Info<< "Reading thermophysical properties\n" << endl;
autoPtr<basicPsiThermo> pThermo
(
basicPsiThermo::New(mesh)
);
basicPsiThermo& thermo = pThermo();
volScalarField& p = thermo.p();
volScalarField& h = thermo.h();
const volScalarField& T = thermo.T();
const volScalarField& psi = thermo.psi();
volScalarField rho
IOobject
"rho",
runTime.timeName(),
mesh,
IOobject::NO_READ,
IOobject::AUTO_WRITE
),
thermo.rho()
rho.oldTime();
Info<< "\nReading field Urel\n" << endl;
volVectorField Urel
"Urel",
IOobject::MUST_READ,
mesh
Info<< "Reading/calculating face flux field phi\n" << endl;
surfaceScalarField phi
"phi",
IOobject::READ_IF_PRESENT,
linearInterpolate(rho*Urel) & mesh.Sf()
Info<< "Creating turbulence model\n" << endl;
autoPtr<compressible::RASModel> turbulence
compressible::RASModel::New
rho,
Urel,
phi,
thermo
)
Info<< "Creating SRF model\n" << endl;
autoPtr<SRF::SRFModel> SRF
SRF::SRFModel::New(Urel)
// Create absolute velocity field
volVectorField Uabs
"Uabs",
Urel + SRF->U()
// Create rothalpy, in two steps to preserve boundary conditions
volScalarField i
"i",
h
i -= 0.5*magSqr(SRF->U());