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Title: Formability and fracture in deep drawing sheet metals: Extended studies for pre-strained anisotropic thin sheets
Authors: Basak, Shamik
Panda S.K.
Lee M.-G.
Published in: International Journal of Mechanical Sciences
Abstract: In this study, experimental and numerical investigations were conducted to predict the formability and fracture behavior of as-received and pre-strained sheet materials during deep drawing process. In this context, various laboratory scale experimental setups were developed to impart different types and amounts of pre-strain such as 5% and 10% equi-biaxial pre-strains (5% EBP and 10% EBP), 10% plane strain pre-strain (10% PSP), and 10% uni-axial pre-strain (10% UP) on the extra deep drawing (EDD) steel and aluminum alloy (AA5052) sheets of 1.2 mm thickness. Further, all the pre-strained sheet samples were deformed using a cylindrical deep drawing setup. The forming limit diagrams (FLDs) of as-received sheets were predicted by the Marciniak–Kuczyński (MK) model incorporating different anisotropic yield functions such as Hill48 models identified based on r-values (Hill48-r), and yield stresses (Hill48-σ), and the non-quadratic plane stress Yld2000-2d model. Also, the Bao–Wierzbicki (BW) fracture curve was calibrated using different anisotropic yield functions. Subsequently, the formability in terms of limiting drawing ratio (LDR) was predicted using the MK-FLD. The BW fracture curve was incorporated into the generalized incremental stress state dependent damage model (GISSMO) platform in LS-Dyna software and the fracture behavior was predicted in terms of failure location and cup height at the onset of fracture. It was also found that the incorporation of Barlat Yld2000-2d yield function into the FE simulation efficiently predicted the necking and fracture behavior of as-received sheets. Furthermore, the concept of path independent polar effective plastic strain (PEPS) based failure model was used to predict LDR, thinning profile and fracture cup height of all the different pre-strained sheets. Finally, the strain paths and experimental fracture strains were plotted in 3D fracture locus to get insight into the deformation behavior during the deep drawing experiments. © 2019 Elsevier Ltd
Citation: International Journal of Mechanical Sciences, 170
Issue Date: 2020
Publisher: Elsevier Ltd
Keywords: Anisotropy
Deep drawing
Ductile fracture model
ISSN: 207403
Author Scopus IDs: 56489932500
Author Affiliations: Basak, S., Department of Materials Science and Engineering & RIAM, Seoul National University, 1 Gwanak-ro, Gwanak-gu, Seoul, 08826, South Korea
Panda, S.K., Department of Mechanical Engineering, Indian Institute of Technology Kharagpur, Kharagpur, 721302, India
Lee, M.-G., Department of Materials Science and Engineering & RIAM, Seoul National University, 1 Gwanak-ro, Gwanak-gu, Seoul, 08826, South Korea
Funding Details: MGL appreciates the support from National Research Foundation (NRF) of Korea with Grant number 2019R1A5A6099595 and 2017R1A2A2A05069619. National Research Foundation of Korea, NRF: 2017R1A2A2A05069619, 2019R1A5A6099595
Corresponding Author: Lee, M.-G.; Department of Materials Science and Engineering & RIAM, 1 Gwanak-ro, Gwanak-gu, South Korea; email:
Appears in Collections:Journal Publications [ME]

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