/*---------------------------------------------------------------------------*\ ========= | \\ / 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 . \*---------------------------------------------------------------------------*/ #include "SCOPELaminarFlameSpeed.H" #include "addToRunTimeSelectionTable.H" // * * * * * * * * * * * * * * Static Data Members * * * * * * * * * * * * * // namespace Foam { namespace laminarFlameSpeedModels { defineTypeNameAndDebug(SCOPE, 0); addToRunTimeSelectionTable ( laminarFlameSpeed, SCOPE, dictionary ); } } // * * * * * * * * * * * * * * * * Constructors * * * * * * * * * * * * * * // Foam::laminarFlameSpeedModels::SCOPE::polynomial::polynomial ( const dictionary& polyDict ) : FixedList(polyDict.lookup("coefficients")), ll(readScalar(polyDict.lookup("lowerLimit"))), ul(readScalar(polyDict.lookup("upperLimit"))), llv(polyPhi(ll, *this)), ulv(polyPhi(ul, *this)), lu(0) {} Foam::laminarFlameSpeedModels::SCOPE::SCOPE ( const dictionary& dict, const hhuCombustionThermo& ct ) : laminarFlameSpeed(dict, ct), coeffsDict_(dict.subDict(typeName + "Coeffs").subDict(fuel_)), LFL_(readScalar(coeffsDict_.lookup("lowerFlamabilityLimit"))), UFL_(readScalar(coeffsDict_.lookup("upperFlamabilityLimit"))), SuPolyL_(coeffsDict_.subDict("lowerSuPolynomial")), SuPolyU_(coeffsDict_.subDict("upperSuPolynomial")), Texp_(readScalar(coeffsDict_.lookup("Texp"))), pexp_(readScalar(coeffsDict_.lookup("pexp"))), MaPolyL_(coeffsDict_.subDict("lowerMaPolynomial")), MaPolyU_(coeffsDict_.subDict("upperMaPolynomial")) { SuPolyL_.ll = max(SuPolyL_.ll, LFL_) + SMALL; SuPolyU_.ul = min(SuPolyU_.ul, UFL_) - SMALL; SuPolyL_.lu = 0.5*(SuPolyL_.ul + SuPolyU_.ll); SuPolyU_.lu = SuPolyL_.lu - SMALL; MaPolyL_.lu = 0.5*(MaPolyL_.ul + MaPolyU_.ll); MaPolyU_.lu = MaPolyL_.lu - SMALL; if (debug) { Info<< "phi Su (T = Tref, p = pref)" << endl; label n = 200; for (int i=0; i UFL_) { // Return 0 beyond the flamibility limits return scalar(0); } else if (phi < SuPolyL_.ll) { // Use linear interpolation between the low end of the // lower polynomial and the lower flamibility limit return SuPolyL_.llv*(phi - LFL_)/(SuPolyL_.ll - LFL_); } else if (phi > SuPolyU_.ul) { // Use linear interpolation between the upper end of the // upper polynomial and the upper flamibility limit return SuPolyU_.ulv*(UFL_ - phi)/(UFL_ - SuPolyU_.ul); } else if (phi < SuPolyL_.lu) { // Evaluate the lower polynomial return polyPhi(phi, SuPolyL_); } else if (phi > SuPolyU_.lu) { // Evaluate the upper polynomial return polyPhi(phi, SuPolyU_); } else { FatalErrorIn("laminarFlameSpeedModels::SCOPE::SuRef(scalar phi)") << "phi = " << phi << " cannot be handled by SCOPE function with the " "given coefficients" << exit(FatalError); return scalar(0); } } inline Foam::scalar Foam::laminarFlameSpeedModels::SCOPE::Ma ( scalar phi ) const { if (phi < MaPolyL_.ll) { // Beyond the lower limit assume Ma is constant return MaPolyL_.llv; } else if (phi > MaPolyU_.ul) { // Beyond the upper limit assume Ma is constant return MaPolyU_.ulv; } else if (phi < SuPolyL_.lu) { // Evaluate the lower polynomial return polyPhi(phi, MaPolyL_); } else if (phi > SuPolyU_.lu) { // Evaluate the upper polynomial return polyPhi(phi, MaPolyU_); } else { FatalErrorIn("laminarFlameSpeedModels::SCOPE::Ma(scalar phi)") << "phi = " << phi << " cannot be handled by SCOPE function with the " "given coefficients" << exit(FatalError); return