Ejemplo n.º 1
0
void dynamicKEqn<BasicTurbulenceModel>::correct()
{
    if (!this->turbulence_)
    {
        return;
    }

    // Local references
    const alphaField& alpha = this->alpha_;
    const rhoField& rho = this->rho_;
    const surfaceScalarField& alphaRhoPhi = this->alphaRhoPhi_;
    const volVectorField& U = this->U_;
    volScalarField& nut = this->nut_;
    fv::options& fvOptions(fv::options::New(this->mesh_));

    LESeddyViscosity<BasicTurbulenceModel>::correct();

    volScalarField divU(fvc::div(fvc::absolute(this->phi(), U)));

    tmp<volTensorField> tgradU(fvc::grad(U));
    const volSymmTensorField D(dev(symm(tgradU())));
    const volScalarField G(this->GName(), 2.0*nut*(tgradU() && D));
    tgradU.clear();

    volScalarField KK(0.5*(filter_(magSqr(U)) - magSqr(filter_(U))));
    KK.max(dimensionedScalar("small", KK.dimensions(), SMALL));

    tmp<fvScalarMatrix> kEqn
    (
        fvm::ddt(alpha, rho, k_)
      + fvm::div(alphaRhoPhi, k_)
      - fvm::laplacian(alpha*rho*DkEff(), k_)
    ==
        alpha*rho*G
      - fvm::SuSp((2.0/3.0)*alpha*rho*divU, k_)
      - fvm::Sp(Ce(D, KK)*alpha*rho*sqrt(k_)/this->delta(), k_)
      + kSource()
      + fvOptions(alpha, rho, k_)
    );

    kEqn.ref().relax();
    fvOptions.constrain(kEqn.ref());
    solve(kEqn);
    fvOptions.correct(k_);
    bound(k_, this->kMin_);

    correctNut(D, KK);
}
Ejemplo n.º 2
0
void RNGkEpsilon<BasicTurbulenceModel>::correct()
{
    if (!this->turbulence_)
    {
        return;
    }

    // Local references
    const alphaField& alpha = this->alpha_;
    const rhoField& rho = this->rho_;
    const surfaceScalarField& alphaRhoPhi = this->alphaRhoPhi_;
    const volVectorField& U = this->U_;
    volScalarField& nut = this->nut_;

    eddyViscosity<RASModel<BasicTurbulenceModel> >::correct();

    volScalarField divU(fvc::div(fvc::absolute(this->phi(), U)));

    tmp<volTensorField> tgradU = fvc::grad(U);
    volScalarField S2((tgradU() && dev(twoSymm(tgradU()))));
    tgradU.clear();

    volScalarField G(this->GName(), nut*S2);

    volScalarField eta(sqrt(mag(S2))*k_/epsilon_);
    volScalarField eta3(eta*sqr(eta));

    volScalarField R
    (
        ((eta*(-eta/eta0_ + scalar(1)))/(beta_*eta3 + scalar(1)))
    );

    // Update epsilon and G at the wall
    epsilon_.boundaryField().updateCoeffs();

    // Dissipation equation
    tmp<fvScalarMatrix> epsEqn
    (
        fvm::ddt(alpha, rho, epsilon_)
      + fvm::div(alphaRhoPhi, epsilon_)
      - fvm::laplacian(alpha*rho*DepsilonEff(), epsilon_)
     ==
        (C1_ - R)*alpha*rho*G*epsilon_/k_
      - fvm::SuSp(((2.0/3.0)*C1_ + C3_)*alpha*rho*divU, epsilon_)
      - fvm::Sp(C2_*alpha*rho*epsilon_/k_, epsilon_)
      + epsilonSource()
    );

    epsEqn().relax();

    epsEqn().boundaryManipulate(epsilon_.boundaryField());

    solve(epsEqn);
    bound(epsilon_, this->epsilonMin_);


    // Turbulent kinetic energy equation

    tmp<fvScalarMatrix> kEqn
    (
        fvm::ddt(alpha, rho, k_)
      + fvm::div(alphaRhoPhi, k_)
      - fvm::laplacian(alpha*rho*DkEff(), k_)
     ==
        alpha*rho*G
      - fvm::SuSp((2.0/3.0)*alpha*rho*divU, k_)
      - fvm::Sp(alpha*rho*epsilon_/k_, k_)
      + kSource()
    );

    kEqn().relax();
    solve(kEqn);
    bound(k_, this->kMin_);

    correctNut();
}
Ejemplo n.º 3
0
void mixtureKEpsilon<BasicTurbulenceModel>::correct()
{
    const transportModel& gas = this->transport();
    const twoPhaseSystem& fluid = gas.fluid();

    // Only solve the mixture turbulence for the gas-phase
    if (&gas != &fluid.phase1())
    {
        // This is the liquid phase but check the model for the gas-phase
        // is consistent
        this->liquidTurbulence();

        return;
    }

    if (!this->turbulence_)
    {
        return;
    }

    // Initialise the mixture fields if they have not yet been constructed
    initMixtureFields();

