opm-simulators/opm/core/WellsGroup.cpp
2012-04-23 13:49:53 +02:00

491 lines
17 KiB
C++

/*
* File: WellsGroup.cpp
* Author: kjetilo
*
* Created on March 27, 2012, 9:27 AM
*/
#include <opm/core/WellsGroup.hpp>
#include <cmath>
#include <opm/core/newwells.h>
namespace Opm
{
WellsGroupInterface::WellsGroupInterface(const std::string& myname,
ProductionSpecification prod_spec,
InjectionSpecification inje_spec)
: parent_(NULL),
name_(myname),
production_specification_(prod_spec),
injection_specification_(inje_spec)
{
}
WellsGroupInterface::~WellsGroupInterface()
{
}
const WellsGroupInterface* WellsGroupInterface::getParent() const
{
return parent_;
}
const std::string& WellsGroupInterface::name()
{
return name_;
}
WellsGroup::WellsGroup(const std::string& myname,
ProductionSpecification prod_spec,
InjectionSpecification inj_spec)
: WellsGroupInterface(myname, prod_spec, inj_spec)
{
}
bool WellsGroupInterface::isLeafNode() const
{
return false;
}
void WellsGroupInterface::setParent(WellsGroupInterface* parent)
{
parent_ = parent;
}
const ProductionSpecification& WellsGroupInterface::prodSpec() const
{
return production_specification_;
}
/// Injection specifications for the well or well group.
const InjectionSpecification& WellsGroupInterface::injSpec() const
{
return injection_specification_;
}
/// Production specifications for the well or well group.
ProductionSpecification& WellsGroupInterface::prodSpec()
{
return production_specification_;
}
/// Injection specifications for the well or well group.
InjectionSpecification& WellsGroupInterface::injSpec()
{
return injection_specification_;
}
WellsGroupInterface* WellsGroup::findGroup(std::string name_of_node)
{
if (name() == name_of_node) {
return this;
} else {
for (size_t i = 0; i < children_.size(); i++) {
WellsGroupInterface* result = children_[i]->findGroup(name_of_node);
if (result) {
return result;
}
}
// Not found in this node.
return NULL;
}
}
void WellsGroup::calculateGuideRates()
{
double guide_rate_sum = 0.0;
for(size_t i = 0; i < children_.size(); i++) {
if(children_[i]->isLeafNode()) {
guide_rate_sum += children_[i]->prodSpec().guide_rate_;
}
else
{
children_[i]->calculateGuideRates();
}
}
if(guide_rate_sum != 0.0) {
for(size_t i = 0; i < children_.size(); i++) {
children_[i]->prodSpec().guide_rate_ /= guide_rate_sum;
}
}
}
void WellsGroup::conditionsMet(const std::vector<double>& well_bhp, const std::vector<double>& well_rate,
const UnstructuredGrid& grid, const std::vector<double>& saturations,
const struct Wells* wells, int index_of_well, WellControlResult& result,
double epsilon)
{
if (parent_ != NULL) {
(static_cast<WellsGroup*> (parent_))->conditionsMet(well_bhp,
well_rate,grid, saturations, wells, index_of_well, result, epsilon);
}
int number_of_leaf_nodes = numberOfLeafNodes();
double bhp_target = 1e100;
double rate_target = 1e100;
switch(wells->type[index_of_well]) {
case INJECTOR:
{
const InjectionSpecification& inje_spec = injSpec();
bhp_target = inje_spec.BHP_limit_ / number_of_leaf_nodes;
rate_target = inje_spec.fluid_volume_max_rate_ / number_of_leaf_nodes;
break;
}
case PRODUCER:
{
const ProductionSpecification& prod_spec = prodSpec();
bhp_target = prod_spec.BHP_limit_ / number_of_leaf_nodes;
rate_target = prod_spec.fluid_volume_max_rate_ / number_of_leaf_nodes;
break;
}
}
if (well_bhp[index_of_well] - bhp_target > epsilon) {
std::cout << "BHP not met" << std::endl;
std::cout << "BHP limit was " << bhp_target << std::endl;
std::cout << "Actual bhp was " << well_bhp[index_of_well] << std::endl;
ExceedInformation info;
info.group_name_ = name();
info.surplus_ = well_bhp[index_of_well] - bhp_target;
info.well_index_ = index_of_well;
result.bhp_.push_back(info);
}
if(well_rate[index_of_well] - rate_target > epsilon) {
std::cout << "well_rate not met" << std::endl;
std::cout << "target = " << rate_target << ", well_rate[index_of_well] = " << well_rate[index_of_well] << std::endl;
std::cout << "Group name = " << name() << std::endl;
ExceedInformation info;
info.group_name_ = name();
info.surplus_ = well_rate[index_of_well] - rate_target;
info.well_index_ = index_of_well;
result.fluid_rate_.push_back(info);
}
}
void WellsGroup::addChild(std::tr1::shared_ptr<WellsGroupInterface> child)
{
children_.push_back(child);
}
int WellsGroup::numberOfLeafNodes() {
// This could probably use some caching, but seeing as how the number of
// wells is relatively small, we'll do without for now.
