The Experimental and Numerical Evaluation of the Residual Stress in the Hot Forming Sheet Process for 5083 Aluminum via the Gas Blowing Process

Document Type : Research Paper

Authors

Abstract

In the present study, it was attempted to perform the residual stress analysis in the aluminum sheets A.A5083 via experimental results of hot metal forming process by gas.Then the accuracy of simulations was evaluated by the Finite Element Method and its comparison with experimental tests. The aim of the present study was to apply an efficient approach to determine the stresses caused during the forming process. Thus, the inductive stress in the imperfect conical sheets produced by gas blow process was measured method via hole drilling. In the experimental test, the stress equal to 44.5 Mpa was obtained. Then, The temperature dependant residual stresses of hot metal forming process were evaluated by the Finite Element Analysis Method. To simulate the forming process, ABAQUS/Explicit finite element software was used. The maximum of deviation in the results of finite element calculations and experimental tests for the maximum stress in the piece was 7%.  Thus, it was concluded that via finite element calculations more accurate study on hot metal forming method by gas can be done.

Keywords

References

1- S. Toros, F. Ozturk and I. Kacar, “Review of Warm Forming of Aluminum–Magnesium Alloys”, Journal of Materials Processing Technology, Vol. 207, October, pp. 1–15, 2008.
2- F. Shehata, M.J. Painter and R. Pearce, “Warm Forming of Aluminum/Magnesium Alloy Sheet”, Journal of Mechanical Work Technology, Vol. 2, pp. 279-291, 1978.                
3- D. Sorgente and L. Tricarico, "Pressure Profile Designing in Superplastic Forming Based on the Strain Rate and on Post-forming Properties", Journal of Materials Engineering and Performance, Vol 23, pp. 2025–2033, 2014.
4- N.J. Nieh, J. Wadsworth and O.D. Sherby, “Superplasticity in Metals and Ceramics”, Cambridge University Press, New York, 1997.        
5- J. Roesler, H. Harders and M. Baeker, “Mechanical behaviour of engineering materials”, Springer, New York, 2007.           
6- D.Wilson, “Aluminum versus Steel in the Family Car-the Formability Factor”, Journal of Mechanical Work Technology, Vol. 16, pp. 257-277, 1988.       
                       
7- J.S. Tang, Y.K. Fuh and S. Lee, "Superplastic forming process applied to aero-industrial strakelet: "wrinkling, thickness, and microstructure analysis", Journal of Advance Manufacturing Technology, pp. 279-291,  2014.           
8- H.Yu Wu and T. M. Da," Modified male die rapid gas blow forming of fine-grained Mg alloy AZ31B thin sheet", Journal of Advance Manufacturing Technology, pp. 1329-1338,  2015.
9- M. Bakhshi-Jooybari, A. Gorji and M. Elyasi, "Developments in sheet hydroforming for complex industrial parts", Metal Forming, Vol. 3, pp. 55-84, 2012.        
           
10-Hosford W. F., “Fundamentals of Engineering Plasticity”, Cambridge University Press, New York, 1997.           

11- P.F. Bariani, “Hot Stamping of AA5083 Aluminum Alloy Sheets”, Journal of Manufacturing Technology, Vol. 63, pp. 251-254, 2013.     
 
12- R. Hambli, A. Potiron, F. Guerin and B. Dumon, “Numerical Pressure Prediction Algorithm of Superplastic Forming Procedd Using 2D and 3D Modles”, Journal of Materials Processing Technology, Vol. 112, October, pp. 83–90, 2004.

Files

History

  • Receive Date: 09 October 2016
  • Accept Date: 09 October 2016

Share

How to cite

Statistics