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henry
2009-01-20 16:31:48 +00:00
parent d29e728814 372cd1b0e6
commit f97160ba7a
14 changed files with 267 additions and 181 deletions
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15
applications/solvers/combustion/dieselEngineFoam/spraySummary.H
View File

@ -1,19 +1,20 @@
label Nparcels = dieselSpray.size();
reduce(Nparcels, sumOp<label>());
Info<< "\nNumber of parcels in system | "
Info<< "\nNumber of parcels in system.... | "
<< Nparcels << endl
<< "Injected liquid mass....... | "
<< "Injected liquid mass........... | "
<< 1e6*dieselSpray.injectedMass(runTime.value()) << " mg" << endl
<< "Liquid Mass in system...... | "
<< "Liquid Mass in system.......... | "
<< 1e6*dieselSpray.liquidMass() << " mg" << endl
<< "SMD, Dmax.................. | "
<< "SMD, Dmax...................... | "
<< dieselSpray.smd()*1e6 << " mu, "
<< dieselSpray.maxD()*1e6 << " mu"
<< endl;
scalar evapMass =
dieselSpray.injectedMass(runTime.value()) - dieselSpray.liquidMass();
dieselSpray.injectedMass(runTime.value())
- dieselSpray.liquidMass();
scalar gasMass = fvc::domainIntegrate(rho).value();
@ -26,6 +27,6 @@
scalar addedMass = gasMass - gasMass0;
Info<< "Added gas mass = " << 1e6*addedMass << " mg" << nl
<< "Evaporation Continuity Error| "
Info<< "Added gas mass................. | " << 1e6*addedMass << " mg"
<< nl << "Evaporation Continuity Error... | "
<< 1e6*(addedMass - evapMass) << " mg" << endl;

49
applications/utilities/postProcessing/patch/patchIntegrate/patchIntegrate.C
View File

@ -31,6 +31,7 @@ Description
\*---------------------------------------------------------------------------*/
#include "fvCFD.H"
#include "cyclicPolyPatch.H"
// * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * //
// Main program:
@ -75,13 +76,37 @@ int main(int argc, char *argv[])
}
// Give patch area
Info<< " Patch area = " << gSum(mesh.Sf().boundaryField()[patchi]) << endl;
if (fieldHeader.headerClassName() == "volScalarField")
if (isType<cyclicPolyPatch>(mesh.boundaryMesh()[patchi]))
{
Info<< " Reading volScalarField " << fieldName << endl;
volScalarField field(fieldHeader, mesh);
Info<< " Cyclic patch area: " << nl;
label nFaces = mesh.boundaryMesh()[patchi].size();
vector sum1 = vector::zero;
vector sum2 = vector::zero;
for (label i=0; i<nFaces/2; i++)
{
sum1 += mesh.Sf().boundaryField()[patchi][i];
sum2 += mesh.Sf().boundaryField()[patchi][i+nFaces/2];
}
reduce(sum1, sumOp<vector>());
reduce(sum2, sumOp<vector>());
Info<< " - half 1 = " << sum1 << ", " << mag(sum1) << nl
<< " - half 2 = " << sum2 << ", " << mag(sum2) << nl
<< " - total = " << (sum1 + sum2) << ", "
<< mag(sum1 + sum2) << endl;;
}
else
{
Info<< " Patch area = "
<< gSum(mesh.Sf().boundaryField()[patchi]) << endl;
}
// Read field and calc integral
if (fieldHeader.headerClassName() == volScalarField::typeName)
{
Info<< " Reading " << volScalarField::typeName << " "
<< fieldName << endl;
volScalarField field(fieldHeader, mesh);
vector sumField = gSum
(
mesh.Sf().boundaryField()[patchi]
@ -92,9 +117,13 @@ int main(int argc, char *argv[])
<< patchName << '[' << patchi << ']' << " = "
<< sumField << nl;
}
else if (fieldHeader.headerClassName() == "surfaceScalarField")
else if
(
fieldHeader.headerClassName() == surfaceScalarField::typeName
)
{
Info<< " Reading surfaceScalarField " << fieldName << endl;
Info<< " Reading " << surfaceScalarField::typeName << " "
<< fieldName << endl;
surfaceScalarField field(fieldHeader, mesh);
scalar sumField = gSum(field.boundaryField()[patchi]);
@ -106,8 +135,10 @@ int main(int argc, char *argv[])
else
{
FatalError
<< "Only possible to integrate volScalarFields "
<< "and surfaceScalarFields" << nl << exit(FatalError);
<< "Only possible to integrate "
<< volScalarField::typeName << "s "
<< "and " << surfaceScalarField::typeName << "s"
<< nl << exit(FatalError);
}
}
else

