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<pdf>Media:Draft_Content_841606240666_paper.pdf</pdf> | <pdf>Media:Draft_Content_841606240666_paper.pdf</pdf> |
A hybrid experimental-numerical approach to characterize plasticity and ductile fracture properties of aluminum 6061-T4 sheet is presented. The anisotropic elasto-plastic behavior is characterized by a Barlat89 model and the ductile fracture behavior by a GISSMO model in combination with the Xue-Wierzbicki model. We discuss then the validation procedure and the results related to a deep-drawing case where the simulation is carried out in a commercial FE-solver LS-DYNA. The drawing depth at fracture, as an exemplary result, shows a very good agreement between simulation and experiment.
Published on 28/02/22
Accepted on 28/02/22
Submitted on 28/02/22
Volume CT09 - Damage, Fracture and Fatigue, 2022
DOI: 10.23967/complas.2021.013
Licence: CC BY-NC-SA license
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