cantera/src/zeroD/FlowDevice.cpp

65 lines
1.4 KiB
C++

//! @file FlowDevice.cpp
#include "cantera/zeroD/FlowDevice.h"
#include "cantera/zeroD/ReactorBase.h"
#include "cantera/numerics/Func1.h"
namespace Cantera
{
bool FlowDevice::install(ReactorBase& in, ReactorBase& out)
{
if (m_in || m_out) {
return false;
}
m_in = ∈
m_out = &out;
m_in->addOutlet(*this);
m_out->addInlet(*this);
// construct adapters between inlet and outlet species
ThermoPhase* mixin = &m_in->contents();
ThermoPhase* mixout = &m_out->contents();
if (mixin == 0 || mixout == 0) {
return false;
}
m_nspin = mixin->nSpecies();
m_nspout = mixout->nSpecies();
std::string nm;
size_t ki, ko;
for (ki = 0; ki < m_nspin; ki++) {
nm = mixin->speciesName(ki);
ko = mixout->speciesIndex(nm);
m_in2out.push_back(ko);
}
for (ko = 0; ko < m_nspout; ko++) {
nm = mixout->speciesName(ko);
ki = mixin->speciesIndex(nm);
m_out2in.push_back(ki);
}
return true;
}
void FlowDevice::setFunction(Func1* f)
{
m_func = f;
}
doublereal FlowDevice::outletSpeciesMassFlowRate(size_t k)
{
if (k >= m_nspout) {
return 0.0;
}
size_t ki = m_out2in[k];
if (ki == npos) {
return 0.0;
}
return m_mdot * m_in->massFraction(ki);
}
doublereal FlowDevice::enthalpy_mass()
{
return m_in->enthalpy_mass();
}
}