1
src/finiteVolume/cfdTools/general/bound/bound.C
View File

@ -53,7 +53,6 @@ void Foam::bound(volScalarField& vsf, const dimensionedScalar& vsf0)
vsf0.value()
);
vsf.correctBoundaryConditions();
vsf.boundaryField() = max(vsf.boundaryField(), vsf0.value());
}
}

2
src/finiteVolume/cfdTools/general/include/setDeltaT.H
View File

@ -27,7 +27,7 @@ Global
Description
Reset the timestep to maintain a constant maximum courant Number.
Reduction of time-step is imediate but increase is damped to avoid
Reduction of time-step is immediate, but increase is damped to avoid
unstable oscillations.
\*---------------------------------------------------------------------------*/

2
src/finiteVolume/cfdTools/general/include/setInitialDeltaT.H
View File

@ -33,7 +33,7 @@ Description
if (adjustTimeStep)
{
if (CoNum > SMALL)
if ((runTime.timeIndex() == 0) && (CoNum > SMALL))
{
runTime.setDeltaT
(

90
src/lagrangian/dieselSpray/injector/unitInjector/unitInjector.C
View File

@ -30,9 +30,9 @@ License
#include "mathematicalConstants.H"
// * * * * * * * * * * * * * * Static Data Members * * * * * * * * * * * * * //
namespace Foam
{
defineTypeNameAndDebug(unitInjector, 0);
addToRunTimeSelectionTable
@ -42,7 +42,7 @@ addToRunTimeSelectionTable
dictionary
);
}
// * * * * * * * * * * * * * Private Member Functions * * * * * * * * * * * //
// * * * * * * * * * * * * * * * * Constructors * * * * * * * * * * * * * * //
@ -74,22 +74,32 @@ Foam::unitInjector::unitInjector
// check if time entries for soi and eoi match
if (mag(massFlowRateProfile_[0][0]-TProfile_[0][0]) > SMALL)
{
FatalError << "unitInjector::unitInjector(const time& t, const dictionary dict) " << endl
<< " start-times do not match for TemperatureProfile and massFlowRateProfile."
<< abort(FatalError);
FatalErrorIn
(
"unitInjector::unitInjector(const time& t, const dictionary dict)"
)<< "start-times do not match for TemperatureProfile and "
<< " massFlowRateProfile." << nl << exit (FatalError);
}
if (mag(massFlowRateProfile_[massFlowRateProfile_.size()-1][0]-TProfile_[TProfile_.size()-1][0]) > SMALL)
if
(
mag(massFlowRateProfile_[massFlowRateProfile_.size()-1][0]
- TProfile_[TProfile_.size()-1][0])
> SMALL
)
{
FatalError << "unitInjector::unitInjector(const time& t, const dictionary dict) " << endl
<< " end-times do not match for TemperatureProfile and massFlowRateProfile."
<< abort(FatalError);
FatalErrorIn
(
"unitInjector::unitInjector(const time& t, const dictionary dict)"
)<< "end-times do not match for TemperatureProfile and "
<< "massFlowRateProfile." << nl << exit(FatalError);
}
// convert CA to real time
forAll(massFlowRateProfile_, i)
{
massFlowRateProfile_[i][0] = t.userTimeToTime(massFlowRateProfile_[i][0]);
massFlowRateProfile_[i][0] =
t.userTimeToTime(massFlowRateProfile_[i][0]);
velocityProfile_[i][0] = massFlowRateProfile_[i][0];
injectionPressureProfile_[i][0] = massFlowRateProfile_[i][0];
}
@ -124,9 +134,9 @@ Foam::unitInjector::unitInjector
if (mag(Xsum - 1.0) > SMALL)
{
Info << "Warning!!!\n unitInjector::unitInjector(const time& t, Istream& is)"
<< "X does not add up to 1.0, correcting molar fractions."
<< endl;
WarningIn("unitInjector::unitInjector(const time& t, Istream& is)")
<< "X does not sum to 1.0, correcting molar fractions."
