The complexity of the deep drawing process is given by many parameters that must be established in order to run the process in the best conditions. In this paper, several numerical simulations of the thickness of a deep drawing cylindrical part were made by modifying the parameters that define this process. Finite element analysis is the method used for modeling and simulating the process of plastic deformation. The analyzed parameters are the punch radius, die radius, the blank holding force. The model was verified by performing several experimental tests under the same conditions. Several deep drawing parts were obtained. The thickness of these parts was measured with the coordinate measuring machine. The material used in the numerical model and in the experimental tests is DC04 steel.

Dengiz, C.G., Yildizli, K. Experimental and simulated comparison of finite element models of bimetallic sheets for deep drawing process. Int J Adv Manuf Technol 117, 3599–3614 (2021)

F. Greco, E. Deckers, J. Stroobants, S. Van Poppel, K. Linck, W. Desmet, Finite element simulation of the dynamic behaviour of deep drawn components with accurate thickness description, Finite Elements in Analysis and Design, Volume 138, 2018, Pages 12-20, ISSN 0168-874X,

Sahu Y.K., Pradhan M.K. (2020) Modelling and Simulation of Deep Drawing Process of Circular Cup on AL1200 Using Finite Element Analysis. In: Shunmugam M., Kanthababu M. (eds) Advances in Simulation, Product Design and Development. Lecture Notes on Multidisciplinary Industrial Engineering. Springer, Singapore.

Ahmad Aminzadeh, Ali Parvizi, Mahmoud Moradi, Multi-objective topology optimization of deep drawing dissimilar tailor laser welded blanks; experimental and finite element investigation, Optics & Laser Technology, Volume 125, 2020, 106029, ISSN 0030-3992,

Timothy J. Barrett, Marko Knezevic, Deep drawing simulations using the finite element method embedding a multi-level crystal plasticity constitutive law: Experimental verification and sensitivity analysis, Computer Methods in Applied Mechanics and Engineering, Volume 354, 2019, Pages 245-270, ISSN 0045-7825,.

M. Kardan, A. Parvizi and A. Askari, Experimental and Finite Element Results for Optimization of Punch Force and Thickness Distribution in Deep Drawing Process, Arab. J. Sci. Eng., Springer, 2018, 43(3), p 1165–1175.

Amir Atrian, Hamed Panahi, Experimental and finite element investigation on wrinkling behaviour in deep drawing process of Al3105/Polypropylene/Steel304 sandwich sheets, Procedia Manufacturing, Volume 15, 018, Pages 984-991, ISSN 2351-9789,

Kardan, M., Parvizi, A. & Askari, A. Experimental and Finite Element Results for Optimization of Punch Force and Thickness Distribution in Deep Drawing Process. Arab J Sci Eng 43, 1165–1175 (2018).

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