Study of springback pattern of non-uniform thickness section based on V-bending experiment

Authors

  • A. F. Adnan Metal Forming Research Laboratory, School of Mechanical Engineering Universiti Sains Malaysia, 14300 Nibong Tebal, Pulau Pinang, Malaysia
  • A. B. Abdullah Metal Forming Research Laboratory, School of Mechanical Engineering Universiti Sains Malaysia, 14300 Nibong Tebal, Pulau Pinang, Malaysia
  • Z. Samad Metal Forming Research Laboratory, School of Mechanical Engineering Universiti Sains Malaysia, 14300 Nibong Tebal, Pulau Pinang, Malaysia

DOI:

https://doi.org/10.15282/jmes.11.3.2017.7.0258%20

Keywords:

Weight reduction; non-uniform thickness; springback; thickness ratio.

Abstract

Non-uniform thickness section is one of most effective approaches in reducing automotive part weight. Less weight results in less fuel consumption and therefore good for the environment. Formability is the main issue of non-uniform thickness section, since changes in thickness may cause parts to behave distinctively compared to uniform thickness during the forming process. One of the main concerns is the springback pattern. This study focused on springback behaviour of AA6061 strip with non-uniform thickness through V-bending experiment. The outcome will contribute in the manufacturing of automotive parts with non-unifrom thickness, where defects such as springback can be predicted and minimised. In the experiment, three parameters i.e. thickness ratio, bend radius and alignment were studied and the effects were observed. The result found that thickness was the most influential parameters compared to others. Thickness was reduced through cold deformation, causing the hardness to increase and then resulted in higher springback value. The effect of alignment was almost negligible. Validation made based on the result found is in agreement with prior published works.

References

Mayyas A, Qattawi A, Omar M, Shan D. Design for sustainability in automotive industry: A comprehensive review. Renewable and Sustainable Energy Reviews. 2012;16:1845-62.

Jeya GR, Vinodh S. Application of fuzzy VIKOR and environmental impact analysis for material selection of an automotive component. Materials & Design. 2012;37:478-86.

Sahaya-Anand TJ. Nickel as an Alternative Automotive Body Material. Journal of Mechanical Engineering and Sciences. 2012;2:187-97.

Merklein M, Johannes M, Lechner M, Kuppert A. A review on tailored blanks—production, applications and evaluation. Journal of Materials Processing Technology. 2014;214:151-64.

Meyer AÃ, Wietbrock B, Hirt G. Increasing of the drawing depth using tailor rolled blanks—Numerical and experimental analysis. International Journal of Machine Tools and Manufacture. 2008;48:522-31.

Eggertsen PA, Mattiasson K. Experiences from experimental and numerical springback studies of a semi-industrial forming tool. International journal of Material Forming. 2012;5:341-59.

Aziz N, Bashah K, Muhamad N, Deros B, Zakaria A, Ashari S, et al. Multi-regression modeling for springback effect on automotive body in white stamped parts. Materials & Design. 2013;46:175-90.

Burchitz I. Springback, improvement of its predictability: Literature study report. (NIMR project MC1.02121). Enschede: Netherlands Institute for Metals Research. 2005.

Fang Z, Jiang Z, Wei D, Liu X. Study on springback in micro V-bending with consideration of grain heterogeneity. International Journal of Advanced Manufacturing Technology. 2015;78:1075–85.

Nie D, Lu Z, Zhang K. Hot V-bending behavior of pre-deformed pure titanium sheet assisted by electrical heating. International Journal of Advanced Manufacturing Technology In Press 2017. 2017.

Aso T, Iizuka T. FEM analysis of springback control with lump-punch penetration after V-bending. Journal of Physics: Conference Series: IOP Publishing; 2016. p. 032068.

Yoshida T. Springback Problems in Forming of High-Strength Steel Sheets and Countermeasures, (103), Nippon Steel Technical Report. 2013:390–400.

Abdullah AB, Samad Z. Effect of Bending Location on Springback via V-Bending Method. Australian Journal of Basic and Applied Sciences. 2015;9:15-20.

