Formability Analysis of Crca-IS2 Sheet to Eliminates the Defects during Deep Draw

  • Satpal Singh Thapar Polytechnic College, Patiala, Punjab India
  • Gurmeet Singh Thapar Institute of Engineering and Technology University, Patiala, Punjab, India
  • Simardeep Singh Honda Motorcycles and Scooters India Pvt. Ltd, Gurgaon, India
Keywords: Finite Element Analysis (FEA), Sheet Metal Bending, Drawing, Simulation, Wrinkling


Metal forming operations in industries are performed by the sheet metal processes. In sheet metal work deep drawing plays a major role to form the desired shapes. Improper design process leads to defected parts which are not acceptable due to ergonomics as well as aesthetics. Enormous defects during drawing have been discussed in the literature. FEA of sheet metal drawing was performed by using a blank. During the drawing operation wrinkling and tearing were observed experimentally. FEA as an effective tool has been concluded for this technique.The results will help in optimizing the process by changing the input parameters and help the industry to perform hit and trial on simulator rather than virtual environment.


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Alin, P., Ioan, M., Ioan, R., & Florin, B. (2013). Parameters influence on wrinkling in deep drawing cylindrical cups. Revista de Tehnologii Neconventionale, 17(3), 59-63.

Altinbalik, T., & Tonka, A. (2012). Numerical and experimental study of sheet thickness variation in deep drawing processes. International Journal of Modern Manufacturing Technologies,4(2), 9-16.

Kang, B. S.,Song, W. J.,& Ku, T. W. (2010). Study on process parameters and its analytic application for nonaxisymmetric rectangular cup of multistage deep drawing process using low carbon thin steel sheet. The International Journal of Advanced Manufacturing Technology, 49(9), 925-940.

Madake, M. A. D., Naik, D. V. R., & Kulkarni, M. S. S. (2013). Development of a sheet-metal component with a forming die using CAE software tools (Hyper form) for design validation and improvement. International Journal of Modern Engineering Research, 3(3), 1787-1791.

Mayavan, T., & Karthikeyan, L. (2013). Experimental and finite element studies on formability of low carbon steel sheets using deep drawing. International Journal of Engineering and Technology, 5(1), 165-174.

Özek, C.,& Bal, M. (2009). The effect of die/blank holder and punch radiuses on limit drawing ratio in angular deep-drawing dies. The International Journal of Advanced Manufacturing Technology, 40(11), 1077-1083.

Ramezani, M.,& Ripin, Z.M. (2012). Analysis of deep drawing of sheet metal using the marform process. The International Journal of Advanced Manufacturing Technology, 59(5), 491-505.

Reddy, R. V., Reddy, D. T. J., & Reddy, D. G. (2012). Effect of various parameters on the wrinkling in deep drawing cylindrical cups. International Journal of Engineering Trends and Technology, 3(1), 53-58.

Reddy, R. V., Reddy, T. A., & Reddy, G. C. M. (2012). Optimization of blank holder force to control wrinkling and fracture of cylindrical cups in deep drawing. International Journal of Engineering Trends and Technology, 3(5), 669-676.

Sen, N., & Kurgan, N. (2016). Improving deep drawability of HC300LA sheet metal by warm forming. International Journal of Advanced Manufacturing Technology, 82(5), 985-995.

Singh, C.P., & Agnihotri, G.(2015). Study of deep drawing process parameters: a review. International Journal of Scientific and Research Publications, 5(2), 1-15.

Vosniakos, G. C.,& Giannakakis, T. (2013). A knowledge-based manufacturing advisor for press worked sheet metal parts. Journal of Intelligent Manufacturing, 24(6), 1253-1266.

Wang, J., Goel, A., & Yang, F. (2009). Blank optimization for sheet metal forming using multi-step finite element simulations. The International Journal of Advanced Manufacturing Technology,40(7), 709-720.

Wei, D., Cui, Z., & Chen, J. (2008). Optimization and tolerance prediction of sheet metal forming process using response surface model. Computational Materials Science, 42(2), 228-233.

Wifi, A., & Mosallam, A. (2007). Some aspects of blank-holder force schemes in deep drawing process. Journal of Achievements in Materialsand Manufacturing Engineering, 24(1), 315-323.

Yang, L., Mori, K., & Tsuji, H. (2008). Deformation behaviors of magnesium alloy AZ31 sheet in cold deep drawing. Transactions of Nonferrous Metals Society of China, 18(1), 86-91.