465 lines
14 KiB
C
465 lines
14 KiB
C
/*---------------------------------------------------------------------------*\
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========= |
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\\ / F ield | OpenFOAM: The Open Source CFD Toolbox
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\\ / O peration |
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\\ / A nd | Copyright held by original author
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\\/ M anipulation |
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-------------------------------------------------------------------------------
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License
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This file is part of OpenFOAM.
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OpenFOAM is free software; you can redistribute it and/or modify it
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under the terms of the GNU General Public License as published by the
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Free Software Foundation; either version 2 of the License, or (at your
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option) any later version.
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OpenFOAM is distributed in the hope that it will be useful, but WITHOUT
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ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
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FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
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for more details.
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You should have received a copy of the GNU General Public License
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along with OpenFOAM; if not, write to the Free Software Foundation,
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Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA
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7
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\*---------------------------------------------------------------------------*/
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#include "plasticityModel.H"
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// * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * //
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namespace Foam
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{
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// * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * //
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defineTypeNameAndDebug(plasticityModel, 0);
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// * * * * * * * * * * * * * * * * Constructors * * * * * * * * * * * * * * //
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plasticityModel::plasticityModel
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(
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const volTensorField& gradDU,
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const volSymmTensorField& epsilon,
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const volSymmTensorField& sigma
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)
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:
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rheologyModel(sigma),
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gradDU_(gradDU),
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epsilon_(epsilon),
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plasticityModelCoeffs_(subDict(type() + "Coeffs")),
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beta_
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(
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IOobject
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(
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"beta",
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sigma.time().timeName(),
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sigma.db(),
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IOobject::READ_IF_PRESENT,
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IOobject::AUTO_WRITE
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),
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sigma.mesh(),
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dimensionedScalar("0", dimless, 0)
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),
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sigmaY_
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(
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IOobject
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(
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"sigmaY",
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sigma.time().timeName(),
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sigma.db(),
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IOobject::READ_IF_PRESENT,
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IOobject::AUTO_WRITE
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),
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sigmaY()
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),
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DEpsilonP_
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(
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IOobject
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(
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"DepsilonP",
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sigma.time().timeName(),
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sigma.db(),
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IOobject::READ_IF_PRESENT,
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IOobject::AUTO_WRITE
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),
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sigma.mesh(),
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dimensionedSymmTensor("0", dimless, symmTensor::zero)
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),
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mu_
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(
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IOobject
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(
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"mu",
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sigma.time().timeName(),
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sigma.db(),
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IOobject::NO_READ,
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IOobject::NO_WRITE
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),
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mu()
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),
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lambda_
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(
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IOobject
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(
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"lambda",
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sigma.time().timeName(),
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sigma.db(),
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IOobject::NO_READ,
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IOobject::NO_WRITE
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),
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lambda()
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)
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{}
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plasticityModel::~plasticityModel()
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{}
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// * * * * * * * * * * * * * * * Member Functions * * * * * * * * * * * * * //
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void plasticityModel::correct()
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{
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// rheologyModel::correct();
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Info << "\tCorrecting plasticity model ... " << flush;
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const volSymmTensorField DEpsilon =
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symm(gradDU_)
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+ dimensioned<symmTensor>
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(
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"SMALL",
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dimless,
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symmTensor(SMALL, SMALL, SMALL, SMALL, SMALL, SMALL)
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);
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const volScalarField epsilonEq =
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sqrt((2.0/3.0)*magSqr(dev(epsilon_ + DEpsilon)))
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+ dimensionedScalar("SMALL", dimless, SMALL);
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scalarField& sigmaYI = sigmaY_.internalField();
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scalarField initialSigmaYI = sigmaY()().internalField();
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volScalarField epsilonEqCorr = epsilonEq;
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/*
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forAll(mu_.internalField(), cellI)
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{
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if (sigmaYI[cellI] > initialSigmaYI[cellI])
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{
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epsilonEqCorr.internalField()[cellI] = 0.02;
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}
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}
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*/
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// Update mu and lambda
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mu_= mu(epsilonEqCorr);
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lambda_ = lambda(epsilonEqCorr);
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// somewhat underestimating - should be combination/line search of epsEq_old and epsEq!!!
