Numerical investigation and experimental validation of Lemaitre ductile damage model for DC04 steel and application to deep drawing process

被引:0
作者
Salah Laboubi
Ouzine Boussaid
Mohamed Zaaf
Walid Ghennai
机构
[1] Badji Mokhtar University Annaba,Laboratory of Metal Materials Forming (LMF2M), Faculty of Technology
[2] Badji Mokhtar-Annaba University,Laboratory of Research on Industrial Risks, Control and Safety, Faculty of Technology
[3] Research Center in Industrial Technologies CRTI,undefined
来源
The International Journal of Advanced Manufacturing Technology | 2023年 / 126卷
关键词
Deep drawing process; Numerical simulation; Lemaitre damage model; Damage evolution; Ductile fracture;
D O I
暂无
中图分类号
学科分类号
摘要
During the metal forming process, the avoidance of ductile fracture has been of great interest to the scientific and engineering communities over the past decades. Hence, ductile damage prediction remains a key issue for achieving defect-free products. In this paper, the elastoplastic damage behaviour of DC04 steel has been studied and simulated to predict the fracture during the deep drawing process and reduce the industrial trial cost. In this context, a fully coupled elastoplastic damage model has been developed and implemented in the Abaqus explicit code using the VUMAT subroutine, knowing that the used elastoplastic and the damage parameters were identified by experimental tests. Numerical simulations have been performed to validate this model, followed by comparisons with the experimental results. These comparisons show a good correlation between the experimental and simulation results and good agreement with the empirical observations. Thus, the initiation of damage and its evolution leading to ductile fracture can be predicted using this model.
引用
收藏
页码:2283 / 2294
页数:11
相关论文
共 82 条
[1]  
Ahmetoglu M(1995)Control of blank holder force to eliminate wrinkling and fracture in deep-drawing rectangular parts CIRP Annals 44 247-250
[2]  
Broek TR(2002)Development of a combination punch speed and blank-holder fuzzy control system for the deep-drawing process J Mater Process Technol 125 440-445
[3]  
Kinzel G(2010)Mechanical anisotropy and deep drawing behaviour of AZ31 and ZE10 magnesium alloy sheets Acta Mater 58 592-605
[4]  
Altan T(2013)Development of a hydroforming setup for deep drawing of square cups with variable blank holding force technique The Int J Adv Manuf Technol 66 1159-1169
[5]  
Manabe K(2019)Optimization of process parameters to enhance formability of AA 5182 alloy in deep drawing of square cups by hydroforming J Mech Sci Technol 33 5337-5346
[6]  
Koyama H(2020)Sheet thinning prediction method based on localized friction effect in deep-drawing Adv Mech Eng 12 1-10
[7]  
Yoshihara S(2019)Formation of weld defects in cold metal transfer arc welded 7075–T6 plates and its effect on joint performance IOP Conf Ser Mater Sci Eng 629 012007-7161
[8]  
Yagami T(2007)Microstructural and mechanical characterization of electron beam welded Al-alloy 7020 J Mater Sci 42 7154-101
[9]  
Yi S(1997)Fracture behaviour of diffusion bonded bimaterial Ti–Al joints Sci Technol Weld Joining 2 95-15
[10]  
Bohlen J(1977)Continuum theory of ductile rupture by void nucleation and growth: part I—yield criteria and flow rules for porous ductile media J Eng Mater Technol 99 2-252
123456789