Void growth and constitutive softening in a periodically voided solid

Worswick, M. J.; Pick, R. J.

Affiliations

¹Defence Research Establishment Suffield, Ralston, Alberta, Canada, TOJ 2NO

²University of Waterloo, Waterloo, Ontario, Canada, N2L 3G1

Abstract

A three-dimensional finite element model of a periodically voided elastic-plastic solid is used to predict void growth and constitutive softening under tensile plastic deformation. The analysis considers an infinite block of material containing a three-dimensional periodic array of voids, subjected to a remote deformation or stress field. The predicted initial dilatational and extensional void growth rate, as a function of stress triaxiality and material work-hardening rate, agrees well with the analytical results of Budiansky et al. (Mechanics of Solids, The Rodney Hill 60th Anniversary Volume, edited by H.G. Hopkins and M.J. Sewell, p. 13, Pergamon Press, Oxford, 1982) for an isolated void in a viscous solid. Increased initial void volume fraction (⨍) has little effect on the dilatational growth rate, but strongly affects the extensional growth rate at high levels of triaxiality. The effect of void aspect ratio on void growth rate was seen during uniaxial tensile deformation, during which extensive void elongation caused a reduction in the final or asymptotic void growth rates. Constitutive softening is shown to be primarily a function of porosity and stress triaxiality.

Links

DOI: 10.1016/0022-5096(90)90025-Y

WoS: A1990DX52400001

History

Received: 1989-07-20

Online: 2002-09-6

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Cited By (11)

Year	Entry
2003	Chen ZT, Worswick MJ, Cinotti N, Pilkey AK, Lloyd D. A linked FEM-damage percolation model of aluminum alloy sheet forming. Int J Plast. December 2003;19(12):2099-2120.
2000	Pardoen T, Hutchinson JW. An extended model for void growth and coalescence. J Mech Phys Solids. December 2000;48(12):2467-2512.
2003	Thomson CIA, Worswick MJ, Pilkey AK, Lloyd DJ. Void coalescence within periodic clusters of particles. J Mech Phys Solids. 2003;51(1):127-146.
2008	Siad L, Ouali MO, Benabbe A. Comparison of explicit and implicit finite element simulations of void growth and coalescence in porous ductile materials. Mater Des. 2008;29(2):319-329.
2000	Fowler JP, Worswick MJ, Pilkey AK, Nahme H. Damage leading to ductile fracture under high strain-rate conditions. Metall Mater Trans. March 2000;A31(3):831-844.
1997	Pilkey AK. Effect of Second-Phase Particle Clustering on Aluminum-Silicon Alloy Sheet Formability [PhD thesis]. Carleton University; July 15, 1997.
2001	Thomson CIA. Modeling the Effects of Particle Clustering on Ductile Failure [PhD thesis]. Carleton University; May 2001.
2011	Butcher C. A Multi-Scale Damage Percolation Model of Ductile Fracture [PhD thesis]. Fredricton, NB: The University of New Brunswick; August 2011.
2004	Chen Z. The Role of Heterogeneous Particle Distribution in the Prediction of Ductile Fracture [PhD thesis]. University of Waterloo; 2004.
2005	Baradari JG. Damage in Hydroforming of Pre-Bent Aluminum Alloy Tubes [PhD thesis]. University of Waterloo; 2005.
2007	Williams BW. A Study of the Axial Crush Response of Hydroformed Aluminum Alloy Tubes [PhD thesis]. University of Waterloo; 2007.