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#include "SyncMachineForm.h"
#include "SyncMotor.h"
SyncMotor::SyncMotor() : Machines() {}
SyncMotor::SyncMotor(wxString name) : Machines() { m_electricalData.name = name; }
SyncMotor::~SyncMotor() {}
void SyncMotor::DrawSymbol() const { DrawArc(m_position, 12, 30, 330, 10, GL_LINE_STRIP); }
bool SyncMotor::GetContextMenu(wxMenu& menu)
{
menu.Append(ID_EDIT_ELEMENT, _("Edit Synchronous Condenser"));
GeneralMenuItens(menu);
return true;
}
bool SyncMotor::ShowForm(wxWindow* parent, Element* element)
{
SyncMachineForm* syncMotorForm = new SyncMachineForm(parent, this);
syncMotorForm->SetTitle(_("Synchronous Condenser"));
if(syncMotorForm->ShowModal() == wxID_OK) {
syncMotorForm->Destroy();
return true;
}
syncMotorForm->Destroy();
return false;
}
SyncMotorElectricalData SyncMotor::GetPUElectricalData(double systemPowerBase)
{
SyncMotorElectricalData data = m_electricalData;
double machineBasePower = 1.0;
if(data.useMachineBase) {
machineBasePower = GetValueFromUnit(data.nominalPower, data.nominalPowerUnit);
}
// Active power
double activePower = GetValueFromUnit(data.activePower, data.activePowerUnit);
if(!m_online) activePower = 0.0;
if(data.activePowerUnit == UNIT_PU) {
if(data.useMachineBase) data.activePower = (activePower * machineBasePower) / systemPowerBase;
} else {
data.activePower = activePower / systemPowerBase;
}
data.activePowerUnit = UNIT_PU;
// Reactive power
double reactivePower = GetValueFromUnit(data.reactivePower, data.reactivePowerUnit);
if(!m_online) reactivePower = 0.0;
if(data.reactivePowerUnit == UNIT_PU) {
if(data.useMachineBase) data.reactivePower = (reactivePower * machineBasePower) / systemPowerBase;
} else {
data.reactivePower = reactivePower / systemPowerBase;
}
data.reactivePowerUnit = UNIT_PU;
// Max reactive power
double maxReactive = GetValueFromUnit(data.maxReactive, data.maxReactiveUnit);
if(data.maxReactiveUnit == UNIT_PU) {
if(data.useMachineBase) data.maxReactive = (maxReactive * machineBasePower) / systemPowerBase;
} else {
data.maxReactive = maxReactive / systemPowerBase;
}
data.maxReactiveUnit = UNIT_PU;
// Min reactive power
double minReactive = GetValueFromUnit(data.minReactive, data.minReactiveUnit);
if(data.minReactiveUnit == UNIT_PU) {
if(data.useMachineBase) data.minReactive = (minReactive * machineBasePower) / systemPowerBase;
} else {
data.minReactive = minReactive / systemPowerBase;
}
data.minReactiveUnit = UNIT_PU;
double baseVoltage = GetValueFromUnit(data.nominalVoltage, data.nominalVoltageUnit);
double systemBaseImpedance = (baseVoltage * baseVoltage) / systemPowerBase;
double machineBaseImpedance = (baseVoltage * baseVoltage) / machineBasePower;
// Fault data
if(data.useMachineBase) {
data.positiveResistance = (data.positiveResistance * machineBaseImpedance) / systemBaseImpedance;
data.positiveReactance = (data.positiveReactance * machineBaseImpedance) / systemBaseImpedance;
data.negativeResistance = (data.negativeResistance * machineBaseImpedance) / systemBaseImpedance;
data.negativeReactance = (data.negativeReactance * machineBaseImpedance) / systemBaseImpedance;
data.zeroResistance = (data.zeroResistance * machineBaseImpedance) / systemBaseImpedance;
data.zeroReactance = (data.zeroReactance * machineBaseImpedance) / systemBaseImpedance;
data.groundResistance = (data.groundResistance * machineBaseImpedance) / systemBaseImpedance;
data.groundReactance = (data.groundReactance * machineBaseImpedance) / systemBaseImpedance;
}
if(!m_online) {
data.faultCurrent[0] = std::complex<double>(0, 0);
data.faultCurrent[1] = std::complex<double>(0, 0);
data.faultCurrent[2] = std::complex<double>(0, 0);
}
return data;
}
void SyncMotor::SetNominalVoltage(std::vector<double> nominalVoltage, std::vector<ElectricalUnit> nominalVoltageUnit)
{
if(nominalVoltage.size() > 0) {
m_electricalData.nominalVoltage = nominalVoltage[0];
m_electricalData.nominalVoltageUnit = nominalVoltageUnit[0];
}
}
Element* SyncMotor::GetCopy()
{
SyncMotor* copy = new SyncMotor();
*copy = *this;
return copy;
}
wxString SyncMotor::GetTipText() const
{
wxString tipText = m_electricalData.name;
tipText += "\n";
double activePower = m_electricalData.activePower;
if(!m_online) activePower = 0.0;
tipText += _("\nP = ") + wxString::FromDouble(activePower, 5);
switch(m_electricalData.activePowerUnit) {
case UNIT_PU: {
tipText += _(" p.u.");
} break;
case UNIT_W: {
tipText += _(" W");
} break;
case UNIT_kW: {
tipText += _(" kW");
} break;
case UNIT_MW: {
tipText += _(" MW");
} break;
default:
break;
}
double reactivePower = m_electricalData.reactivePower;
if(!m_online) reactivePower = 0.0;
tipText += _("\nQ = ") + wxString::FromDouble(reactivePower, 5);
switch(m_electricalData.reactivePowerUnit) {
case UNIT_PU: {
tipText += _(" p.u.");
} break;
case UNIT_VAr: {
tipText += _(" VAr");
} break;
case UNIT_kVAr: {
tipText += _(" kVAr");
} break;
case UNIT_MVAr: {
tipText += _(" MVAr");
} break;
default:
break;
}
return tipText;
}
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