Damage evolution in creep bulging of thin sheet metal

The creeping motion of thin sheet metal, damaged by artificial cavities is observed in bulging tests and simulated 'semi'-analytically. The sheet meta l satisfies Norton's Law for secondary creep and is subjected to a bi-direc tional stretch. The stretch is produced by creep bulging through elliptical dies with the virtue of sustaining nearly uniform background stress ratio for each aspect ratio of the die axes. In order to reach large deformations with significant shape evolution of the cavities, the tests were conducted at superplastic conditions. The sheet is double layered (only one layer is cavitated) made of Tin-Lead (50-50 Pb-Sn). The measured damage growth is c ompared to an approximate simulation. The simulation of the damage evolutio n, throughout its time history, makes repeated use of a so-called "Green-fu nction solution" for the motion of a single isolated cavity in an infinite viscoplastic continuum. The solution is modified from Muskhelishvili's elas tic solution by replacing the elastic shear modulus by a "viscous-like" var iable ("plastic shear modulus") which depends (non-linearly) on the evolved average strain-rate. Similarly, the stresses in the ligaments between cavi ties were averaged to approximate the local stress concentrations. Due emph asis is given to the rotation of each elliptical cavity, beside its expansi on (contraction) and elongation. (C) 1999 Elsevier Science Ltd. All rights reserved.