Functions
volScalarField	kByCp2 ("kByCp2", alpha2 *(k2/Cp2/rho2+nut2/Prt))
fvScalarMatrix	T1Eqn (fvm::ddt(alpha1, T1)+fvm::div(alphaPhi1, T1) - fvm::laplacian(kByCp1, T1)==heatTransferCoeff T2/Cp1/rho1 - fvm::Sp(heatTransferCoeff/Cp1/rho1, T1)+alpha1 Dp1Dt/Cp1/rho1)
fvScalarMatrix	T2Eqn (fvm::ddt(alpha2, T2)+fvm::div(alphaPhi2, T2) - fvm::laplacian(kByCp2, T2)==heatTransferCoeff T1/Cp2/rho2 - fvm::Sp(heatTransferCoeff/Cp2/rho2, T2)+alpha2 Dp2Dt/Cp2/rho2)
T1Eqn	relax ()
T1Eqn	solve ()

Variables
	psi1 = 1.0/(R1*T1)
	psi2 = 1.0/(R2*T2)

Function Documentation

◆ kByCp2()

volScalarField kByCp2	(	"kByCp2"	,
		alpha2 *	k2/Cp2/rho2+nut2/Prt )

References alpha2, Cp2, Prt(), and rho2.

Referenced by T2Eqn().

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◆ T1Eqn()

fvScalarMatrix T1Eqn ( fvm::ddt(alpha1, T1)+fvm::div(alphaPhi1, T1) - fvm::laplacian(kByCp1, T1) = =heatTransferCoeff *T2/Cp1/rho1 - fvm::Sp(heatTransferCoeff/Cp1/rho1, T1)+alpha1 *Dp1Dt/Cp1/rho1 )

References alpha1, alphaPhi1, Cp1, and rho1.

Referenced by relax(), and solve().

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◆ T2Eqn()

fvScalarMatrix T2Eqn ( fvm::ddt(alpha2, T2)+fvm::div(alphaPhi2, T2) - fvm::laplacian(kByCp2, T2) = =heatTransferCoeff *T1/Cp2/rho2 - fvm::Sp(heatTransferCoeff/Cp2/rho2, T2)+alpha2 *Dp2Dt/Cp2/rho2 )

References alpha2, alphaPhi2, Cp2, kByCp2(), and rho2.

Referenced by solve().

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◆ relax()

T1Eqn relax ( )

References T1Eqn().

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◆ solve()

T1Eqn solve ( )

References T1Eqn(), and T2Eqn().

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Variable Documentation

◆ psi1

psi1 = 1.0/(R1*T1)

Definition at line 34 of file TEqns.H.

◆ psi2

psi2 = 1.0/(R2*T2)

Definition at line 35 of file TEqns.H.

Functions

Variables

Function Documentation

◆ kByCp2()

◆ T1Eqn()

◆ T2Eqn()

◆ relax()

◆ solve()

Variable Documentation

◆ psi1

◆ psi2