A novel yield locus description by combining the Taylor and the relaxed Taylor theory for sheet steels

► A polycrystal plasticity based yield loci is correlated with those from mechanical tests. ► A new yield loci based on the Taylor models, referred to as CTFP, is proposed. ► The new description can be used as virtual experiment for complicated mechanical tests. ► The model is easily deployed as inp...

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Bibliographic Details
Published inInternational journal of plasticity Vol. 27; no. 11; pp. 1758 - 1780
Main Authors An, Yuguo, Vegter, Henk, Carless, Louisa, Lambriks, Marc
Format Journal Article
LanguageEnglish
Published Kidlington Elsevier Ltd 01.11.2011
Elsevier
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Summary:► A polycrystal plasticity based yield loci is correlated with those from mechanical tests. ► A new yield loci based on the Taylor models, referred to as CTFP, is proposed. ► The new description can be used as virtual experiment for complicated mechanical tests. ► The model is easily deployed as input for other constitutive equations in simulations. ► The difference between the measured and the calculated FLD is remarkable. Recently, several flexible constitutive equations have been proposed for sheet forming simulations. However, various mechanical tests are required to determine the material parameters needed for such models. In the present work, effort has been made to investigate the correlation between the polycrystal plasticity based yield loci and those determined from mechanical tests, in order to define yield functions easily and accurately with minimum experimental work. The results for different materials indicate that, in many cases, the Hill’48 quadratic yield function conventionally fitted with the plastic anisotropy R-values deviates significantly from measured yield loci. The Hill’48 yield function fitted with the uniaxial and biaxial yield stresses is quite close to the measured one, but with large deviation in the strain ratios for strong anisotropic materials. A careful comparison of the measured yield loci and those calculated from the Taylor full constraint model and the relaxed model indicates that the yield loci derived from the Taylor full constraint model capture the shape of the measured ones in general, but they are less elongated in the stretching direction, and the stretching factor is usually smaller than that derived from the relaxed Taylor model. The measured biaxial points are between those calculated from the two Taylor models. Based on the two yield loci derived from the Taylor models, a new combined model referred to as CTFP is proposed. The new model retains roughly the shape of the yield loci derived from the Taylor full constraint model, but the size is scaled using the averaged biaxial points of each model in the stretching regime. The proposed new description has been validated using several forming steel grades. This model can be used as virtual experiment for complicated mechanical tests, such as the plane strain tension, balanced biaxial stretching and shear test. The stress and strain data from the virtual experiments, together with the stress and plastic anisotropy measured in the uniaxial tensile test, are easily deployed as input data for other constitutive equations used in sheet metal forming simulations. Forming limit diagrams were predicted using different material constitutive models. The difference between the measured FLD and the calculated ones is remarkable. A profound analysis of the phenomena and a systematic study of intrinsic material parameters on the FLDs is needed.
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ISSN:0749-6419
1879-2154
DOI:10.1016/j.ijplas.2011.05.003