Abstract
The purpose of this work is the modeling and simulation of the deformation behavior of thin sheets consisting of large grains of Fe–3%Si and comparison with experiment. To this end, a crystal-plasticity-based finite-element model is developed for each grain, the grain morphology, and the specimen as a whole. The crystal plasticity model itself is rate-dependent and accounts for local dissipative hardening effects. In order to compare model predictions with experiment, the material parameters have been identified with the help of single-crystal data from [1–3]. Identified model predictions are compared with the experimental results of [4] for the deformation behavior of thin sheets of Fe–3%Si loaded incrementally in tension at room temperature. To this end, attention is restricted to the two slip families {110} and {112} expected to be active at room temperature. Comparison of model predictions for grain morphological evolution with the corresponding experimental results up to 19.5% deformation on this basis imply good agreement. In addition, model predictions for the development of the strain field and the grain reorientation field are discussed and evaluated.
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