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// volScalarField Ep_ = Ep(epsilonEq);
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const volScalarField DEpsilonEq =
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sqrt((2.0/3.0)*magSqr(dev(epsilon_ + DEpsilon)))
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- sqrt((2.0/3.0)*magSqr(dev(epsilon_)))
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+ dimensionedScalar("SMALL", dimless, SMALL);
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const volSymmTensorField DSigma =
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2*mu_*(DEpsilon - DEpsilonP_) + I*(lambda_*tr(DEpsilon));
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const volSymmTensorField& oldSigma = sigma();
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const volScalarField oldSigmaEq = sqrt(1.5*magSqr(dev(oldSigma)));
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const volSymmTensorField sigma_ = sigma() + DSigma;
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const volScalarField sigmaEq =
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sqrt(1.5*magSqr(dev(sigma_)))
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+ dimensionedScalar("SMALL", dimPressure, SMALL);
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const volSymmTensorField devSigma = dev(sigma_);
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const volSymmTensorField DSigmaE = DSigma + 2*mu_*DEpsilonP_;
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const volScalarField sigmaEqE = sqrt(1.5*magSqr(dev(oldSigma + DSigmaE)));
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const volScalarField DSigmaEqE = sqrt(1.5*magSqr(dev(DSigmaE)));
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volScalarField Ep_ = Ep(sigmaEq);
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// Update internal beta
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const scalarField& muI = mu_.internalField();
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const scalarField& lambdaI = lambda_.internalField();
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const symmTensorField& DEpsilonI = DEpsilon.internalField();
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const scalarField& DEpsilonEqI = DEpsilonEq.internalField();
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const symmTensorField& oldSigmaI = oldSigma.internalField();
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const scalarField& oldSigmaEqI = oldSigmaEq.internalField();
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const symmTensorField& devSigmaI = devSigma.internalField();
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const symmTensorField& DSigmaEI = DSigmaE.internalField();
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const scalarField& sigmaEqEI = sigmaEqE;
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const scalarField& DSigmaEqEI = DSigmaEqE;
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const scalarField& oldBetaI = beta_.oldTime().internalField();
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scalarField& betaI = beta_.internalField();
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forAll (betaI, cellI)
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{
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tensor curDEpsEPred = tensor::zero;
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if( (DEpsilonEqI[cellI] >= 0) && (oldBetaI[cellI] > SMALL) )
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{
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betaI[cellI] = 1.0;
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curDEpsEPred = tensor::zero;
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}
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else
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{
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betaI[cellI] = 0.0;
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curDEpsEPred = DEpsilonI[cellI];
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if
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(
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(DEpsilonEqI[cellI] >= 0)
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&& (sigmaEqEI[cellI] >= sigmaYI[cellI])
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)
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{
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scalar C = sqr(oldSigmaEqI[cellI]) - sqr(sigmaYI[cellI]);
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scalar B = 3.0*(dev(oldSigmaI[cellI]) && dev(DSigmaEI[cellI]));
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scalar A = sqr(DSigmaEqEI[cellI]);
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scalar alpha = (-B + ::sqrt(mag(B*B - 4*A*C)))/(2*A + SMALL);
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// scalar alpha = (-B + ::sqrt((B*B - 4*A*C)))/(2*A + SMALL);
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curDEpsEPred =
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alpha/(2.0*muI[cellI] + SMALL)
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*(
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DSigmaEI[cellI]
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- (lambdaI[cellI]/(2*muI[cellI] + 3*lambdaI[cellI] + SMALL))
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*tr(DSigmaEI[cellI])*I
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);
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betaI[cellI] =
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1.0
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- (devSigmaI[cellI] && curDEpsEPred)
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/((devSigmaI[cellI] && DEpsilonI[cellI]) + SMALL);
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}
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}
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betaI[cellI] = max(betaI[cellI], 0.0);
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betaI[cellI] = min(betaI[cellI], 1.0);
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}
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// Update beta at boundary
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forAll(beta_.boundaryField(), patchI)
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{
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if (!beta_.boundaryField()[patchI].coupled())
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{
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const scalarField& muPatch = mu_.boundaryField()[patchI];
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const scalarField& lambdaPatch = lambda_.boundaryField()[patchI];
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const scalarField& sigmaYPatch = sigmaY_.boundaryField()[patchI];
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const symmTensorField& DEpsilonPatch =
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DEpsilon.boundaryField()[patchI];
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const scalarField DEpsilonEqPatch =
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DEpsilonEq.boundaryField()[patchI];
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const symmTensorField& oldSigmaPatch =
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oldSigma.boundaryField()[patchI];
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const scalarField& oldSigmaEqPatch =
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oldSigmaEq.boundaryField()[patchI];
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const symmTensorField& devSigmaPatch =
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devSigma.boundaryField()[patchI];
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const symmTensorField& DSigmaEPatch = DSigmaE.boundaryField()[patchI];
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const scalarField& sigmaEqEPatch = sigmaEqE.boundaryField()[patchI];
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const scalarField& DSigmaEqEPatch = DSigmaEqE.boundaryField()[patchI];
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const scalarField& oldBetaPatch =
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beta_.oldTime().boundaryField()[patchI];
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scalarField& betaPatch = beta_.boundaryField()[patchI];
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forAll(betaPatch, faceI)
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{
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tensor curDEpsEPred = tensor::zero;
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if
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(
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(DEpsilonEqPatch[faceI] >= 0)
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&& (oldBetaPatch[faceI] > SMALL)
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)
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{
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betaPatch[faceI] = 1;
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curDEpsEPred = tensor::zero;
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}
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else
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{
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betaPatch[faceI] = 0;
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curDEpsEPred = DEpsilonPatch[faceI];
