/*---------------------------------------------------------------------------*\ ========= | \\ / F ield | foam-extend: Open Source CFD \\ / O peration | Version: 3.2 \\ / A nd | Web: http://www.foam-extend.org \\/ M anipulation | For copyright notice see file Copyright ------------------------------------------------------------------------------- License This file is part of foam-extend. foam-extend is free software: you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation, either version 3 of the License, or (at your option) any later version. foam-extend is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with foam-extend. If not, see . Application adiabaticFlameT Description Calculates the adiabatic flame temperature for a given fuel over a range of unburnt temperatures and equivalence ratios. \*---------------------------------------------------------------------------*/ #include "argList.H" #include "objectRegistry.H" #include "Time.H" #include "dictionary.H" #include "IFstream.H" #include "OSspecific.H" #include "specieThermo.H" #include "janafThermo.H" #include "perfectGas.H" using namespace Foam; typedef specieThermo > thermo; // * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * // int main(int argc, char *argv[]) { argList::validArgs.clear(); argList::validArgs.append("controlFile"); argList args(argc, argv); fileName controlFileName(args.additionalArgs()[0]); // Construct control dictionary IFstream controlFile(controlFileName); // Check controlFile stream is OK if (!controlFile.good()) { FatalErrorIn(args.executable()) << "Cannot read file " << controlFileName << exit(FatalError); } dictionary control(controlFile); scalar T0(readScalar(control.lookup("T0"))); word fuelName(control.lookup("fuel")); scalar n(readScalar(control.lookup("n"))); scalar m(readScalar(control.lookup("m"))); Info<< nl << "Reading Burcat data dictionary" << endl; fileName BurcatCpDataFileName(findEtcFile("thermoData/BurcatCpData")); // Construct control dictionary IFstream BurcatCpDataFile(BurcatCpDataFileName); // Check BurcatCpData stream is OK if (!BurcatCpDataFile.good()) { FatalErrorIn(args.executable()) << "Cannot read file " << BurcatCpDataFileName << exit(FatalError); } dictionary CpData(BurcatCpDataFile); scalar stoicO2 = n + m/4.0; scalar stoicN2 = (0.79/0.21)*(n + m/4.0); scalar stoicCO2 = n; scalar stoicH2O = m/2.0; thermo fuel ( "fuel", thermo(CpData.lookup(fuelName)) ); thermo oxidant ( "oxidant", stoicO2*thermo(CpData.lookup("O2")) + stoicN2*thermo(CpData.lookup("N2")) ); dimensionedScalar stoichiometricAirFuelMassRatio ( "stoichiometricAirFuelMassRatio", dimless, (oxidant.W()*oxidant.nMoles())/fuel.W() ); Info<< "stoichiometricAirFuelMassRatio " << stoichiometricAirFuelMassRatio << ';' << endl; for (int i=0; i<300; i++) { scalar equiv = (i + 1)*0.01; scalar ft = 1/(1 + stoichiometricAirFuelMassRatio.value()/equiv); Info<< "phi = " << equiv << nl << "ft = " << ft << endl; scalar o2 = (1.0/equiv)*stoicO2; scalar n2 = (0.79/0.21)*o2; scalar fres = max(1.0 - 1.0/equiv, 0.0); scalar ores = max(1.0/equiv - 1.0, 0.0); scalar fburnt = 1.0 - fres; thermo fuel ( "fuel", thermo(CpData.lookup(fuelName)) ); Info<< "fuel " << fuel << ';' << endl; thermo oxidant ( "oxidant", o2*thermo(CpData.lookup("O2")) + n2*thermo(CpData.lookup("N2")) ); Info<< "oxidant " << (1/oxidant.nMoles())*oxidant << ';' << endl; thermo reactants ( "reactants", fuel + oxidant ); Info<< "reactants " << (1/reactants.nMoles())*reactants << ';' << endl; thermo burntProducts ( "burntProducts", + (n2 - (0.79/0.21)*ores*stoicO2)*thermo(CpData.lookup("N2")) + fburnt*stoicCO2*thermo(CpData.lookup("CO2")) + fburnt*stoicH2O*thermo(CpData.lookup("H2O")) ); Info<< "burntProducts " << (1/burntProducts.nMoles())*burntProducts << ';' << endl; thermo products ( "products", fres*fuel + n2*thermo(CpData.lookup("N2")) + fburnt*stoicCO2*thermo(CpData.lookup("CO2")) + fburnt*stoicH2O*thermo(CpData.lookup("H2O")) + ores*stoicO2*thermo(CpData.lookup("O2")) ); Info<< "products " << (1/products.nMoles())*products << ';' << endl; scalar Tad = products.TH(reactants.H(T0), 1000.0); Info<< "Tad = " << Tad << nl << endl; } Info<< nl << "end" << endl; return 0; } // ************************************************************************* //