Influence of Spatial Grain Orientation Distribution on Sheet Metal Necking

Pei Dong Wu; David J. Lloyd

doi:10.4028/www.scientific.net/MSF.519-521.103

Paper Titles

The Work Hardening of Single Phase and Multi-Phase Aluminium Alloys
p.71

Large Strain Deformation and Annealing of Aluminium
p.79

Heterogeneity in Plastic Deformation
p.85

Through-Process Texture Simulation for Aluminium Sheet Fabrication
p.93

Influence of Spatial Grain Orientation Distribution on Sheet Metal Necking
p.103

A Suitable Criterion for Precise Determination of Incipient Necking in Sheet Materials
p.111

Evaluation of Biaxial Forming Limits by Bulge Testing
p.117

Comparing the Influence of Mn and Fe Content on the Fracture of a AA6XXX Series Alloy in Different Aged States
p.125

Influence of Surface Defect Geometry on the Localization and Failure of AA6111 Sheet: Necking versus Shear
p.131

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Influence of Spatial Grain Orientation Distribution on Sheet Metal Necking

Abstract:

Necking under in-plane plane strain tension along the transverse direction (TD) is numerically simulated for two sheets: one with very high Cube (HC) and the other with low Cube (LC). To do so, the EBSD measurement is performed in the TD-ND (normal direction) section for the sheets. The EBSD map (grain orientations and their spatial distributions) is directly implemented into the crystal plasticity based finite element code. More specifically, the measured orientations are assigned to elements in the mesh according to their positions. The values of the material parameters in the crystal plasticity model are determined by curve-fitting numerical simulations of uniaxial tension in the rolling direction (RD) to corresponding experimental data. The effect of spatial grain orientation distribution on necking is emphasized. It is found that both the global averaged texture and its spatial distribution are important to the onset of necking. The predicted results are in good agreement with experimental observations.