41 template<
class BasicMomentumTransportModel>
44 return exp(-3.4/
sqr(scalar(1) +
sqr(k_)/(this->nu()*epsilon_)/50.0));
48 template<
class BasicMomentumTransportModel>
53 - 0.3*
exp(-
min(
sqr(
sqr(k_)/(this->nu()*epsilon_)), scalar(50.0)));
57 template<
class BasicMomentumTransportModel>
60 epsilon_ =
max(epsilon_, Cmu_*
sqr(k_)/(this->nutMaxCoeff_*this->nu()));
64 template<
class BasicMomentumTransportModel>
68 this->nut_ = Cmu_*fMu()*
sqr(k_)/epsilon_;
69 this->nut_.correctBoundaryConditions();
74 template<
class BasicMomentumTransportModel>
83 dimVolume*this->rho_.dimensions()*k_.dimensions()
90 template<
class BasicMomentumTransportModel>
99 dimVolume*this->rho_.dimensions()*epsilon_.dimensions()
108 template<
class BasicMomentumTransportModel>
131 Cmu_(
"Cmu", this->typeDict(
type), 0.09),
132 C1_(
"C1", this->typeDict(
type), 1.44),
133 C2_(
"C2", this->typeDict(
type), 1.92),
134 C3_(
"C3", this->typeDict(
type), 0),
135 sigmak_(
"sigmak", this->typeDict(
type), 1.0),
136 sigmaEps_(
"sigmaEps", this->typeDict(
type), 1.3),
142 this->groupName(
"k"),
143 this->runTime_.
name(),
156 this->groupName(
"epsilon"),
157 this->runTime_.
name(),
173 template<
class BasicMomentumTransportModel>
178 Cmu_.readIfPresent(this->typeDict());
179 C1_.readIfPresent(this->typeDict());
180 C2_.readIfPresent(this->typeDict());
181 C3_.readIfPresent(this->typeDict());
182 sigmak_.readIfPresent(this->typeDict());
183 sigmaEps_.readIfPresent(this->typeDict());
194 template<
class BasicMomentumTransportModel>
197 if (!this->turbulence_)
244 epsEqn.
ref().relax();
246 epsEqn.
ref().boundaryManipulate(epsilon_.boundaryFieldRef());
269 bound(k_, this->kMin_);
Bound the given scalar field where it is below the specified minimum.
static fvConstraints & New(const word &name, const fvMesh &mesh)
Construct and return the named DemandDrivenMeshObject.
Generic GeometricField class.
IOobject defines the attributes of an object for which implicit objectRegistry management is supporte...
Templated abstract base class for RAS turbulence models.
virtual tmp< fvScalarMatrix > epsilonSource() const
Source term for the epsilon equation.
tmp< volScalarField > f2() const
virtual void correct()
Solve the turbulence equations and correct the turbulence viscosity.
LaunderSharmaKE(const alphaField &alpha, const rhoField &rho, const volVectorField &U, const surfaceScalarField &alphaRhoPhi, const surfaceScalarField &phi, const viscosity &viscosity, const word &type=typeName)
Construct from components.
void boundEpsilon()
Bound epsilon.
virtual void correctNut()
Correct the eddy-viscosity nut.
virtual tmp< fvScalarMatrix > kSource() const
Source term for the k equation.
tmp< volScalarField > fMu() const
virtual bool read()
Re-read model coefficients if they have changed.
Eddy viscosity turbulence model base class.
Finite volume constraints.
bool constrain(fvMatrix< Type > &eqn) const
Apply constraints to an equation.
A special matrix type and solver, designed for finite volume solutions of scalar equations....
tmp< fvMatrix< Type > > source(const VolField< Type > &field) const
Return source for an equation.
BasicMomentumTransportModel::alphaField alphaField
BasicMomentumTransportModel::rhoField rhoField
A class for managing temporary objects.
void clear() const
If object pointer points to valid object:
T & ref() const
Return non-const reference or generate a fatal error.
Abstract base class for all fluid physical properties.
A class for handling words, derived from string.
Foam::fvConstraints & fvConstraints(Foam::fvConstraints::New(mesh))
Foam::fvModels & fvModels(Foam::fvModels::New(mesh))
Calculate the magnitude of the square of the gradient of the gradient of the given volField.
volScalarField alpha(IOobject("alpha", runTime.name(), mesh, IOobject::READ_IF_PRESENT, IOobject::AUTO_WRITE), lambda *max(Ua &U, zeroSensitivity))
void correct(const RdeltaTType &rDeltaT, const RhoType &rho, volScalarField &psi, const surfaceScalarField &phiCorr, const SpType &Sp)
const dimensionedScalar G
Newtonian constant of gravitation.
const dimensionSet turbulentKineticEnergy
const dimensionSet turbulentEpsilon
tmp< volScalarField > magSqrGradGrad(const VolField< Type > &vf)
tmp< VolField< typename outerProduct< vector, Type >::type > > grad(const SurfaceField< Type > &ssf)
tmp< VolField< Type > > div(const SurfaceField< Type > &ssf)
tmp< surfaceScalarField > absolute(const tmp< surfaceScalarField > &tphi, const volVectorField &U)
Return the given relative flux in absolute form.
tmp< fvMatrix< Type > > laplacian(const VolField< Type > &vf, const word &name)
tmp< fvMatrix< Type > > div(const surfaceScalarField &flux, const VolField< Type > &vf, const word &name)
tmp< fvMatrix< Type > > Sp(const volScalarField::Internal &, const VolField< Type > &)
tmp< fvMatrix< Type > > SuSp(const volScalarField::Internal &, const VolField< Type > &)
tmp< fvMatrix< Type > > ddt(const VolField< Type > &vf)
static const coefficient D("D", dimTemperature, 257.14)
dimensionedScalar exp(const dimensionedScalar &ds)
bool read(const char *, int32_t &)
const dimensionSet & dimVolume
tmp< DimensionedField< typename outerProduct< Type, Type >::type, GeoMesh, Field >> sqr(const DimensionedField< Type, GeoMesh, PrimitiveField > &df)
const dimensionSet & dimTime
void dev(pointPatchField< tensor > &, const pointPatchField< tensor > &)
dimensioned< Type > min(const DimensionedField< Type, GeoMesh, PrimitiveField > &df)
bool bound(volScalarField &, const dimensionedScalar &min)
Bound the given scalar field where it is below the specified min value.
word name(const LagrangianState state)
Return a string representation of a Lagrangian state enumeration.
void twoSymm(pointPatchField< tensor > &, const pointPatchField< tensor > &)
void sqrt(LagrangianPatchField< scalar > &f, const LagrangianPatchField< scalar > &f1)
tmp< DimensionedField< scalar, GeoMesh, Field > > magSqr(const DimensionedField< Type, GeoMesh, PrimitiveField > &df)
dimensioned< Type > max(const DimensionedField< Type, GeoMesh, PrimitiveField > &df)
fileType type(const fileName &, const bool checkVariants=true, const bool followLink=true)
Return the file type: directory or file.
SolverPerformance< Type > solve(fvMatrix< Type > &, const word &)
Solve returning the solution statistics given convergence tolerance.