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| volScalarField | Cpv1 ("Cpv1", thermo1.Cpv()) |
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| volScalarField | Cpv2 ("Cpv2", thermo2.Cpv()) |
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| volScalarField | Kh (fluid.Kh()) |
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| fvScalarMatrix | E1Eqn (fvm::ddt(alpha1, rho1, he1)+fvm::div(alphaRhoPhi1, he1) - fvm::Sp(contErr1, he1)+fvc::ddt(alpha1, rho1, K1)+fvc::div(alphaRhoPhi1, K1) - contErr1 *K1+(he1.name()==thermo1.phasePropertyName("e") ? fvc::ddt(alpha1) *p+fvc::div(alphaPhi1, p) :-alpha1 *dpdt) - fvm::laplacian(fvc::interpolate(alpha1) *fvc::interpolate(thermo1.alphaEff(phase1.turbulence().mut())), he1)) |
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| E1Eqn | relax () |
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| fvScalarMatrix | E2Eqn (fvm::ddt(alpha2, rho2, he2)+fvm::div(alphaRhoPhi2, he2) - fvm::Sp(contErr2, he2)+fvc::ddt(alpha2, rho2, K2)+fvc::div(alphaRhoPhi2, K2) - contErr2 *K2+(he2.name()==thermo2.phasePropertyName("e") ? fvc::ddt(alpha2) *p+fvc::div(alphaPhi2, p) :-alpha2 *dpdt) - fvm::laplacian(fvc::interpolate(alpha2) *fvc::interpolate(thermo2.alphaEff(phase2.turbulence().mut())), he2)) |
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| fvOptions | constrain (E1Eqn) |
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| E1Eqn | solve () |
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| fvOptions | constrain (E2Eqn) |
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| thermo1 | correct () |
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◆ Cpv1()
| volScalarField Cpv1 |
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"Cpv1" |
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thermo1. |
Cpv() |
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) |
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◆ Cpv2()
| volScalarField Cpv2 |
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"Cpv2" |
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thermo2. |
Cpv() |
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) |
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◆ Kh()
| volScalarField Kh |
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fluid. |
Kh() | ) |
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◆ E1Eqn()
◆ relax()
◆ E2Eqn()
◆ constrain() [1/2]
◆ solve()
◆ constrain() [2/2]
◆ correct()
◆ he2
◆ E1Eqn
Initial value:
Definition at line 33 of file EEqns.H.
Referenced by for().
◆ E2Eqn
Initial value:
Definition at line 65 of file EEqns.H.
tmp< GeometricField< Type, fvPatchField, volMesh > > Sp(const volScalarField &sp, const GeometricField< Type, fvPatchField, volMesh > &vf)
1.8.17
