diff --git a/applications/solvers/multiphase/twoPhaseEulerFoam/phaseCompressibleTurbulenceModels/kineticTheoryModels/kineticTheoryModel/kineticTheoryModel.C b/applications/solvers/multiphase/twoPhaseEulerFoam/phaseCompressibleTurbulenceModels/kineticTheoryModels/kineticTheoryModel/kineticTheoryModel.C
index 4fdc9a5f8f14c59d9475c97bbc8446a13fd0cda0..8f136cd5936c470fc4edde2934a3ca2ff4088692 100644
--- a/applications/solvers/multiphase/twoPhaseEulerFoam/phaseCompressibleTurbulenceModels/kineticTheoryModels/kineticTheoryModel/kineticTheoryModel.C
+++ b/applications/solvers/multiphase/twoPhaseEulerFoam/phaseCompressibleTurbulenceModels/kineticTheoryModels/kineticTheoryModel/kineticTheoryModel.C
@@ -2,7 +2,7 @@
========= |
\\ / F ield | OpenFOAM: The Open Source CFD Toolbox
\\ / O peration |
- \\ / A nd | Copyright (C) 2011-2014 OpenFOAM Foundation
+ \\ / A nd | Copyright (C) 2011-2015 OpenFOAM Foundation
\\/ M anipulation |
-------------------------------------------------------------------------------
License
@@ -406,7 +406,7 @@ void Foam::RASModels::kineticTheoryModel::correct()
// Particle viscosity (Table 3.2, p.47)
nut_ = viscosityModel_->nu(alpha, Theta_, gs0_, rho, da, e_);
- volScalarField ThetaSqrt(sqrt(Theta_));
+ volScalarField ThetaSqrt("sqrtTheta", sqrt(Theta_));
// Bulk viscosity p. 45 (Lun et al. 1984).
lambda_ = (4.0/3.0)*sqr(alpha)*da*gs0_*(1.0 + e_)*ThetaSqrt/sqrtPi;
@@ -420,6 +420,7 @@ void Foam::RASModels::kineticTheoryModel::correct()
// Dissipation (Eq. 3.24, p.50)
volScalarField gammaCoeff
(
+ "gammaCoeff",
12.0*(1.0 - sqr(e_))
*max(sqr(alpha), residualAlpha_)
*rho*gs0_*(1.0/da)*ThetaSqrt/sqrtPi
@@ -429,9 +430,10 @@ void Foam::RASModels::kineticTheoryModel::correct()
volScalarField beta(phase_.fluid().drag(phase_).K());
// Eq. 3.25, p. 50 Js = J1 - J2
- volScalarField J1(3.0*beta);
+ volScalarField J1("J1", 3.0*beta);
volScalarField J2
(
+ "J2",
0.25*sqr(beta)*da*magSqr(U - Uc_)
/(
max(alpha, residualAlpha_)*rho
@@ -482,9 +484,10 @@ void Foam::RASModels::kineticTheoryModel::correct()
{
// Equilibrium => dissipation == production
// Eq. 4.14, p.82
- volScalarField K1(2.0*(1.0 + e_)*rho*gs0_);
+ volScalarField K1("K1", 2.0*(1.0 + e_)*rho*gs0_);
volScalarField K3
(
+ "K3",
0.5*da*rho*
(
(sqrtPi/(3.0*(3.0 - e_)))
@@ -495,24 +498,27 @@ void Foam::RASModels::kineticTheoryModel::correct()
volScalarField K2
(
+ "K2",
4.0*da*rho*(1.0 + e_)*alpha*gs0_/(3.0*sqrtPi) - 2.0*K3/3.0
);
- volScalarField K4(12.0*(1.0 - sqr(e_))*rho*gs0_/(da*sqrtPi));
+ volScalarField K4("K4", 12.0*(1.0 - sqr(e_))*rho*gs0_/(da*sqrtPi));
volScalarField trD
(
+ "trD",
alpha/(alpha + residualAlpha_)
*fvc::div(this->phi_)
);
- volScalarField tr2D(sqr(trD));
- volScalarField trD2(tr(D & D));
+ volScalarField tr2D("tr2D", sqr(trD));
+ volScalarField trD2("trD2", tr(D & D));
- volScalarField t1(K1*alpha + rho);
- volScalarField l1(-t1*trD);
- volScalarField l2(sqr(t1)*tr2D);
+ volScalarField t1("t1", K1*alpha + rho);
+ volScalarField l1("l1", -t1*trD);
+ volScalarField l2("l2", sqr(t1)*tr2D);
volScalarField l3
(
+ "l3",
4.0
*K4
*alpha
@@ -535,7 +541,7 @@ void Foam::RASModels::kineticTheoryModel::correct()
// particle viscosity (Table 3.2, p.47)
nut_ = viscosityModel_->nu(alpha, Theta_, gs0_, rho, da, e_);
- volScalarField ThetaSqrt(sqrt(Theta_));
+ volScalarField ThetaSqrt("sqrtTheta", sqrt(Theta_));
// Bulk viscosity p. 45 (Lun et al. 1984).
lambda_ = (4.0/3.0)*sqr(alpha)*da*gs0_*(1.0 + e_)*ThetaSqrt/sqrtPi;
@@ -572,4 +578,5 @@ void Foam::RASModels::kineticTheoryModel::correct()
}
}
+
// ************************************************************************* //