Ductile fracture by the growth and coalescence of microvoids of non-uniform size and spacing

Thomason, P. F.

Affiliations

¹Department of Aeronautical and Mechanical Engineering, University of Salford, Salford M5 4WT, England

Abstract

A two-dimensional plane strain model of void growth and coalescence in a rigid/plastic solid, containing void sizes and spacings which can be highly non-uniform, is developed to investigate the effects of non-uniform distributions of void-nucleating particles on the ductility of a metal. The theoretical void-growth strains to ductile fracture for a wide variation in void diameters and spacings show that, for a given volume fraction of voids, the minimum ductile-fracture strain occurs when the voids are of uniform size and spacing. For the same volume fraction of voids, greatly increased ductility is likely to be achieved when the void sizes and spacings are highly non-uniform and the sub-cell volume fractions are also non-uniform.

Links

DOI: 10.1016/0956-7151(93)90382-3

WoS: A1993LG38200019

History

Received: 1992-07-08

Revised: 1992-12-18

Cited Works (3)

Year	Entry
1969	Rice JR, Tracey DM. On the ductile enlargement of voids in triaxial stress fields. J Mech Phys Solids. 1969;17(3):201-217.
1979	Goods SH, Brown LM. The nucleation of cavities by plastic deformation. Acta Metall. 1979;27(1):1-15.
1990	Thomason PF. Ductile Fracture of Metals. Pergamon Press; 1990.

Cited By (15)

Year	Entry
2004	Worswick MJ, Chen Z, Pilkey K, Lloyd D. Damage percolation modeling in aluminum alloy sheet. In: Raabe D, Roters F, Barlat F, Chen L-Q, eds. Continuum Scale Simulation of Engineering Materials: Fundamentals - Microstructures - Process Applications. Weinheim, Germany: Wiley-VCH Verlag GmbH & Co. KGaA; 2004:805-816.
2013	Chen Z, Butcher C. Micromechanics Modelling of Ductile Fracture. Dordrecht, Netherlands: Springer; 2013. Solid Mechanics and Its Applications; vol 195.
2001	Worswick MJ, Chen ZT, Pilkey AK, Lloyd D, Court S. Damage characterization and damage percolation modelling in aluminum alloy sheet. Acta Mater. August 16, 2001;49(14):2791-2803.
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.
1999	Thomson CIA, Worswick MJ, Pilkey AK, Lloyd DJ, Burger G. Modeling void nucleation and growth within periodic clusters of particles. J Mech Phys Solids. 1999;47(1):1-26.
2000	Pardoen T, Hutchinson JW. An extended model for void growth and coalescence. J Mech Phys Solids. December 2000;48(12):2467-2512.
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.
2018	Scott H. Effects of Microstructure and Particle Population on Void Damage Evolution in Complex Phase Steel [PhD thesis]. Queen's University; September 2018.
2015	Guzmán CF. Experimental and Numerical Characterization of Damage and Application to Incremental Forming [PhD thesis]. Liège, Belgique: Université de Liège; November 2015.
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.
2006	Orlov OS. A Three-Dimensional Damage Percolation Model [PhD thesis]. University of Waterloo; 2006.
2018	Pathak N. Characterization and Modeling of Sheared Edge Failure in Advanced High Strength Steel [PhD thesis]. University of Waterloo; 2018.