Analysis of forming limits in metal forming processes

A methodology for formulating an elasto-plastic finite element model was developed to analyze the direct penetration and re-penetration in the hole-flanging process. The model was based on the updated lagrangian formulation, Prandtl-Reuss flow rule, and Hill's yield criterion. Simulation results inc

Theoretical prediction of forming limit strain of sheet metal is developed in the framework of the three-dimensional general bifurcation theory. The onset of the three-dimensional discontinuous velocity "eld in the biaxially stretched uniform sheet is predicted. Three fundamental mode vectors, i.e.

This paper develops a numerical technique for determining the shape sensitivity parameters in steady metalforming processes such as drawing and rolling. The adjoint method is applied to the discrete non-linear system of equations in the finite element model in order to determine the discrete matrix

A computational method based on the membrane theory for the analysis of axisymmetric sheet metal forming processes such as punch stretching, deep drawing and hydroforming is presented. The elastic-plastic finite element approach is based on the flow rule associated with Hill's quadratic yield criter

The evolution of structural anisotropy during sheet forming of time-dependent metarial is considered here in some details. The eventual alignment of the elongated pores (voids, cavities, etc.) towards the principal loading direction provides the source for the structural anisotropy. Experimental obs