Abstract
The purpose of this study is devoted to an “advanced” coupled ductile damage model that describes the elastoplastic behavior of DD13 (Hot rolled steel) sheet material deformed using for the first time a single point incremental forming (SPIF) process. This numerical approach is carried out using a non-associated plasticity model coupled with continuum ductile damage. The constitutive elastoplastic equations and the calculation algorithms are implemented on Abaqus/Explicit via the user interface (VUMAT) subroutine. The numerical simulation is scrutinized two phenomena in this study: the damage behavior and the springback of DD13 sheet material when a conical shape is manufactured using the SPIF process to assess where the damage can accumulate. The simulation results included the damage area of the DD13 sheets, the Hill’48 stress distribution as long as a quadratic function of Hill’48 is used in this formulation, and a comparative figure to explain the final shape of the manufactured part after springback.
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Bouhamed, A., Ben Said, L., Jrad, H., Wali, M., Dammak, F. (2021). Ductile Damage Prediction of DD13 Sheet Material in Single Point Incremental Forming Process. In: Kharrat, M., Baccar, M., Dammak, F. (eds) Advances in Mechanical Engineering, Materials and Mechanics. ICAMEM 2019. Lecture Notes in Mechanical Engineering. Springer, Cham. https://doi.org/10.1007/978-3-030-52071-7_10
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