<< nl << endl;
forAll(X_, i)
{
X_[i] /= Xsum;
@ -169,18 +179,18 @@ Foam::label Foam::unitInjector::nParcelsToInject
const scalar time1
) const
{
scalar mInj = mass_*(fractionOfInjection(time1)-fractionOfInjection(time0));
label nParcels = label(mInj/averageParcelMass_ + 0.49);
return nParcels;
}
const Foam::vector Foam::unitInjector::position(const label n) const
{
return position_;
}
Foam::vector Foam::unitInjector::position
(
const label n,
@ -226,16 +236,19 @@ Foam::vector Foam::unitInjector::position
return position_;
}
Foam::label Foam::unitInjector::nHoles() const
{
return 1;
}
Foam::scalar Foam::unitInjector::d() const
{
return d_;
}
const Foam::vector& Foam::unitInjector::direction
(
const label i,
@ -245,6 +258,7 @@ const Foam::vector& Foam::unitInjector::direction
return direction_;
}
Foam::scalar Foam::unitInjector::mass
(
const scalar time0,
@ -264,82 +278,80 @@ Foam::scalar Foam::unitInjector::mass
return mInj;
}
Foam::scalar Foam::unitInjector::mass() const
{
return mass_;
}
const Foam::scalarField& Foam::unitInjector::X() const
{
return X_;
}
Foam::List<Foam::unitInjector::pair> Foam::unitInjector::T() const
{
return TProfile_;
}
Foam::scalar Foam::unitInjector::T(const scalar time) const
{
return getTableValue(TProfile_, time);
}
Foam::scalar Foam::unitInjector::tsoi() const
{
return massFlowRateProfile_[0][0];
}
Foam::scalar Foam::unitInjector::teoi() const
{
return massFlowRateProfile_[massFlowRateProfile_.size()-1][0];
}
Foam::scalar Foam::unitInjector::massFlowRate
(
const scalar time
) const
Foam::scalar Foam::unitInjector::massFlowRate(const scalar time) const
{
return getTableValue(massFlowRateProfile_, time);
}
Foam::scalar Foam::unitInjector::injectionPressure
(
const scalar time
) const
Foam::scalar Foam::unitInjector::injectionPressure(const scalar time) const
{
return getTableValue(injectionPressureProfile_, time);
}
Foam::scalar Foam::unitInjector::velocity
(
const scalar time
) const
Foam::scalar Foam::unitInjector::velocity(const scalar time) const
{
return getTableValue(velocityProfile_, time);
}
Foam::List<Foam::unitInjector::pair> Foam::unitInjector::CdProfile() const
{
return CdProfile_;
}
Foam::scalar Foam::unitInjector::Cd
(
const scalar time
) const
Foam::scalar Foam::unitInjector::Cd(const scalar time) const
{
return Cd_;
}
Foam::scalar Foam::unitInjector::fractionOfInjection(const scalar time) const
{
return integrateTable(massFlowRateProfile_, time)/mass_;
}
Foam::scalar Foam::unitInjector::injectedMass
(
const scalar t
) const
Foam::scalar Foam::unitInjector::injectedMass(const scalar t) const
{
return mass_*fractionOfInjection(t);
}
@ -351,7 +363,6 @@ void Foam::unitInjector::correctProfiles
const scalar referencePressure
)
{
scalar A = 0.25*mathematicalConstant::pi*pow(d_, 2.0);
scalar pDummy = 1.0e+5;
@ -365,14 +376,17 @@ void Foam::unitInjector::correctProfiles
}
}
Foam::vector Foam::unitInjector::tan1(const label n) const
Foam::vector Foam::unitInjector::tan1(const label) const
{
return tangentialInjectionVector1_;
}
Foam::vector Foam::unitInjector::tan2(const label n) const
Foam::vector Foam::unitInjector::tan2(const label) const
{
return tangentialInjectionVector2_;
}
// ************************************************************************* //