int sum = 0;
for(size_t i = 0; i < children_.size(); i++) {
sum += children_[i]->numberOfLeafNodes();
}
return sum;
}
WellNode::WellNode(const std::string& myname,
ProductionSpecification prod_spec,
InjectionSpecification inj_spec)
: WellsGroupInterface(myname, prod_spec, inj_spec)
{
}
void WellNode::conditionsMet(const std::vector<double>& well_bhp, const std::vector<double>& well_rate,
const UnstructuredGrid& grid, const std::vector<double>& saturations,
WellControlResult& result, double epsilon)
{
if (parent_ != NULL) {
(static_cast<WellsGroup*> (parent_))->conditionsMet(well_bhp,
well_rate,
grid,
saturations,
wells_,
self_index_,
result,
epsilon);
}
// Check for self:
if (wells_->type[self_index_] == PRODUCER) {
double bhp_diff = well_bhp[self_index_] - prodSpec().BHP_limit_;
double rate_diff = well_rate[self_index_] - prodSpec().fluid_volume_max_rate_;
if(bhp_diff > epsilon) {
std::cout << "BHP exceeded, bhp_diff = " << bhp_diff << std::endl;
std::cout << "BHP_limit = " << prodSpec().BHP_limit_ << std::endl;
std::cout << "BHP = " << well_bhp[self_index_] << std::endl;
ExceedInformation info;
info.group_name_ = name();
info.surplus_ = bhp_diff;
info.well_index_ = self_index_;
result.bhp_.push_back(info);
}
if(rate_diff > epsilon) {
ExceedInformation info;
info.group_name_ = name();
info.surplus_ = rate_diff;
info.well_index_ = self_index_;
result.fluid_rate_.push_back(info);
std::cout << "Rate exceeded, rate_diff = " << rate_diff << std::endl;
}
} else {
double bhp_diff = well_bhp[self_index_] - injSpec().BHP_limit_;
double rate_diff = well_rate[self_index_] - injSpec().fluid_volume_max_rate_;
if(bhp_diff > epsilon) {
std::cout << "BHP exceeded, bhp_diff = " << bhp_diff<<std::endl;
ExceedInformation info;
info.group_name_ = name();
info.surplus_ = bhp_diff;
info.well_index_ = self_index_;
result.bhp_.push_back(info);
}
if(rate_diff > epsilon) {
std::cout << "Flow diff exceeded, flow_diff = " << rate_diff << std::endl;
ExceedInformation info;
info.group_name_ = name();
info.surplus_ = rate_diff;
info.well_index_ = self_index_;
result.fluid_rate_.push_back(info);
}
}
}
WellsGroupInterface* WellNode::findGroup(std::string name_of_node)
{
if (name() == name_of_node) {
return this;
} else {
return NULL;
}
}
bool WellNode::isLeafNode() const
{
return true;
}
void WellNode::setWellsPointer(const struct Wells* wells, int self_index)
{
wells_ = wells;
self_index_ = self_index;
}
void WellNode::calculateGuideRates()
{
// Empty
}
int WellNode::numberOfLeafNodes()
{
return 1;
}
namespace
{
SurfaceComponent toSurfaceComponent(std::string type)
{
if (type == "OIL") {
return OIL;
}
if (type == "WATER") {
return WATER;
}
if (type == "GAS") {
return GAS;
}
THROW("Unknown type " << type << ", could not convert to SurfaceComponent");
}
InjectionSpecification::ControlMode toInjectionControlMode(std::string type)
{
if (type == "NONE") {
return InjectionSpecification::NONE;
}
if (type == "ORAT") {
return InjectionSpecification::ORAT;
}
if (type == "REIN") {
return InjectionSpecification::REIN;
}
if (type == "RESV") {
return InjectionSpecification::RESV;
}
if (type == "VREP") {
return InjectionSpecification::VREP;
}
if (type == "WGRA") {
return InjectionSpecification::WGRA;
}
if (type == "FLD") {
return InjectionSpecification::FLD;
}
if (type == "GRUP") {
return InjectionSpecification::GRUP;
}
THROW("Unknown type " << type << ", could not convert to ControlMode.");
}
ProductionSpecification::ControlMode toProductionControlMode(std::string type)
{
if (type == "NONE") {
return ProductionSpecification::NONE_CM;
}
if (type == "ORAT") {
return ProductionSpecification::ORAT;
}
if (type == "LRAT") {
return ProductionSpecification::LRAT;
}
if (type == "REIN") {
return ProductionSpecification::REIN;
}
if (type == "RESV") {
return ProductionSpecification::RESV;
}
if (type == "VREP") {
return ProductionSpecification::VREP;
}
if (type == "WGRA") {
return ProductionSpecification::WGRA;
}
if (type == "FLD") {
return ProductionSpecification::FLD;
}
if (type == "GRUP") {
