cantera/test_problems/rankine_democxx/rankine.cpp
2012-05-25 23:13:30 +00:00

91 lines
2 KiB
C++

// An open Rankine cycle
#include <string>
#include <map>
#include "cantera/PureFluid.h" // defines class Water
using namespace Cantera;
using namespace std;
map<string,double> h;
map<string,double> s;
map<string,double> T;
map<string,double> P;
map<string,double> x;
vector<string> states;
template<class F>
void saveState(F& fluid, string name)
{
h[name] = fluid.enthalpy_mass();
s[name] = fluid.entropy_mass();
T[name] = fluid.temperature();
P[name] = fluid.pressure();
x[name] = fluid.vaporFraction();
states.push_back(name);
}
void printStates()
{
size_t nStates = states.size();
for (size_t n = 0; n < nStates; n++) {
string name = states[n];
printf(" %5s %10.6g %10.6g %12.6g %12.6g %5.2g \n",
name.c_str(), T[name], P[name], h[name], s[name], x[name]);
}
}
int openRankine(int np, void* p)
{
double etap = 0.6; // pump isentropic efficiency
double etat = 0.8; // turbine isentropic efficiency
double phigh = 8.0e5; // high pressure
Water w;
// begin with water at 300 K, 1 atm
w.setState_TP(300.0, OneAtm);
saveState(w,"1");
// pump water to 0.8 MPa
w.setState_SP(s["1"], phigh);
saveState(w,"2s");
double h2 = (h["2s"] - h["1"])/etap + h["1"];
w.setState_HP(h2, phigh);
saveState(w,"2");
// heat to saturated vapor
w.setState_Psat(phigh, 1.0);
saveState(w,"3");
// expand to 1 atm
w.setState_SP(s["3"], OneAtm);
saveState(w,"4s");
double work_s = h["3"] - h["4s"];
double work = etat*work_s;
w.setState_HP(h["3"] - work, OneAtm);
saveState(w,"4");
printStates();
double heat_in = h["3"] - h["2"];
double efficiency = work/heat_in;
cout << "efficiency = " << efficiency << endl;
return 0;
}
int main()
{
#ifdef _MSC_VER
_set_output_format(_TWO_DIGIT_EXPONENT);
#endif
try {
return openRankine(0, 0);
} catch (CanteraError& err) {
std::cout << err.what() << std::endl;
return -1;
}
}