论文信息 - Modelling deformation microstructure with the crystal plasticity finite–element method

Modelling deformation microstructure with the crystal plasticity finite–element method

The finite–element (FE) method is commonly used to solve boundary value problems in continua. Constitutive equations based on crystal plasticity have been implemented in FE simulations, and these slip–based calculations have the potential to model a variety of interesting phenomena. However, the substructure of the deformed state in metals is inherently discontinuous. To what extent continuum plasticity calculations can be reasonably used for deformation microstructure predictions depends on the microstructural interpretation of the constitutive models. It is possible with quite simple models to predict orientation gradients at large second–phase particles and at grain boundaries. Because of the implicit link between the substructure and mechanical behaviour of metals, and the great flexibility that crystal plasticity models have, the prediction of at least some of the more important aspects of substructure, by association with state variables, is possible.

P. Bate | Peter Bate

[1] I. Dillamore,et al. Transition bands and recrystallization in metals , 1972, Proceedings of the Royal Society of London. A. Mathematical and Physical Sciences.

[2] H. Mecking,et al. A Method for the Determination of the Active Slip Systems and Orientation Changes During Single Crystal Deformation , 1978 .

[3] Alan Needleman,et al. An analysis of nonuniform and localized deformation in ductile single crystals , 1982 .

[4] Alan Needleman,et al. Material rate dependence and localized deformation in crystalline solids , 1983 .

[5] E. Aifantis. On the dynamical origin of dislocation patterns , 1986 .

[6] L. Anand,et al. Crystallographic texture evolution in bulk deformation processing of FCC metals , 1992 .

[7] J. Humphreys. A Microstructural Model of Recrystallization , 1993 .

[8] F. J. Humphreys,et al. The deformation of particle-containing aluminium single crystals , 1994 .

[9] van der Erik Giessen,et al. Discrete dislocation plasticity: a simple planar model , 1995 .

[10] Gorti B. Sarma,et al. Texture predictions using a polycrystal plasticity model incorporating neighbor interactions , 1996 .

[11] Gorti B. Sarma,et al. Effects of interactions among crystals on the inhomogeneous deformations of polycrystals , 1996 .

[12] P. Dawson,et al. Computational Mechanics for Metal Deformation Processes Using Polycrystal Plasticity , 1997 .