return ProductionSpecification::GRUP;
}
if (type == "BHP") {
return ProductionSpecification::BHP;
}
THROW("Unknown type " << type << ", could not convert to ControlMode.");
}
ProductionSpecification::Procedure toProductionProcedure(std::string type)
{
if (type == "NONE") {
return ProductionSpecification::NONE_P;
}
if (type == "RATE") {
return ProductionSpecification::RATE;
}
if (type == "WELL") {
return ProductionSpecification::WELL;
}
THROW("Unknown type " << type << ", could not convert to ControlMode.");
}
} // anonymous namespace
std::tr1::shared_ptr<WellsGroupInterface> createWellsGroup(std::string name, const EclipseGridParser& deck)
{
std::tr1::shared_ptr<WellsGroupInterface> return_value;
// First we need to determine whether it's a group or just a well:
bool isWell = false;
if (deck.hasField("WELSPECS")) {
WELSPECS wspecs = deck.getWELSPECS();
for (size_t i = 0; i < wspecs.welspecs.size(); i++) {
if (wspecs.welspecs[i].name_ == name) {
isWell = true;
break;
}
}
}
// For now, assume that if it isn't a well, it's a group
if (isWell) {
InjectionSpecification injection_specification;
if (deck.hasField("WCONINJE")) {
WCONINJE wconinje = deck.getWCONINJE();
for (size_t i = 0; i < wconinje.wconinje.size(); i++) {
if (wconinje.wconinje[i].well_ == name) {
WconinjeLine line = wconinje.wconinje[i];
injection_specification.BHP_limit_ = line.BHP_limit_;
injection_specification.injector_type_ = toSurfaceComponent(line.injector_type_);
injection_specification.control_mode_ = toInjectionControlMode(line.control_mode_);
injection_specification.surface_flow_max_rate_ = line.surface_flow_max_rate_;
injection_specification.fluid_volume_max_rate_ = line.fluid_volume_max_rate_;
}
}
}
ProductionSpecification production_specification;
if (deck.hasField("WCONPROD")) {
WCONPROD wconprod = deck.getWCONPROD();
std::cout << wconprod.wconprod.size() << std::endl;
for (size_t i = 0; i < wconprod.wconprod.size(); i++) {
if (wconprod.wconprod[i].well_ == name) {
WconprodLine line = wconprod.wconprod[i];
production_specification.BHP_limit_ = line.BHP_limit_;
production_specification.fluid_volume_max_rate_ = line.fluid_volume_max_rate_;
production_specification.oil_max_rate_ = line.oil_max_rate_;
production_specification.control_mode_ = toProductionControlMode(line.control_mode_);
production_specification.water_production_target_ = line.water_max_rate_;
}
}
}
return_value.reset(new WellNode(name, production_specification, injection_specification));
} else {
InjectionSpecification injection_specification;
if (deck.hasField("GCONINJE")) {
GCONINJE gconinje = deck.getGCONINJE();
for (size_t i = 0; i < gconinje.gconinje.size(); i++) {
if (gconinje.gconinje[i].group_ == name) {
GconinjeLine line = gconinje.gconinje[i];
injection_specification.injector_type_ = toSurfaceComponent(line.injector_type_);
injection_specification.control_mode_ = toInjectionControlMode(line.control_mode_);
injection_specification.surface_flow_max_rate_ = line.surface_flow_max_rate_;
injection_specification.fluid_volume_max_rate_ = line.resv_flow_max_rate_;
}
}
}
ProductionSpecification production_specification;
if (deck.hasField("GCONPROD")) {
std::cout << "Searching in gconprod " << std::endl;
std::cout << "name= " << name << std::endl;
GCONPROD gconprod = deck.getGCONPROD();
for (size_t i = 0; i < gconprod.gconprod.size(); i++) {
if (gconprod.gconprod[i].group_ == name) {
GconprodLine line = gconprod.gconprod[i];
production_specification.oil_max_rate_ = line.oil_max_rate_;
std::cout << "control_mode = " << line.control_mode_ << std::endl;
production_specification.control_mode_ = toProductionControlMode(line.control_mode_);
production_specification.water_production_target_ = line.water_max_rate_;
production_specification.gas_max_rate_ = line.gas_max_rate_;
production_specification.liquid_max_rate_ = line.liquid_max_rate_;
production_specification.procedure_ = toProductionProcedure(line.procedure_);
}
}
}
return_value.reset(new WellsGroup(name, production_specification, injection_specification));
}
return return_value;
}
}