280 lines
7.6 KiB
C
280 lines
7.6 KiB
C
/*---------------------------------------------------------------------------*\
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========= |
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\\ / F ield | foam-extend: Open Source CFD
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\\ / O peration |
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\\ / A nd | For copyright notice see file Copyright
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\\/ M anipulation |
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-------------------------------------------------------------------------------
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License
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This file is part of foam-extend.
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foam-extend is free software: you can redistribute it and/or modify it
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under the terms of the GNU General Public License as published by the
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Free Software Foundation, either version 3 of the License, or (at your
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option) any later version.
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foam-extend is distributed in the hope that it will be useful, but
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WITHOUT ANY WARRANTY; without even the implied warranty of
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MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
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General Public License for more details.
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You should have received a copy of the GNU General Public License
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along with foam-extend. If not, see <http://www.gnu.org/licenses/>.
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Application
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adiabaticFlameT
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Description
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Calculates the equilibrium flame temperature for a given fuel and
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pressure for a range of unburnt gas temperatures and equivalence
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ratios; the effects of dissociation on O2, H2O and CO2 are included.
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\*---------------------------------------------------------------------------*/
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#include "argList.H"
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#include "objectRegistry.H"
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#include "Time.H"
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#include "dictionary.H"
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#include "IFstream.H"
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#include "OSspecific.H"
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#include "IOmanip.H"
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#include "specieThermo.H"
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#include "janafThermo.H"
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#include "perfectGas.H"
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using namespace Foam;
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typedef specieThermo<janafThermo<perfectGas> > thermo;
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// * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * //
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int main(int argc, char *argv[])
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{
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argList::validArgs.clear();
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argList::validArgs.append("controlFile");
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argList args(argc, argv);
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fileName controlFileName(args.additionalArgs()[0]);
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// Construct control dictionary
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IFstream controlFile(controlFileName);
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// Check controlFile stream is OK
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if (!controlFile.good())
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{
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FatalErrorIn(args.executable())
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<< "Cannot read file " << controlFileName
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<< abort(FatalError);
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}
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dictionary control(controlFile);
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scalar P(readScalar(control.lookup("P")));
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word fuel(control.lookup("fuel"));
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scalar n(readScalar(control.lookup("n")));
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scalar m(readScalar(control.lookup("m")));
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Info<< nl << "Reading Burcat data dictionary" << endl;
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fileName BurcatCpDataFileName(findEtcFile("thermoData/BurcatCpData"));
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// Construct control dictionary
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IFstream BurcatCpDataFile(BurcatCpDataFileName);
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// Check BurcatCpData stream is OK
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if (!BurcatCpDataFile.good())
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{
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FatalErrorIn(args.executable())
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<< "Cannot read file " << BurcatCpDataFileName
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<< abort(FatalError);
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}
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dictionary thermoData(BurcatCpDataFile);
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Info<< nl << "Reading Burcat data for relevant species" << nl << endl;
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// Reactants
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thermo FUEL(thermoData.lookup(fuel));
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thermo O2(thermoData.lookup("O2"));
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thermo N2(thermoData.lookup("N2"));
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// Products
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thermo CO2(thermoData.lookup("CO2"));
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thermo H2O(thermoData.lookup("H2O"));
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// Product fragments
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thermo CO(thermoData.lookup("CO"));
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thermo H2(thermoData.lookup("H2"));
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// Product dissociation reactions
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thermo CO2BreakUp
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(
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CO2 == CO + 0.5* O2
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);
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thermo H2OBreakUp
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(
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H2O == H2 + 0.5*O2
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);
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// Stoiciometric number of moles of species for one mole of fuel
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scalar stoicO2 = n + m/4.0;
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scalar stoicN2 = (0.79/0.21)*(n + m/4.0);
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scalar stoicCO2 = n;
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scalar stoicH2O = m/2.0;
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// Oxidant
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thermo oxidant
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(
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"oxidant",
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stoicO2*O2
