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foam-extend4.1-coherent-io/applications/solvers/solidMechanics/elasticIncrAcpSolidFoam/writeFields.H
2014-06-01 20:12:52 +02:00

173 lines
4.3 KiB
C

if (runTime.outputTime() || topoChange)
{
volScalarField sigmaEq
(
IOobject
(
"sigmaEq",
runTime.timeName(),
mesh,
IOobject::NO_READ,
IOobject::AUTO_WRITE
),
sqrt((3.0/2.0)*magSqr(dev(sigma)))
);
Info<< "Max sigmaEq = " << max(sigmaEq).value()
<< endl;
volScalarField epsilonEq
(
IOobject
(
"epsilonEq",
runTime.timeName(),
mesh,
IOobject::NO_READ,
IOobject::AUTO_WRITE
),
sqrt((2.0/3.0)*magSqr(dev(epsilon)))
);
Info<< "Max epsilonEq = " << max(epsilonEq).value()
<< endl;
// Info << "\nCalculate maximal principal stress ..." << flush;
// // Principal stresses
// volVectorField sigmaMax
// (
// IOobject
// (
// "sigmaMax",
// runTime.timeName(),
// mesh,
// IOobject::NO_READ,
// IOobject::AUTO_WRITE
// ),
// mesh,
// dimensionedVector("sigmaMax", dimPressure, vector::zero)
// );
// vectorField& sigmaMaxI = sigmaMax.internalField();
// forAll (sigmaMaxI, cellI)
// {
// vector eValues = eigenValues(sigma.internalField()[cellI]);
// tensor eVectors = eigenVectors(sigma.internalField()[cellI]);
// scalar maxEValue = 0;
// label iMax = -1;
// forAll(eValues, i)
// {
// if (eValues[i] > maxEValue)
// {
// maxEValue = eValues[i];
// iMax = i;
// }
// }
// if (iMax != -1)
// {
// if (iMax == 0)
// {
// sigmaMaxI[cellI] = eVectors.x()*eValues.x();
// }
// else if (iMax == 1)
// {
// sigmaMaxI[cellI] = eVectors.y()*eValues.y();
// }
// else if (iMax == 2)
// {
// sigmaMaxI[cellI] = eVectors.z()*eValues.z();
// }
// }
// }
// //- boundary traction
// volVectorField tractionBoundary
// (
// IOobject
// (
// "tractionBoundary",
// runTime.timeName(),
// mesh,
// IOobject::NO_READ,
// IOobject::AUTO_WRITE
// ),
// mesh,
// dimensionedVector("zero", dimForce/dimArea, vector::zero)
// );
// surfaceVectorField n = mesh.Sf()/mesh.magSf();
// forAll(tractionBoundary.boundaryField(), patchi)
// {
// if(mesh.boundaryMesh()[patchi].type() != processorPolyPatch::typeName)
// {
// tractionBoundary.boundaryField()[patchi] =
// n.boundaryField()[patchi] & sigma.boundaryField()[patchi];
// }
// }
//- cohesive damage and cracking, and GII and GII
volScalarField damageAndCracks
(
IOobject
(
"damageAndCracks",
runTime.timeName(),
mesh,
IOobject::NO_READ,
IOobject::AUTO_WRITE
),
mesh,
dimensionedScalar("zero", dimless, 0.0),
calculatedFvPatchVectorField::typeName
);
volScalarField GI
(
IOobject
(
"GI",
runTime.timeName(),
mesh,
IOobject::NO_READ,
IOobject::AUTO_WRITE
),
mesh,
dimensionedScalar("zero", dimless, 0.0),
calculatedFvPatchVectorField::typeName
);
volScalarField GII
(
IOobject
(
"GII",
runTime.timeName(),
mesh,
IOobject::NO_READ,
IOobject::AUTO_WRITE
),
mesh,
dimensionedScalar("zero", dimless, 0.0),
calculatedFvPatchVectorField::typeName
);
forAll(DU.boundaryField(), patchi)
{
// if(DU.boundaryField()[patchi].type() == cohesiveLawMultiMatFvPatchVectorField::typeName)
if(DU.boundaryField()[patchi].type() == solidCohesiveFvPatchVectorField::typeName)
{
// cohesiveLawMultiMatFvPatchVectorField& DUpatch =
// refCast<cohesiveLawMultiMatFvPatchVectorField>(DU.boundaryField()[patchi]);
solidCohesiveFvPatchVectorField& DUpatch =
refCast<solidCohesiveFvPatchVectorField>(DU.boundaryField()[patchi]);
GI.boundaryField()[patchi] = DUpatch.GI();
GII.boundaryField()[patchi] = DUpatch.GII();
damageAndCracks.boundaryField()[patchi] = DUpatch.crackingAndDamage();
}
}
//Info << "done" << endl;
runTime.writeNow();
}