16
src/lagrangian/dieselSpray/spray/sprayInject.C
View File

@ -66,11 +66,7 @@ void spray::inject()
// constT is only larger than zero for the first
// part of the injection
scalar constT = max
(
0.0,
it->tsoi() - time0
);
scalar constT = max(0.0, it->tsoi() - time0);
// deltaT is the duration of injection during this timestep
scalar deltaT = min
@ -105,7 +101,8 @@ void spray::inject()
);
scalar diameter = injection().d0(i, toi);
vector direction = injection().direction(i, n, toi, diameter);
vector direction =
injection().direction(i, n, toi, diameter);
vector U = injection().velocity(i, toi)*direction;
scalar symComponent = direction & axisOfSymmetry_;
@ -148,7 +145,7 @@ void spray::inject()
fuels_->components()
);
injectedLiquidKE_ += 0.5*pPtr->m()*pow(mag(U), 2.0);
injectedLiquidKE_ += 0.5*pPtr->m()*magSqr(U);
scalar dt = time - toi;
@ -156,10 +153,7 @@ void spray::inject()
(runTime_.deltaT().value() - dt)
/runTime_.deltaT().value();
bool keepParcel = pPtr->move
(
*this
);
bool keepParcel = pPtr->move(*this);
if (keepParcel)
{

14
src/lagrangian/dieselSpray/spray/sprayOps.C
View File

@ -89,12 +89,7 @@ void spray::move()
void spray::breakupLoop()
{
for
(
spray::iterator elmnt = begin();
elmnt != end();
++elmnt
)
forAllIter(spray::iterator, *this, elmnt)
{
// interpolate...
vector velocity = UInterpolator().interpolate
@ -128,12 +123,7 @@ void spray::breakupLoop()
void spray::atomizationLoop()
{
for
(
spray::iterator elmnt = begin();
elmnt != end();
++elmnt
)
forAllIter(spray::iterator, *this, elmnt)
{
// interpolate...
vector velocity = UInterpolator().interpolate

61
src/lagrangian/dieselSpray/spraySubModels/breakupModel/reitzKHRT/reitzKHRT.C
View File

@ -108,31 +108,19 @@ void reitzKHRT::breakupParcel
// frequency of the fastest growing KH-wave
scalar omegaKH =
(
0.34 + 0.38*pow(weGas, 1.5)
)/
(
(1 + ohnesorge)*(1 + 1.4*pow(taylor, 0.6))
)*sqrt(sigma/(rhoLiquid*pow(r, 3)) );
(0.34 + 0.38*pow(weGas, 1.5))
/((1 + ohnesorge)*(1 + 1.4*pow(taylor, 0.6)))
*sqrt(sigma/(rhoLiquid*pow(r, 3)));
// ... and the corresponding KH wave-length.
// corresponding KH wave-length.
scalar lambdaKH =
9.02*r*
(
1.0 + 0.45*sqrt(ohnesorge)
)*
(
1.0 + 0.4*pow(taylor, 0.7)
)/
pow
(
(
1.0 + 0.865*pow(weGas, 1.67)
),
0.6
);
9.02
*r
*(1.0 + 0.45*sqrt(ohnesorge))
*(1.0 + 0.4*pow(taylor, 0.7))
/pow(1.0 + 0.865*pow(weGas, 1.67), 0.6);
// the characteristic Kelvin-Helmholtz breakup time
// characteristic Kelvin-Helmholtz breakup time
scalar tauKH = 3.726*b1_*r/(omegaKH*lambdaKH);
// stable KH diameter
@ -140,7 +128,6 @@ void reitzKHRT::breakupParcel
// the frequency of the fastest growing RT wavelength.
scalar helpVariable = mag(gt*(rhoLiquid - rhoGas));
scalar omegaRT = sqrt
(
2.0*pow(helpVariable, 1.5)
@ -148,12 +135,9 @@ void reitzKHRT::breakupParcel
);
// RT wave number
scalar KRT = sqrt
(
helpVariable/(3.0*sigma + VSMALL)
);
scalar KRT = sqrt(helpVariable/(3.0*sigma + VSMALL));
// the wavelength of the fastest growing Raleigh-Taylor frequency
// wavelength of the fastest growing RT frequency
scalar lambdaRT = 2.0*mathematicalConstant::pi*cRT_/(KRT + VSMALL);
// if lambdaRT < diameter, then RT waves are growing on the surface
@ -163,7 +147,7 @@ void reitzKHRT::breakupParcel
p.ct() += deltaT;
}
// the characteristic RT breakup time
// characteristic RT breakup time
scalar tauRT = cTau_/(omegaRT + VSMALL);
// check if we have RT breakup
@ -178,7 +162,7 @@ void reitzKHRT::breakupParcel
// otherwise check for KH breakup
else if (dc < p.d())
{
// no breakup below weber = 12
// no breakup below Weber = 12
if (weGas > weberLimit_)
{
@ -188,25 +172,24 @@ void reitzKHRT::breakupParcel
// reduce the diameter according to the rate-equation
p.d() = (fraction*dc + p.d())/(1.0 + fraction);
scalar dc3 = pow(dc, 3.0);
scalar ms = rhoLiquid*Np*dc3*mathematicalConstant::pi/6.0;
scalar ms = rhoLiquid*Np*pow3(dc)*mathematicalConstant::pi/6.0;
p.ms() += ms;
label nParcels = spray_.injectors()[injector].properties()->nParcelsToInject
// Total number of parcels for the whole injection event
label nParcels =
spray_.injectors()[injector].properties()->nParcelsToInject
(
spray_.injectors()[injector].properties()->tsoi(),
spray_.injectors()[injector].properties()->teoi()
);
scalar averageParcelMass = spray_.injectors()[injector].properties()->mass()/nParcels;
scalar averageParcelMass =
spray_.injectors()[injector].properties()->mass()/nParcels;
if
(
(p.ms()/averageParcelMass > msLimit_)
)
if (p.ms()/averageParcelMass > msLimit_)
{
// set the initial ms value to -GREAT. This prevents
// new droplets from being formed from the childDroplet
// new droplets from being formed from the child droplet
// from the KH instability
// mass of stripped child parcel

