Springback Analysis in Bending of V-Section Using Deformable Die

Authors

  • Jalil Shukur Department of Production Engineering and Metallurgy, University of Technology - Iraq
  • Waqass S. Khudhir Production Engineering and Metallurgy Department, University of Technology, Baghdad, Iraq.
  • Mohanad Qusay Abbood Production Engineering and Metallurgy Department, University of Technology, Baghdad, Iraq.

DOI:

https://doi.org/10.29194/NJES.25020096

Keywords:

Flexible Die Forming, Rubber Pad forming, Numerical Simulation

Abstract

With the development of manufacturing techniques, the demands have increased on tools with flexible components that can produce parts with different shapes and sizes only by replacing the rigid part of these tools, since the flexible part can match the required geometry. This study is focused on effects of rubber hardness and sheet thickness on the springback developed on the produced parts. Silicone rubber with three hardness (40,60 ,80) Shore A hardness scale was used. The material of workpiece was Aluminum (3003) with three different thicknesses of (0.8,1,1.2) mm and three holding time of (0,10,20) seconds. The results demonstrate that, the springback decreases with any increase in the rubber hardness or sheet thickness. In addition, the holding time showed a significant effect only with a harder rubber.

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References

Z. M. R. Maziar Ramezani, Rubber-pad forming processes: Technology and applications. Woodhead Publishing Ltd, 2012.

QUADRINI, Fabrizio; SANTO, Loredana; SQUEO, Erica Anna. Flexible forming of thin aluminum alloy sheets. International Journal of Modern Manufacturing Technologies, 2010, 2.1: 79-84.?

M. Benisa, B. Babic, A. Grbovic, and Z. Stefanovic, “Computer-aided modeling of the rubber-pad forming process,” 46(5)2012, pp. 503–510.

Jingwei Zhang, Sheng Ding, Jun Yanagimoto, “Bending properties of sandwich sheets with metallic face sheets and additively manufactured 3D CFRP lattice cores” vol. 300, 117437, 2022.

Mahshidifar, A., & Vafaeesefat, A. (2013). Numerical and experimental study of parameters affecting metal forming using rubber pads, on parts with radius of curvature.

L. Chen, H. Chen, Q. Wang, and Z. Li, “Studies on wrinkling and control method in rubber forming using aluminium sheet shrink flanging process,” Mater. Des., 65, 2015, pp. 505–510.

Y. Sun, M. Wan, X. Wu, “Wrinkling prediction in rubber forming of Ti-15-3 alloy,” Trans. Nonferrous Met. Soc. China, Vol. 23, pp. 3002? 3010, 2013.

H. S. Halkaci, “2D Finite Element Analysis of Rubber Pad Forming Process” 2 ND Int. Conf. Sci. Ecol. Technol. 2D, no. January 2017, 2016.

R. Subbaramaiah, S. Lim, G. Pearce “Rubber pad forming of glare cruciform using numerical and experimental analysis,” Cooperative Research Centre for Advanced Composite Structures, Fishermans Bend, Australia, pp.1–11, 2016.

Mahmut Tandogan and Omer Eyercioglu " Hardness Effect of Polyurethane Rubber on Mesoscale Rubber Pad Forming " International Advanced Research Journal in Science, Engineering and Technology, 4(9)2017, pp. 95-105.

Koubaa, Sana, et al. "Numerical investigation of the forming capability of bulge process by using rubber as a forming medium." The International Journal of Advanced Manufacturing Technology 92.5-8 (2017): 1839-1848.?

A. A. Abbas, M. A. Hussein, and M. M. Mohammad, “Design Parameters Estimation and Design Sensitivity Analysis in Manufacturing Process of Rubber Pad by Using Finite Element Technique,” Int. J. Mech. Mechatronics Eng., 18(3)2018, pp. 75–85.

Cheng, C., Chen, H., Guo, J., Guo, X., & Shi, Y., “Investigation on the influence of mandrel on the forming quality of thin-walled tube during free bending process,” In Journal of Manufacturing Processes, 72, 2021, pp. 215–226.

T. You , Y. Pan and Y. Zhai, “Heat transfer in a U-bend pipe flow at supercritical pressure,” Int. J. of Heat and Mass Transfer, 191, 2022, pp.75–85.

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Published

19-07-2022

How to Cite

[1]
J. Shukur, W. Khudhir, and M. Abbood, “Springback Analysis in Bending of V-Section Using Deformable Die”, NJES, vol. 25, no. 2, pp. 96–102, Jul. 2022, doi: 10.29194/NJES.25020096.

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