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if
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(
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(DEpsilonEqPatch[faceI] >= 0)
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&& (sigmaEqEPatch[faceI] >= sigmaYPatch[faceI])
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)
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{
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scalar C =
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sqr(oldSigmaEqPatch[faceI])
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- sqr(sigmaYPatch[faceI]);
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scalar B =
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3.0
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*(
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dev(oldSigmaPatch[faceI])
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&& dev(DSigmaEPatch[faceI])
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);
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scalar A = sqr(DSigmaEqEPatch[faceI]);
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scalar alpha = (-B + ::sqrt(mag(B*B-4*A*C)))/(2*A + SMALL);
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//scalar alpha = (-B + ::sqrt((B*B-4*A*C)))/(2*A + SMALL);
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curDEpsEPred =
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alpha/(2.0*muPatch[faceI] + SMALL)
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*(
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DSigmaEPatch[faceI]
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- (
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lambdaPatch[faceI]
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/(2*muPatch[faceI] + 3*lambdaPatch[faceI] + SMALL)
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)
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*tr(DSigmaEPatch[faceI])*I
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);
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betaPatch[faceI] =
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1.0
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- (devSigmaPatch[faceI] && curDEpsEPred)
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/((devSigmaPatch[faceI] && DEpsilonPatch[faceI]) + SMALL);
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}
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}
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betaPatch[faceI] = max(betaPatch[faceI], 0.0);
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betaPatch[faceI] = min(betaPatch[faceI], 1.0);
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}
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}
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}
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// Update plastic strain increment
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scalar rf =
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readScalar(plasticityModelCoeffs_.lookup("relaxationFactor"));
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volSymmTensorField newDEpsilonP =
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4.5*beta_*mu_*(devSigma && DEpsilon)*devSigma
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/(
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(Ep_ + 3*mu_)*sqr(sigmaEq)
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+ dimensioned<scalar>
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(
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"SMALL",
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mu_.dimensions()*sigmaEq.dimensions()*sigmaEq.dimensions(),
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SMALL
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)
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);
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DEpsilonP_ = rf*newDEpsilonP + (1.0 - rf)*DEpsilonP_;
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DEpsilonP_.correctBoundaryConditions();
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Info << "done" << endl;
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}
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void plasticityModel::updateYieldStress()
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{
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Info << "Updating yield stress ... ";
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/*
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const volScalarField epsilonEq =
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sqrt((2.0/3.0)*magSqr(dev(epsilon_ )))
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+ dimensionedScalar("SMALL", dimless, SMALL);
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volScalarField Ep_ = Ep(epsilonEq);
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*/
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const volSymmTensorField& newSigma = sigma();
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const volScalarField sigmaEq = sqrt(1.5*magSqr(dev(newSigma)));
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volScalarField Ep_ = Ep(sigmaEq);
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const scalarField& EpI = Ep_.internalField();
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const scalarField& sigmaEqI = sigmaEq.internalField();
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scalarField& sigmaYI = sigmaY_.internalField();
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forAll(sigmaYI, cellI)
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{
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if(EpI[cellI] != 0)
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{
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if( sigmaEqI[cellI] > sigmaYI[cellI] )
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{
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sigmaYI[cellI] = sigmaEqI[cellI];
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Info << " Internal cell " << cellI
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<< " Yield stress updated to Sy= "
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<< sigmaEqI[cellI] * 1.0E-06 << " MPa"
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<< endl;
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}
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}
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}
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forAll(sigmaY_.boundaryField(), patchI)
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{
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if (!sigmaY_.boundaryField()[patchI].coupled())
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{
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const scalarField& EpPatch = Ep_.boundaryField()[patchI];
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const scalarField& sigmaEqPatch = sigmaEq.boundaryField()[patchI];
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scalarField& sigmaYPatch = sigmaY_.boundaryField()[patchI];
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forAll(sigmaYPatch, faceI)
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{
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if(EpPatch[faceI] != 0)
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{
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if(sigmaEqPatch[faceI] > sigmaYPatch[faceI])
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{
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sigmaYPatch[faceI] = sigmaEqPatch[faceI];
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Info << "Boundary cell " << patchI << " " << faceI
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<< " Yield stress updated to Sy= "
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<< sigmaEqPatch[faceI] * 1.0E-06 << " MPa"
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<< endl;
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}
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}
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}
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}
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}
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Info << "done" << endl;
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}
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bool plasticityModel::read()
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{
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if (regIOobject::read())
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{
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return true;
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}
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else
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{
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return false;
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}
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}
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// * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * //
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} // End namespace Foam
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// ************************************************************************* //
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