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

114 lines
3.5 KiB
C

if (runTime.outputTime())
{
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;
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;
pointMesh pMesh(mesh);
pointScalarField contactPointGap
(
IOobject
(
"contactPointGap",
runTime.timeName(),
mesh,
IOobject::NO_READ,
IOobject::AUTO_WRITE
),
pMesh,
dimensionedScalar("zero", dimless, 0.0)
);
forAll(mesh.boundary(), patchi)
{
if(DU.boundaryField()[patchi].type() == solidContactFvPatchVectorField::typeName)
{
const solidContactFvPatchVectorField& DUpatch =
refCast<const solidContactFvPatchVectorField>
(DU.boundaryField()[patchi]);
if(!DUpatch.master())
{
const labelList& meshPoints = mesh.boundaryMesh()[patchi].meshPoints();
const scalarField gap = DUpatch.normalContactModelPtr()->slaveContactPointGap();
forAll(meshPoints, pointi)
{
contactPointGap[meshPoints[pointi]] = gap[pointi];
}
}
}
}
//- total force
/* forAll(mesh.boundary(), patchi)
{
Info << "Patch " << mesh.boundary()[patchi].name() << endl;
vectorField totalForce = mesh.Sf().boundaryField()[patchi] & sigma.boundaryField()[patchi];
vector force = sum( totalForce );
Info << "\ttotal force is " << force << " N" << endl;
tensorField F = I + gradDU.boundaryField()[patchi];
tensorField Finv = inv(F);
//vectorField nCurrent = Finv & n.boundaryField()[patchi];
//nCurrent /= mag(nCurrent);
//scalar normalForce = sum( nCurrent & totalForce );
scalar normalForce = sum( n.boundaryField()[patchi] & totalForce );
Info << "\tnormal force is " << normalForce << " N" << endl;
//scalar shearForce = mag(sum( (I - sqr(nCurrent)) & totalForce ));
scalar shearForce = mag(sum( (I - sqr(n.boundaryField()[patchi])) & totalForce ));
Info << "\tshear force is " << shearForce << " N" << endl;
// if(mesh.boundary()[patchi].type() != "empty")
// {
// vector Sf0 = Sf.boundaryField()[patchi][0];
// symmTensor sigma0 = sigma.boundaryField()[patchi][0];
// Info << "sigmab[0] is " << sigma0 << nl
// << "Sfb is " << Sf0 << nl
// << "force is " << (Sf.boundaryField()[patchi][0]&sigma.boundaryField()[patchi][0]) << nl
// << "Sfx*sigmaxx " << (Sf0[vector::X]*sigma0[symmTensor::XX]) << nl
// << "Sfy*sigmaxy " << (Sf0[vector::Y]*sigma0[symmTensor::XY]) << nl
// << "Sfx*sigmayx " << (Sf0[vector::X]*sigma0[symmTensor::XY]) << nl
// << "Sfy*sigmayy " << (Sf0[vector::Y]*sigma0[symmTensor::YY]) << nl
// << endl;
//vector SfTL(-0.000137451, 0.00383599, -4.76878e-20);
// vector SfTL = Finv[0] & vector(0,0.004,0);
// Info << "SfTLx*sigmaxx " << (SfTL[vector::X]*sigma0[symmTensor::XX]) << nl
// << "SfTLy*sigmaxy " << (SfTL[vector::Y]*sigma0[symmTensor::XY]) << nl
// << "SfTLx*sigmayx " << (SfTL[vector::X]*sigma0[symmTensor::XY]) << nl
// << "SfTLy*sigmayy " << (SfTL[vector::Y]*sigma0[symmTensor::YY]) << nl
// << endl;
// }
}*/
runTime.write();
}