21
src/postProcessing/functionObjects/field/fieldMinMax/fieldMinMax.C
View File

@ -38,6 +38,18 @@ namespace Foam
}
template<>
const char* Foam::NamedEnum<Foam::fieldMinMax::modeType, 2>::names[] =
{
"magnitude",
"component"
};
const Foam::NamedEnum<Foam::fieldMinMax::modeType, 2>
Foam::fieldMinMax::modeTypeNames_;
// * * * * * * * * * * * * * * * * Constructors * * * * * * * * * * * * * * //
Foam::fieldMinMax::fieldMinMax
@ -52,6 +64,7 @@ Foam::fieldMinMax::fieldMinMax
obr_(obr),
active_(true),
log_(false),
mode_(mdMag),
fieldSet_(),
fieldMinMaxFilePtr_(NULL)
{
@ -85,6 +98,7 @@ void Foam::fieldMinMax::read(const dictionary& dict)
{
log_ = dict.lookupOrDefault<Switch>("log", false);
mode_ = modeTypeNames_[dict.lookup("mode")];
dict.lookup("fields") >> fieldSet_;
}
}
@ -175,17 +189,14 @@ void Foam::fieldMinMax::calcMinMaxFields<Foam::scalar>
)
{
if (obr_.foundObject<volScalarField>(fieldName))
{
if (Pstream::master())
{
const volScalarField& field =
obr_.lookupObject<volScalarField>(fieldName);
scalar minValue = min(field).value();
scalar maxValue = max(field).value();
reduce(minValue, minOp<scalar>());
reduce(maxValue, maxOp<scalar>());
if (Pstream::master())
{
fieldMinMaxFilePtr_() << obr_.time().value() << tab
<< fieldName << tab << minValue << tab << maxValue << endl;

