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opm-simulators/opm/simulators/wells/VFPProdProperties.hpp
Joakim Hove 471a19e851 Pass table argument to getGFR() and getWFR()
2021-02-15 22:36:51 +01:00

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/*
Copyright 2015 SINTEF ICT, Applied Mathematics.
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 <http://www.gnu.org/licenses/>.
*/
#ifndef OPM_AUTODIFF_VFPPRODPROPERTIES_HPP_
#define OPM_AUTODIFF_VFPPRODPROPERTIES_HPP_
#include <opm/parser/eclipse/EclipseState/Schedule/VFPProdTable.hpp>
#include <opm/material/densead/Math.hpp>
#include <opm/material/densead/Evaluation.hpp>
#include <opm/simulators/wells/VFPHelpers.hpp>
#include <vector>
#include <map>
namespace Opm {
/**
* Class which linearly interpolates BHP as a function of rate, tubing head pressure,
* water fraction, gas fraction, and artificial lift for production VFP tables, and similarly
* the BHP as a function of the rate and tubing head pressure.
*/
class VFPProdProperties {
public:
VFPProdProperties() = default;
/**
* Takes *no* ownership of data.
*/
void addTable(const VFPProdTable& new_table);
/**
* Linear interpolation of bhp as a function of the input parameters given as
* Evalutions
* Each entry corresponds typically to one well.
* @param table_id Table number to use. A negative entry (e.g., -1)
* will indicate that no table is used, and the corresponding
* BHP will be calculated as a constant -1e100.
* @param aqua Water phase
* @param liquid Oil phase
* @param vapour Gas phase
* @param thp Tubing head pressure
* @param alq Artificial lift or other parameter
*
* @return The bottom hole pressure, interpolated/extrapolated linearly using
* the above parameters from the values in the input table, for each entry in the
* input ADB objects.
*/
template <class EvalWell>
EvalWell bhp(const int table_id,
const EvalWell& aqua,
const EvalWell& liquid,
const EvalWell& vapour,
const double& thp,
const double& alq) const {
//Get the table
const VFPProdTable& table = detail::getTable(m_tables, table_id);
EvalWell bhp = 0.0 * aqua;
//Find interpolation variables
EvalWell flo = detail::getFlo(table, aqua, liquid, vapour);
EvalWell wfr = detail::getWFR(table, aqua, liquid, vapour);
EvalWell gfr = detail::getGFR(table, aqua, liquid, vapour);
//First, find the values to interpolate between
//Value of FLO is negative in OPM for producers, but positive in VFP table
auto flo_i = detail::findInterpData(-flo.value(), table.getFloAxis());
auto thp_i = detail::findInterpData( thp, table.getTHPAxis()); // assume constant
auto wfr_i = detail::findInterpData( wfr.value(), table.getWFRAxis());
auto gfr_i = detail::findInterpData( gfr.value(), table.getGFRAxis());
auto alq_i = detail::findInterpData( alq, table.getALQAxis()); //assume constant
detail::VFPEvaluation bhp_val = detail::interpolate(table, flo_i, thp_i, wfr_i, gfr_i, alq_i);
bhp = (bhp_val.dwfr * wfr) + (bhp_val.dgfr * gfr) - (bhp_val.dflo * flo);
bhp.setValue(bhp_val.value);
return bhp;
}
/**
* Linear interpolation of bhp as a function of the input parameters
* @param table_id Table number to use
* @param aqua Water phase
* @param liquid Oil phase
* @param vapour Gas phase
* @param thp Tubing head pressure
* @param alq Artificial lift or other parameter
*
* @return The bottom hole pressure, interpolated/extrapolated linearly using
* the above parameters from the values in the input table.
*/
double bhp(int table_id,
const double& aqua,
const double& liquid,
const double& vapour,
const double& thp,
const double& alq) const;
/**
* Linear interpolation of thp as a function of the input parameters
* @param table_id Table number to use
* @param aqua Water phase
* @param liquid Oil phase
* @param vapour Gas phase
* @param bhp Bottom hole pressure
* @param alq Artificial lift or other parameter
*
* @return The tubing hole pressure, interpolated/extrapolated linearly using
* the above parameters from the values in the input table.
*/
double thp(int table_id,
const double& aqua,
const double& liquid,
const double& vapour,
const double& bhp,
const double& alq) const;
/**
* Returns the table associated with the ID, or throws an exception if
* the table does not exist
*/
const VFPProdTable& getTable(const int table_id) const;
/**
* Check whether there is table associated with ID
*/
bool hasTable(const int table_id) const;
/**
* Returns true if no vfp tables are in the current map
*/
bool empty() const {
return m_tables.empty();
}
/**
* Calculate the Bhp value from the THP target/constraint value
* based on inflow performance relationship and VFP curves
*/
double
calculateBhpWithTHPTarget(const std::vector<double>& ipr_a,
const std::vector<double>& ipr_b,
const double bhp_limit,
const double thp_table_id,
const double thp_limit,
const double alq,
const double dp) const;
protected:
// calculate a group bhp values with a group of flo rate values
std::vector<double> bhpwithflo(const std::vector<double>& flos,
const int table_id,
const double wfr,
const double gfr,
const double thp,
const double alq,
const double dp) const;
// Map which connects the table number with the table itself
std::map<int, std::reference_wrapper<const VFPProdTable>> m_tables;
};
} //namespace
#endif /* OPM_AUTODIFF_VFPPRODPROPERTIES_HPP_ */
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