Erdin ME, Atmaca A. Effects of Holding Force on the Springback Behavior of Annealed Aluminum Plates. Procedia Engineering. 2016;149:56-61.

Kartik T, Rajesh R. Effect of Punch Radius and Sheet Thickness on Spring-back in V-die Bending. Advances in Natural and Applied Sciences. 2017;11:178-83.

Yazdani A, Naseri R, Rahmati S. Investigation of springback of two-layer metallic sheet produced by explosive welding in U-die bending process. Journal of Engineering Research. 2017;5:187-206.

Abdullah SA, Buang MS, Saedon J, Abdullah H. Design Parameters Selection Springback Effect in Air-V Bending Using Taguchi Approach on Advance High Strength Steel-DP590. Jurnal Teknologi (Sciences & Engineering). 2015;76:69–73.

Suyuti MA, Nur R, Asmeati. The Influence of Punch Angle on the Spring Back during V-Bending of Medium Carbon Steel. Advanced Materials Research2015. p. 157-60.

Panthi SK, Hora MS, Ahmed M. Artificial neural network and experimental study of effect of velocity on springback in straight flanging process. Indian Journal of Engineering and Material Sciences. 2016;23:159-64.

Trzepiecinski T, HG. L. Effect of Computational Parameters on Springback Prediction by Numerical Simulation. Metals. 2017;7:380.

Abdullah MA. Springback prediction in V-bending process using artificial neural netwok. Al-Qadisiyah Journal for Engineering Sciences. 2017;10:180-90.

Paithankar SA, Varade BV. Springback Prediction Analytical Model for V-Bend Process. International Journal of Modern Trends in Engineering and Research. 2016;3:870-6.

Panthi SK, Ramakrishnan N, Ahmed M, Singh SS, Goel MD. Finite element analysis of sheet metal bending process to predict the springback. Materials & Design. 2010;31:657-62.

Sutasn T, Pakkawat K. Analysis of bending mechanism and spring-back characteristics in the offset Z-bending process. The International Journal of Advanced Manufacturing Technology. 2016;85:2589-96.

Trzepiecinski T, Lemu H. Prediction of springback in V-die air bending process by using finite element method. MATEC Web of Conferences: EDP Sciences; 2017. p. 03023.

Ling JS, Abdullah AB, Samad Z. Application of Taguchi method for predicting Springback in V-bending of aluminum alloy AA5052 strip. Journal of Scientific Research and Development. 2016;3:91-7.

Karaagac İ. The Experimental Investigation of Springback in V-Bending Using the Flexforming Process. Arabian Journal of Science and Engineering. 2017;42:1853–64.

Peng Q, Peng X, Wang Y, Wang T. Investigation on V-Bending and Springback of Laminated Steel Sheets. Journal of Manufacturing Science and Engineering. 2015;137:041002.

Selvakumar N, Narayanasamy R. Experimental investigation of strain hardening behaviour of sintered aluminium preforms. Transactions of the Indian Institute of Metals. 2005;58:789-99.

Ouakdi EH, Louahdi R, Khirani D, Tabourot L. Evaluation of springback under the effect of holding force and die radius in a stretch bending test. Materials & Design. 2012;35:106-12.

Karaagac İ. The evaluation of process parameters on springback in V-bending using the flexforming process. Materials Research. 2017;20:1291-9.

Garcia-Romeu ML, Ciurana J, Ferrer I. Springback determination of sheet metals in an air bending process based on an experimental work. Journal of Materials Processing Technology. 2007;191:174-7.

Abdullah AB, Samad Z. An experimental investigation of springback of AA6061 aluminum alloy strip via V-bending process. IOP Conference Series: Materials Science and Engineering: IOP Publishing; 2013. p. 012069.

Zhang H. Springback characteristics in U-channel forming of tailor rolled blank. Acta Metallurgica Sinica. 2012;25:207-13.

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Published

2017-09-30

How to Cite

[1]
A. F. Adnan, A. B. Abdullah, and Z. Samad, “Study of springback pattern of non-uniform thickness section based on V-bending experiment”, J. Mech. Eng. Sci., vol. 11, no. 3, pp. 2845–2855, Sep. 2017.

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