void
StructuralCrossSection :: computeStressIndependentStrainVector(FloatArray &answer,
                                                               GaussPoint *gp, TimeStep *stepN, ValueModeType mode)
//
// returns initial strain vector induced by stress independent effects
// like temperatue or shrinkage.
// takes into account form of load vector assumed by engngModel (Incremental or Total Load form).
//
{
    StructuralMaterial *mat = ( StructuralMaterial * ) gp->giveElement()->giveMaterial();
    FloatArray e0, fullAnswer;

    //
    // add parts caused by  material
    //

    mat->computeStressIndependentStrainVector(answer, gp, stepN, mode);
}
Esempio n. 2
0
void
SimpleCrossSection :: computeStressIndependentStrainVector(FloatArray &answer,
                                                           GaussPoint *gp, TimeStep *stepN, ValueModeType mode)
//
// returns initial strain vector induced by stress independent effects
// like temperatue or shrinkage.
// takes into account form of load vector assumed by engngModel (Incremental or Total Load form).
//
{
    StructuralMaterial *mat = ( StructuralMaterial * ) gp->giveElement()->giveMaterial();
    ///@todo  Deprecated or not? If so, remove it! / Mikael
#if 0
    MaterialMode matmode = gp-> giveMaterialMode ();
    FloatArray et, e0, fullAnswer;
    double thick, width;

    if ((matmode == _2dBeam) || (matmode == _3dBeam) || (matmode == _3dShell) || (matmode == _2dPlate)) {

        StructuralElement *elem = (StructuralElement*)gp->giveElement();
        elem -> computeResultingIPTemperatureAt (et, stepN, gp, mode);
        FloatArray redAnswer;

        if (et.giveSize() == 0) {answer.resize(0); return ;}
        if (et.giveSize() < 1) {
            _error ("computeStressIndependentStrainVector - Bad format of TemperatureLoad");
            exit (1);
        }
        mat->giveThermalDilatationVector (e0, gp,stepN);

        if (matmode == _2dBeam) {
            answer.resize (3);
            answer.zero();
            answer.at(1) = e0.at(1) * (et.at(1)- mat->giveReferenceTemperature());
            if (et.giveSize() > 1) {
                thick = this->give(THICKNESS);
                answer.at(2) = e0.at(1) * et.at(2)/ thick;   // kappa_x
            }
        } else if (matmode == _3dBeam) {
            answer.resize (6);
            answer.zero();

            answer.at(1) = e0.at(1) * (et.at(1)- mat->giveReferenceTemperature());
            if (et.giveSize() > 1) {
                thick = this->give(THICKNESS);
                width = this->give(WIDTH);
                answer.at(5) = e0.at(1) * et.at(2)/ thick;   // kappa_y
                if (et.giveSize() > 2)
                    answer.at(6) = e0.at(1) * et.at(3)/ width;   // kappa_z
            }
        } else if (matmode == _2dPlate) {

            if (et.giveSize() > 1) {
                answer.resize (5);
                answer.zero();

                thick = this->give(THICKNESS);
                if (et.giveSize() > 1) {
                    answer.at(1) = e0.at(1) * et.at(2)/ thick;   // kappa_x
                    answer.at(2) = e0.at(2) * et.at(2)/ thick;   // kappa_y
                }
            }
        } else if (matmode == _3dShell) {
            answer.resize (8);
            answer.zero();

            answer.at(1) = e0.at(1) * (et.at(1)- mat->giveReferenceTemperature());
            answer.at(2) = e0.at(2) * (et.at(1)- mat->giveReferenceTemperature());
            if (et.giveSize() > 1) {
                thick = this->give(THICKNESS);
                answer.at(4) = e0.at(1) * et.at(2)/ thick;   // kappa_x
                answer.at(5) = e0.at(2) * et.at(2)/ thick;   // kappa_y
            }
        } else _error ("Unsupported material mode");
    } else {
        mat->computeStressIndependentStrainVector (answer, gp, stepN, mode);
    }
#endif
    mat->computeStressIndependentStrainVector(answer, gp, stepN, mode);
}