cantera/doc/doxygen/demo1.cpp
Ray Speth 2528df0f75 Reorganized source tree structure
These changes make it unnecessary to copy header files around during
the build process, which tends to confuse IDEs and debuggers. The
headers which comprise Cantera's external C++ interface are now in
the 'include' directory.

All of the samples and demos are now in the 'samples' subdirectory.
2012-02-12 02:27:14 +00:00

108 lines
3 KiB
C++

#include <cantera/Cantera.h>
#include <cantera/IdealGasMix.h> // defines class IdealGasMix
#include <cantera/equilibrium.h> // chemical equilibrium
#include <cantera/transport.h> // transport properties
void demoprog()
{
// construct a gas mixture object from the specification in
// fileh2o2.cti, which defines a reacting hydrogen/oxygen mixture.
IdealGasMix gas("h2o2.cti","ohmech");
// set its state by specifying the temperature, pressure,
// and mole fractions
double temp = 1200.0;
double pres = OneAtm;
gas.setState_TPX(temp, pres, "H2:1, O2:1, AR:2");
// Print some thermodynamic properties
printf("\n\nInitial state:\n\n");
printf(
"Temperature: %14.5g K\n"
"Pressure: %14.5g Pa\n"
"Density: %14.5g kg/m3\n"
"Molar Enthalpy: %14.5g J/kmol\n"
"Molar Entropy: %14.5g J/kmol-K\n"
"Molar cp: %14.5g J/kmol-K\n",
gas.temperature(), gas.pressure(), gas.density(),
gas.enthalpy_mole(), gas.entropy_mole(), gas.cp_mole());
// set the gas to the equilibrium state with the same specific
// enthalpy and pressure
equilibrate(gas,"HP");
// Print them again for the new equilibrium state
printf("\n\nEquilibrium state:\n\n");
printf(
"Temperature: %14.5g K\n"
"Pressure: %14.5g Pa\n"
"Density: %14.5g kg/m3\n"
"Molar Enthalpy: %14.5g J/kmol\n"
"Molar Entropy: %14.5g J/kmol-K\n"
"Molar cp: %14.5g J/kmol-K\n",
gas.temperature(), gas.pressure(), gas.density(),
gas.enthalpy_mole(), gas.entropy_mole(), gas.cp_mole());
// Reaction information
int irxns = gas.nReactions();
double* qf = new double[irxns];
double* qr = new double[irxns];
double* q = new double[irxns];
// since the gas has been set to an equilibrium state, the forward
// and reverse rates of progress should be equal for all
// reversible reactions, and the net rates should be zero.
// We'll print them to check this.
gas.getFwdRatesOfProgress(qf);
gas.getRevRatesOfProgress(qr);
gas.getNetRatesOfProgress(q);
printf("\n\n");
for (int i = 0; i < irxns; i++) {
printf("%30s %14.5g %14.5g %14.5g kmol/m3/s\n",
gas.reactionString(i).c_str(), qf[i], qr[i], q[i]);
}
// transport properties
Transport* tr = newTransportMgr("Mix", &gas, 1);
printf("\n\nViscosity: %14.5g Pa-s\n", tr->viscosity());
printf("Thermal conductivity: %14.5g W/m/K\n", tr->thermalConductivity());
int nsp = gas.nSpecies();
double* diff = new double[nsp];
tr->getMixDiffCoeffs(diff);
int k;
printf("\n\n%20s %26s\n", "Species","Diffusion Coefficient");
for (k = 0; k < nsp; k++) {
printf("%20s %14.5g m2/s \n", gas.speciesName(k).c_str(), diff[k]);
}
// clean up
delete qf;
delete qr;
delete q;
delete diff;
delete tr;
}
int main()
{
try {
demoprog();
} catch (CanteraError) {
showErrors(cout);
}
}