Numerical simulations of sheet-metal forming

Three phenomenological yield criteria are adopted to describe the plastic behaviour of sheet metals with normal plastic anisotropy. The sheet metals are assumed to be elastic-plastic, rate-sensitive and incompressible. A rate-sensitive thin shell ÿnite element formulation based on the virtual work p

The finite element simulation is now widely used in the design of stamping tools. That is, the trial and error procedure is replaced by simulation in which defects of sheet forming processes are predicted and evaluated. The theoretical background and numerical implementation of a three dimensional f

Sheet-metal forming simulations are made using a plane-stress yield function proposed by Ferron et al. for orthotropic sheets. Following the general method for the integration of rate-independent plasticity models, the yield function has been implemented in the implicit Abaqus=Standard ÿnite element

A drawback of former wear simulation of deep drawing processes is that the change of wear caused by increasing the number of punch strokes was not considered. Geometry-Update-Scheme (GUS) which has been proposed at Institute of Metal Forming and Casting considers the changes of tool geometry caused