22
src/postProcessing/functionObjects/field/fieldMinMax/fieldMinMax.H
View File

@ -49,6 +49,7 @@ SourceFiles
#include "OFstream.H"
#include "Switch.H"
#include "pointFieldFwd.H"
#include "NamedEnum.H"
// * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * //
@ -66,9 +67,18 @@ class mapPolyMesh;
class fieldMinMax
{
public:
enum modeType
{
mdMag,
mdCmpt
};
protected:
// Private data
// Protected data
//- Name of this set of forces,
// Also used as the name of the probes directory.
@ -82,11 +92,17 @@ protected:
//- Switch to send output to Info as well as to file
Switch log_;
//- Patches to integrate forces over
//- Mode type names
static const NamedEnum<modeType, 2> modeTypeNames_;
//- Mode for min/max - only applicable for ranks > 0
modeType mode_;
//- Fields to assess min/max
wordList fieldSet_;
//- Forces/moment file ptr
//- Min/max file ptr
autoPtr<OFstream> fieldMinMaxFilePtr_;

52
src/postProcessing/functionObjects/field/fieldMinMax/fieldMinMaxTemplates.C
View File

@ -37,26 +37,62 @@ void Foam::fieldMinMax::calcMinMaxFields(const word& fieldName)
typedef GeometricField<Type, fvPatchField, volMesh> fieldType;
if (obr_.foundObject<fieldType>(fieldName))
{
if (Pstream::master())
{
const fieldType& field = obr_.lookupObject<fieldType>(fieldName);
switch (mode_)
{
case mdMag:
{
scalar minValue = min(mag(field)).value();
scalar maxValue = max(mag(field)).value();
reduce(minValue, minOp<scalar>());
reduce(maxValue, maxOp<scalar>());
if (Pstream::master())
{
fieldMinMaxFilePtr_() << obr_.time().value() << tab
<< fieldName << tab << minValue << tab << maxValue << endl;
<< fieldName << tab << minValue << tab << maxValue
<< endl;
if (log_)
{
Info<< "fieldMinMax output:" << nl
<< " min(mag(" << fieldName << ")) = " << minValue << nl
<< " max(mag(" << fieldName << ")) = " << maxValue << nl
<< " min(mag(" << fieldName << ")) = "
<< minValue << nl
<< " max(mag(" << fieldName << ")) = "
<< maxValue << nl
<< endl;
}
break;
}
case mdCmpt:
{
Type minValue = min(field).value();
Type maxValue = max(field).value();
fieldMinMaxFilePtr_() << obr_.time().value() << tab
<< fieldName << tab << minValue << tab << maxValue
<< endl;
if (log_)
{
Info<< "fieldMinMax output:" << nl
<< " cmptMin(" << fieldName << ") = "
<< minValue << nl
<< " cmptMax(" << fieldName << ") = "
<< maxValue << nl
<< endl;
}
break;
}
default:
{
FatalErrorIn
(
"Foam::fieldMinMax::calcMinMaxFields"
"(const word& fieldName)"
)<< "Unknown min/max mode: " << modeTypeNames_[mode_]
<< exit(FatalError);
}
}
}
}
}

4
tutorials/dieselFoam/aachenBomb/constant/turbulenceProperties
View File

@ -14,6 +14,10 @@ FoamFile
}
// * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * //
<<<<<<< HEAD:tutorials/dieselFoam/aachenBomb/constant/turbulenceProperties
simulationType RASModel;
=======
simulationType RASModel;
>>>>>>> c2eac7aaca53e9702c56bbbbd2c0dc47a83829e0:tutorials/dieselFoam/aachenBomb/constant/turbulenceProperties
// ************************************************************************* //

21
tutorials/dieselFoam/aachenBomb/system/fvSolution
View File

@ -16,44 +16,51 @@ FoamFile
solvers
{
rho PCG
rho
{
solver PCG;
preconditioner DIC;
tolerance 1e-06;
relTol 0;
};
U PBiCG
U
{
solver PBiCG;
preconditioner DILU;
tolerance 1e-06;
relTol 0;
};
p PCG
p
{
solver PCG;
preconditioner DIC;
tolerance 1e-09;
relTol 0;
};
Yi PBiCG
Yi
{
solver PBiCG;
preconditioner DILU;
tolerance 1e-06;
relTol 0;
};
h PBiCG
h
{
solver PBiCG;
preconditioner DILU;
tolerance 1e-06;
relTol 0;
};
k PBiCG
k
{
solver PBiCG;
preconditioner DILU;
tolerance 1e-06;
relTol 0;
};
epsilon PBiCG
epsilon
{
solver PBiCG;
preconditioner DILU;
tolerance 1e-06;
relTol 0;