Plastic deformation treated as material flow through adjustable crystal lattice

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Abstract

Looking at severe plastic deformation experiments, it seems that crystalline materials at yield behave as a special kind of anisotropic, highly viscous fluids flowing through an adjustable crystal lattice space. High viscosity provides a possibility to describe the flow as a quasi-static process, where inertial and other body forces can be neglected. The flow through the lattice space is restricted to preferred crystallographic planes and directions causing anisotropy. In the deformation process the lattice is strained and rotated. The proposed model is based on the rate form of the decomposition rule: the velocity gradient consists of the lattice velocity gradient and the sum of the velocity gradients corresponding to the slip rates of individual slip systems. The proposed crystal plasticity model allowing for large deformations is treated as the flow-adjusted boundary value problem. As a test example we analyze a plastic flow of an single crystal compressed in a channel die. We propose three step algorithm of finite element discretization for a numerical solution in the Arbitrary Lagrangian Eulerian (ALE) configuration. © Published under licence by IOP Publishing Ltd.

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APA

Minakowski, P., Hron, J., Kratochvíl, J., Kruík, M., & Málek, J. (2014). Plastic deformation treated as material flow through adjustable crystal lattice. In IOP Conference Series: Materials Science and Engineering (Vol. 63). Institute of Physics Publishing. https://doi.org/10.1088/1757-899X/63/1/012130

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