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+ stoicN2*N2
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);
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dimensionedScalar stoichiometricAirFuelMassRatio
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(
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"stoichiometricAirFuelMassRatio",
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dimless,
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(oxidant.W()*oxidant.nMoles())/FUEL.W()
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);
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Info<< "stoichiometricAirFuelMassRatio "
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<< stoichiometricAirFuelMassRatio << ';' << endl;
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Info<< "Equilibrium flame temperature data ("
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<< P/1e5 << " bar)" << nl << nl
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<< setw(3) << "Phi"
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<< setw(12) << "ft"
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<< setw(7) << "T0"
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<< setw(12) << "Tad"
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<< setw(12) << "Teq"
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<< setw(12) << "Terror"
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<< setw(20) << "O2res (mole frac)" << nl
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<< endl;
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// Loop over equivalence ratios
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for (int i=0; i<16; i++)
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{
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scalar equiv = 0.6 + i*0.05;
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scalar ft = 1/(1 + stoichiometricAirFuelMassRatio.value()/equiv);
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// Loop over initial temperatures
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for (int j=0; j<28; j++)
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{
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scalar T0 = 300.0 + j*100.0;
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// Number of moles of species for one mole of fuel
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scalar o2 = (1.0/equiv)*stoicO2;
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scalar n2 = (0.79/0.21)*o2;
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scalar fres = max(1.0 - 1.0/equiv, 0.0);
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scalar fburnt = 1.0 - fres;
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// Initial guess for number of moles of product species
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// ignoring product dissociation
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scalar oresInit = max(1.0/equiv - 1.0, 0.0)*stoicO2;
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scalar co2Init = fburnt*stoicCO2;
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scalar h2oInit = fburnt*stoicH2O;
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scalar ores = oresInit;
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scalar co2 = co2Init;
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scalar h2o = h2oInit;
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scalar co = 0.0;
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scalar h2 = 0.0;
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// Total number of moles in system
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scalar N = fres + n2 + co2 + h2o + ores;
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// Initial guess for adiabatic flame temperature
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scalar adiabaticFlameTemperature =
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T0
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+ (fburnt/(1.0 + o2 + n2))/(1.0/(1.0 + (1.0 + 0.79/0.21)*stoicO2))
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*2000.0;
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scalar equilibriumFlameTemperature = adiabaticFlameTemperature;
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// Iteration loop for adiabatic flame temperature
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for (int j=0; j<20; j++)
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{
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if (j > 0)
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{
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co = co2*
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min
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(
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CO2BreakUp.Kn(equilibriumFlameTemperature, P, N)
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/::sqrt(max(ores, 0.001)),
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1.0
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);
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h2 = h2o*
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min
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(
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H2OBreakUp.Kn(equilibriumFlameTemperature, P, N)
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/::sqrt(max(ores, 0.001)),
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1.0
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);
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co2 = co2Init - co;
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h2o = h2oInit - h2;
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ores = oresInit + 0.5*co + 0.5*h2;
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}
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thermo reactants
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(
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FUEL + o2*O2 + n2*N2
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);
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thermo products
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(
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fres*FUEL + ores*O2 + n2*N2
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+ co2*CO2 + h2o*H2O + co*CO + h2*H2
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);
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scalar equilibriumFlameTemperatureNew =
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products.TH(reactants.H(T0), adiabaticFlameTemperature);
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if (j==0)
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{
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adiabaticFlameTemperature = equilibriumFlameTemperatureNew;
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}
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else
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{
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equilibriumFlameTemperature = 0.5*
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(
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equilibriumFlameTemperature
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+ equilibriumFlameTemperatureNew
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);
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}
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}
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Info<< setw(3) << equiv
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<< setw(12) << ft
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<< setw(7) << T0
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<< setw(12) << adiabaticFlameTemperature
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<< setw(12) << equilibriumFlameTemperature
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<< setw(12)
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<< adiabaticFlameTemperature - equilibriumFlameTemperature
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<< setw(12) << ores/N
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<< endl;
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}
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}
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Info<< nl << "end" << endl;
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return 0;
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}
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// ************************************************************************* //
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