Functions
volScalarField	Cpv1 ("Cpv1", thermo1.Cpv())
volScalarField	Cpv2 ("Cpv2", thermo2.Cpv())
volScalarField	Kh (fluid.Kh())
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::div(fvc::absolute(alphaPhi1, alpha1, U1), p)+p fvc::ddt(alpha1) :-alpha1 dpdt) - fvm::laplacian(fvc::interpolate(alpha1) fvc::interpolate(thermo1.alphaEff(phase1.turbulence().mut())), he1))
E1Eqn	relax ()
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::div(fvc::absolute(alphaPhi2, alpha2, U2), p)+p fvc::ddt(alpha2) :-alpha2 dpdt) - fvm::laplacian(fvc::interpolate(alpha2) fvc::interpolate(thermo2.alphaEff(phase2.turbulence().mut())), he2))
fvOptions	constrain (E1Eqn)
E1Eqn	solve ()
fvOptions	correct (he1)
fvOptions	constrain (E2Eqn)
fvOptions	correct (he2)
thermo1	correct ()

Variables
volScalarField &	he2 = thermo2.he()
	E1Eqn
	E2Eqn

Function Documentation

◆ Cpv1()

volScalarField Cpv1	(	"Cpv1"	,
		thermo1.	Cpv() )

References thermo1.

◆ Cpv2()

volScalarField Cpv2	(	"Cpv2"	,
		thermo2.	Cpv() )

References thermo2.

◆ Kh()

volScalarField Kh ( fluid. Kh() )

References fluid.

◆ E1Eqn()

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::div(fvc::absolute(alphaPhi1, alpha1, U1), p)+p *fvc::ddt(alpha1) :-alpha1 *dpdt) - fvm::laplacian(fvc::interpolate(alpha1) *fvc::interpolate(thermo1.alphaEff(phase1.turbulence().mut())), he1) )

References alpha1, alphaPhi1, alphaRhoPhi1, contErr1, dpdt, K1, p, phase1, rho1, thermo1, and U1.

◆ relax()

E1Eqn relax ( )

References E1Eqn.

◆ E2Eqn()

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::div(fvc::absolute(alphaPhi2, alpha2, U2), p)+p *fvc::ddt(alpha2) :-alpha2 *dpdt) - fvm::laplacian(fvc::interpolate(alpha2) *fvc::interpolate(thermo2.alphaEff(phase2.turbulence().mut())), he2) )

References alpha2, alphaPhi2, alphaRhoPhi2, contErr2, dpdt, E2Eqn, he2, K2, p, phase2, rho2, thermo2, and U2.

◆ constrain() [1/2]

fvOptions constrain ( E1Eqn )

References E1Eqn, and fvOptions.

◆ solve()

E1Eqn solve ( )

References E1Eqn.

◆ correct() [1/3]

fvOptions correct ( he1 )

References fvOptions.

◆ constrain() [2/2]

fvOptions constrain ( E2Eqn )

References E2Eqn, and fvOptions.

◆ correct() [2/3]

fvOptions correct ( he2 )

References fvOptions, and he2.

◆ correct() [3/3]

thermo1 correct ( )

References thermo1, and thermo2.

Variable Documentation

◆ he2

volScalarField& he2 = thermo2.he()

Definition at line 3 of file EEqns.H.

Referenced by correct(), ThermalPhaseChangePhaseSystem< BasePhaseSystem >::correctInterfaceThermo(), E2Eqn(), OneResistanceHeatTransferPhaseSystem< BasePhaseSystem >::heatTransfer(), and TwoResistanceHeatTransferPhaseSystem< BasePhaseSystem >::heatTransfer().

◆ E1Eqn

E1Eqn

Initial value:

      =
(
    Kh*(thermo2.T() - thermo1.T())
  + Kh*he1/Cpv1
  - fvm::Sp(Kh/Cpv1, he1)
  + alpha1*rho1*(U1&g)
  + fvOptions(alpha1, rho1, he1)
)

Definition at line 34 of file EEqns.H.

Referenced by constrain(), for(), relax(), and solve().

◆ E2Eqn

E2Eqn