diff --git a/applications/solvers/multiphase/multiphaseEulerFoam/multiphaseSystem/multiphaseSystem.C b/applications/solvers/multiphase/multiphaseEulerFoam/multiphaseSystem/multiphaseSystem.C
index 2203d6e144f4f96f40aec455caf25aff374d0598..767600e394011a6cedce9e0b389ee4b489034b92 100644
--- a/applications/solvers/multiphase/multiphaseEulerFoam/multiphaseSystem/multiphaseSystem.C
+++ b/applications/solvers/multiphase/multiphaseEulerFoam/multiphaseSystem/multiphaseSystem.C
@@ -888,7 +888,7 @@ void Foam::multiphaseSystem::solve()
dimensionedScalar totalDeltaT = runTime.deltaT();
PtrList<volScalarField> alpha0s(phases_.size());
- PtrList<surfaceScalarField> phiSums(phases_.size());
+ PtrList<surfaceScalarField> alphaPhiSums(phases_.size());
int phasei = 0;
forAllIter(PtrDictionary<phaseModel>, phases_, iter)
@@ -902,7 +902,7 @@ void Foam::multiphaseSystem::solve()
new volScalarField(alpha.oldTime())
);
- phiSums.set
+ alphaPhiSums.set
(
phasei,
new surfaceScalarField
@@ -936,7 +936,7 @@ void Foam::multiphaseSystem::solve()
int phasei = 0;
forAllIter(PtrDictionary<phaseModel>, phases_, iter)
{
- phiSums[phasei] += (runTime.deltaT()/totalDeltaT)*iter().phi();
+ alphaPhiSums[phasei] += iter().alphaPhi()/nAlphaSubCycles;
phasei++;
}
}
@@ -947,7 +947,7 @@ void Foam::multiphaseSystem::solve()
phaseModel& phase = iter();
volScalarField& alpha = phase;
- phase.phi() = phiSums[phasei];
+ phase.alphaPhi() = alphaPhiSums[phasei];
// Correct the time index of the field
// to correspond to the global time
diff --git a/applications/solvers/multiphase/reactingEulerFoam/reactingMultiphaseEulerFoam/multiphaseSystem/multiphaseSystem.C b/applications/solvers/multiphase/reactingEulerFoam/reactingMultiphaseEulerFoam/multiphaseSystem/multiphaseSystem.C
index 5512fd655999faf20d8745b1bd65df923a560fed..d92368a8867d804d190690b4504e0c199be2f6ad 100644
--- a/applications/solvers/multiphase/reactingEulerFoam/reactingMultiphaseEulerFoam/multiphaseSystem/multiphaseSystem.C
+++ b/applications/solvers/multiphase/reactingEulerFoam/reactingMultiphaseEulerFoam/multiphaseSystem/multiphaseSystem.C
@@ -157,7 +157,7 @@ void Foam::multiphaseSystem::solveAlphas()
MULES::limit
(
- 1.0/mesh_.time().deltaT().value(),
+ 1.0/mesh_.time().deltaT().value(), // ***HGW add support for LTS
geometricOneField(),
phase,
phi_,
@@ -620,7 +620,7 @@ void Foam::multiphaseSystem::solve()
dimensionedScalar totalDeltaT = runTime.deltaT();
PtrList<volScalarField> alpha0s(phases().size());
- PtrList<surfaceScalarField> phiSums(phases().size());
+ PtrList<surfaceScalarField> alphaPhiSums(phases().size());
forAll(phases(), phasei)
{
@@ -633,7 +633,7 @@ void Foam::multiphaseSystem::solve()
new volScalarField(alpha.oldTime())
);
- phiSums.set
+ alphaPhiSums.set
(
phasei,
new surfaceScalarField
@@ -664,7 +664,7 @@ void Foam::multiphaseSystem::solve()
forAll(phases(), phasei)
{
- phiSums[phasei] += phases()[phasei].phi();
+ alphaPhiSums[phasei] += phases()[phasei].alphaPhi();
}
}
@@ -673,7 +673,7 @@ void Foam::multiphaseSystem::solve()
phaseModel& phase = phases()[phasei];
volScalarField& alpha = phase;
- phase.phi() = phiSums[phasei]/nAlphaSubCycles;
+ phase.alphaPhi() = alphaPhiSums[phasei]/nAlphaSubCycles;
// Correct the time index of the field
// to correspond to the global time