_density_[regionIdx] = mix_param_viscosity_[regionIdx];
} else if (numDensityItems == 1) {
mix_param_density_[regionIdx] = mix_params_density[0];
} else {
OPM_THROW(std::runtime_error, "Only one value can be entered for the TL parameter pr MISC region.");
}
}
}
}
}
}
