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OpenFOAM-12/applications/modules/solidDisplacement/solidDisplacement.C

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/*---------------------------------------------------------------------------*\
========= |
\\ / F ield | OpenFOAM: The Open Source CFD Toolbox
\\ / O peration | Website: https://openfoam.org
\\ / A nd | Copyright (C) 2023 OpenFOAM Foundation
\\/ M anipulation |
-------------------------------------------------------------------------------
License
This file is part of OpenFOAM.
OpenFOAM is free software: you can redistribute it and/or modify it
under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.
OpenFOAM is distributed in the hope that it will be useful, but WITHOUT
ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
for more details.
You should have received a copy of the GNU General Public License
along with OpenFOAM. If not, see <http://www.gnu.org/licenses/>.
\*---------------------------------------------------------------------------*/
#include "solidDisplacement.H"
#include "fvcGrad.H"
#include "fvcDiv.H"
#include "fvcLaplacian.H"
#include "fvmD2dt2.H"
#include "fvmLaplacian.H"
#include "addToRunTimeSelectionTable.H"
// * * * * * * * * * * * * * * Static Data Members * * * * * * * * * * * * * //
namespace Foam
{
namespace solvers
{
defineTypeNameAndDebug(solidDisplacement, 0);
addToRunTimeSelectionTable(solver, solidDisplacement, fvMesh);
}
}
// * * * * * * * * * * * * * Private Member Functions * * * * * * * * * * * //
void Foam::solvers::solidDisplacement::readControls(const bool construct)
{
solid::readControls(construct);
if (construct || mesh.solution().modified())
{
nCorr = pimple.dict().lookupOrDefault<int>("nCorrectors", 1);
convergenceTolerance = pimple.dict().lookupOrDefault<scalar>("D", 0);
pimple.dict().lookup("compactNormalStress") >> compactNormalStress;
accFac = pimple.dict().lookupOrDefault<scalar>("accelerationFactor", 1);
}
}
// * * * * * * * * * * * * * * * * Constructors * * * * * * * * * * * * * * //
Foam::solvers::solidDisplacement::solidDisplacement(fvMesh& mesh)
:
solid
(
mesh,
autoPtr<solidThermo>(new solidDisplacementThermo(mesh))
),
thermo_(refCast<solidDisplacementThermo>(solid::thermo_)),
compactNormalStress(pimple.dict().lookup("compactNormalStress")),
D_
(
IOobject
(
"D",
runTime.name(),
mesh,
IOobject::MUST_READ,
IOobject::AUTO_WRITE
),
mesh
),
E(thermo_.E()),
nu(thermo_.nu()),
mu(E/(2*(1 + nu))),
lambda
(
thermo_.planeStress()
? nu*E/((1 + nu)*(1 - nu))
: nu*E/((1 + nu)*(1 - 2*nu))
),
threeK
(
thermo_.planeStress()
? E/(1 - nu)
: E/(1 - 2*nu)
),
threeKalpha("threeKalpha", threeK*thermo_.alphav()),
sigmaD
(
IOobject
(
"sigmaD",
runTime.name(),
mesh
),
mu*twoSymm(fvc::grad(D_)) + lambda*(I*tr(fvc::grad(D_)))
),
divSigmaExp
(
IOobject
(
"divSigmaExp",
runTime.name(),
mesh
),
fvc::div(sigmaD)
- (
compactNormalStress
? fvc::laplacian(2*mu + lambda, D_, "laplacian(DD,D)")
: fvc::div((2*mu + lambda)*fvc::grad(D_), "div(sigmaD)")
)
),
thermo(thermo_),
D(D_)
{
mesh.schemes().setFluxRequired(D.name());
// Read the controls
readControls(true);
}
// * * * * * * * * * * * * * * * * Destructor * * * * * * * * * * * * * * * //
Foam::solvers::solidDisplacement::~solidDisplacement()
{}
// * * * * * * * * * * * * * * Member Functions * * * * * * * * * * * * * * //
void Foam::solvers::solidDisplacement::prePredictor()
{
if (thermo.thermalStress())
{
solid::prePredictor();
}
}
void Foam::solvers::solidDisplacement::thermophysicalPredictor()
{
if (thermo.thermalStress())
{
solid::thermophysicalPredictor();
}
}
void Foam::solvers::solidDisplacement::pressureCorrector()
{
volVectorField& D(D_);
const volScalarField& rho = thermo_.rho();
int iCorr = 0;
scalar initialResidual = 0;
{
{
fvVectorMatrix DEqn
(
fvm::d2dt2(rho, D)
==
fvm::laplacian(2*mu + lambda, D, "laplacian(DD,D)")
+ divSigmaExp
+ rho*fvModels().d2dt2(D)
);
if (thermo.thermalStress())
{
DEqn += fvc::grad(threeKalpha*T);
}
fvConstraints().constrain(DEqn);
initialResidual = DEqn.solve().max().initialResidual();
// For steady-state optionally accelerate the solution
// by over-relaxing the displacement
if (mesh.schemes().steady() && accFac > 1)
{
D += (accFac - 1)*(D - D.oldTime());
}
if (!compactNormalStress)
{
divSigmaExp = fvc::div(DEqn.flux());
}
}
const volTensorField gradD(fvc::grad(D));
sigmaD = mu*twoSymm(gradD) + (lambda*I)*tr(gradD);
if (compactNormalStress)
{
divSigmaExp = fvc::div
(
sigmaD - (2*mu + lambda)*gradD,
"div(sigmaD)"
);
}
else
{
divSigmaExp += fvc::div(sigmaD);
}
} while (initialResidual > convergenceTolerance && ++iCorr < nCorr);
}
void Foam::solvers::solidDisplacement::postCorrector()
{
if (thermo.thermalStress())
{
solid::postCorrector();
}
}
void Foam::solvers::solidDisplacement::postSolve()
{
if (runTime.writeTime())
{
volSymmTensorField sigma
(
IOobject
(
"sigma",
runTime.name(),
mesh
),
sigmaD
);
if (thermo.thermalStress())
{
sigma = sigma - I*(threeKalpha*thermo.T());
}
volScalarField sigmaEq
(
IOobject
(
"sigmaEq",
runTime.name(),
mesh
),
sqrt((3.0/2.0)*magSqr(dev(sigma)))
);
Info<< "Max sigmaEq = " << max(sigmaEq).value()
<< endl;
sigma.write();
sigmaEq.write();
}
}
// ************************************************************************* //
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