    // Local references to gas-phase properties
    const surfaceScalarField& phig = this->phi_;
    const volVectorField& Ug = this->U_;
    const volScalarField& alphag = this->alpha_;
    volScalarField& kg = this->k_;
    volScalarField& epsilong = this->epsilon_;
    volScalarField& nutg = this->nut_;

    // Local references to liquid-phase properties
    mixtureKEpsilon<BasicTurbulenceModel>& liquidTurbulence =
        this->liquidTurbulence();
    const surfaceScalarField& phil = liquidTurbulence.phi_;
    const volVectorField& Ul = liquidTurbulence.U_;
    const volScalarField& alphal = liquidTurbulence.alpha_;
    volScalarField& kl = liquidTurbulence.k_;
    volScalarField& epsilonl = liquidTurbulence.epsilon_;
    volScalarField& nutl = liquidTurbulence.nut_;

    // Local references to mixture properties
    volScalarField& rhom = rhom_();
    volScalarField& km = km_();
    volScalarField& epsilonm = epsilonm_();

    eddyViscosity<RASModel<BasicTurbulenceModel> >::correct();

    // Update the effective mixture density
    rhom = this->rhom();

    // Mixture flux
    surfaceScalarField phim("phim", mixFlux(phil, phig));

    // Mixture velocity divergence
    volScalarField divUm
    (
        mixU
        (
            fvc::div(fvc::absolute(phil, Ul)),
            fvc::div(fvc::absolute(phig, Ug))
        )
    );

    tmp<volScalarField> Gc;
    {
        tmp<volTensorField> tgradUl = fvc::grad(Ul);
        Gc = tmp<volScalarField>
        (
            new volScalarField
            (
                this->GName(),
                nutl*(tgradUl() && dev(twoSymm(tgradUl())))
            )
        );
        tgradUl.clear();

        // Update k, epsilon and G at the wall
        kl.boundaryField().updateCoeffs();
        epsilonl.boundaryField().updateCoeffs();

        Gc().checkOut();
    }

    tmp<volScalarField> Gd;
    {
        tmp<volTensorField> tgradUg = fvc::grad(Ug);
        Gd = tmp<volScalarField>
        (
            new volScalarField
            (
                this->GName(),
                nutg*(tgradUg() && dev(twoSymm(tgradUg())))
            )
        );
        tgradUg.clear();

        // Update k, epsilon and G at the wall
        kg.boundaryField().updateCoeffs();
        epsilong.boundaryField().updateCoeffs();

        Gd().checkOut();
    }

    // Mixture turbulence generation
    volScalarField Gm(mix(Gc, Gd));

    // Mixture turbulence viscosity
    volScalarField nutm(mixU(nutl, nutg));

    // Update the mixture k and epsilon boundary conditions
    km == mix(kl, kg);
    bound(km, this->kMin_);
    epsilonm == mix(epsilonl, epsilong);
    bound(epsilonm, this->epsilonMin_);

    // Dissipation equation
    tmp<fvScalarMatrix> epsEqn
    (
        fvm::ddt(rhom, epsilonm)
      + fvm::div(phim, epsilonm)
      - fvm::Sp(fvc::ddt(rhom) + fvc::div(phim), epsilonm)
      - fvm::laplacian(DepsilonEff(rhom*nutm), epsilonm)
     ==
        C1_*rhom*Gm*epsilonm/km
      - fvm::SuSp(((2.0/3.0)*C1_)*rhom*divUm, epsilonm)
      - fvm::Sp(C2_*rhom*epsilonm/km, epsilonm)
      + epsilonSource()
    );

    epsEqn().relax();

    epsEqn().boundaryManipulate(epsilonm.boundaryField());

    solve(epsEqn);
    bound(epsilonm, this->epsilonMin_);


    // Turbulent kinetic energy equation
    tmp<fvScalarMatrix> kmEqn
    (
        fvm::ddt(rhom, km)
      + fvm::div(phim, km)
      - fvm::Sp(fvc::ddt(rhom) + fvc::div(phim), km)
      - fvm::laplacian(DkEff(rhom*nutm), km)
     ==
        rhom*Gm
      - fvm::SuSp((2.0/3.0)*rhom*divUm, km)
      - fvm::Sp(rhom*epsilonm/km, km)
      + kSource()
    );

    kmEqn().relax();
    solve(kmEqn);
    bound(km, this->kMin_);
    km.correctBoundaryConditions();

    volScalarField Cc2(rhom/(alphal*rholEff() + alphag*rhogEff()*Ct2_()));
    kl = Cc2*km;
    kl.correctBoundaryConditions();
    epsilonl = Cc2*epsilonm;
    epsilonl.correctBoundaryConditions();
    liquidTurbulence.correctNut();

    Ct2_() = Ct2();
    kg = Ct2_()*kl;
    kg.correctBoundaryConditions();
    epsilong = Ct2_()*epsilonl;
    epsilong.correctBoundaryConditions();
    nutg = Ct2_()*(liquidTurbulence.nu()/this->nu())*nutl;
}