scalar(0); } } inline Foam::scalar Foam::laminarFlameSpeedModels::SCOPE::Su0pTphi ( scalar p, scalar Tu, scalar phi ) const { static const scalar Tref = 300.0; static const scalar pRef = 1.013e5; return SuRef(phi)*pow((Tu/Tref), Texp_)*pow((p/pRef), pexp_); } Foam::tmp Foam::laminarFlameSpeedModels::SCOPE::Su0pTphi ( const volScalarField& p, const volScalarField& Tu, scalar phi ) const { tmp tSu0 ( new volScalarField ( IOobject ( "Su0", p.time().timeName(), p.db(), IOobject::NO_READ, IOobject::NO_WRITE ), p.mesh(), dimensionedScalar("Su0", dimVelocity, 0.0) ) ); volScalarField& Su0 = tSu0(); forAll(Su0, celli) { Su0[celli] = Su0pTphi(p[celli], Tu[celli], phi); } forAll(Su0.boundaryField(), patchi) { scalarField& Su0p = Su0.boundaryField()[patchi]; const scalarField& pp = p.boundaryField()[patchi]; const scalarField& Tup = Tu.boundaryField()[patchi]; forAll(Su0p, facei) { Su0p[facei] = Su0pTphi(pp[facei], Tup[facei], phi); } } return tSu0; } Foam::tmp Foam::laminarFlameSpeedModels::SCOPE::Su0pTphi ( const volScalarField& p, const volScalarField& Tu, const volScalarField& phi ) const { tmp tSu0 ( new volScalarField ( IOobject ( "Su0", p.time().timeName(), p.db(), IOobject::NO_READ, IOobject::NO_WRITE ), p.mesh(), dimensionedScalar("Su0", dimVelocity, 0.0) ) ); volScalarField& Su0 = tSu0(); forAll(Su0, celli) { Su0[celli] = Su0pTphi(p[celli], Tu[celli], phi[celli]); } forAll(Su0.boundaryField(), patchi) { scalarField& Su0p = Su0.boundaryField()[patchi]; const scalarField& pp = p.boundaryField()[patchi]; const scalarField& Tup = Tu.boundaryField()[patchi]; const scalarField& phip = phi.boundaryField()[patchi]; forAll(Su0p, facei) { Su0p[facei] = Su0pTphi ( pp[facei], Tup[facei], phip[facei] ); } } return tSu0; } Foam::tmp Foam::laminarFlameSpeedModels::SCOPE::Ma ( const volScalarField& phi ) const { tmp tMa ( new volScalarField ( IOobject ( "Ma", phi.time().timeName(), phi.db(), IOobject::NO_READ, IOobject::NO_WRITE ), phi.mesh(), dimensionedScalar("Ma", dimless, 0.0) ) ); volScalarField& ma = tMa(); forAll(ma, celli) { ma[celli] = Ma(phi[celli]); } forAll(ma.boundaryField(), patchi) { scalarField& map = ma.boundaryField()[patchi]; const scalarField& phip = phi.boundaryField()[patchi]; forAll(map, facei) { map[facei] = Ma(phip[facei]); } } return tMa; } Foam::tmp Foam::laminarFlameSpeedModels::SCOPE::Ma() const { if (hhuCombustionThermo_.composition().contains("ft")) { const volScalarField& ft = hhuCombustionThermo_.composition().Y("ft"); return Ma ( dimensionedScalar ( hhuCombustionThermo_.lookup("stoichiometricAirFuelMassRatio") )*ft/(scalar(1) - ft) ); } else { const fvMesh& mesh = hhuCombustionThermo_.p().mesh(); return tmp ( new volScalarField ( IOobject ( "Ma", mesh.time().timeName(), mesh, IOobject::NO_READ, IOobject::NO_WRITE ), mesh, dimensionedScalar("Ma", dimless, Ma(equivalenceRatio_)) ) ); } } Foam::tmp Foam::laminarFlameSpeedModels::SCOPE::operator()() const { if (hhuCombustionThermo_.composition().contains("ft")) { const volScalarField& ft = hhuCombustionThermo_.composition().Y("ft"); return Su0pTphi ( hhuCombustionThermo_.p(), hhuCombustionThermo_.Tu(), dimensionedScalar ( hhuCombustionThermo_.lookup("stoichiometricAirFuelMassRatio") )*ft/(scalar(1) - ft) ); } else { return Su0pTphi ( hhuCombustionThermo_.p(), hhuCombustionThermo_.Tu(), equivalenceRatio_ ); } } // ************************************************************************* //