Inclination Angle Effect on the Thickness Distribution in a Superplastic Formed Long Rectangular Pan-Reference-Cited by-同舟云学术

Inclination Angle Effect on the Thickness Distribution in a Superplastic Formed Long Rectangular Pan

Published:2012-12 Issue: Volume:735 Page:155-161
ISSN:1662-9752
Container-title:Materials Science Forum
language:
Short-container-title:MSF

Author:

Jarrar Firas Salah¹,Nazzal Mohammad Ahmad²

Affiliation:

1. University of Jordan

2. German Jordanian University

Abstract

In the superplastic process, the non-uniformity of the produced part thickness and the possibility of severe thinning are among the major disadvantages. This paper presents a parametric study on the superplastic forming of a Pb-Sn sheet into the shape of a long rectangular pan. A two dimensional plain strain finite element model was used to predict the forming times and thinning profiles of the formed Pb-Sn pan. The effect of varying the sidewall inclination angle was investigated for different friction conditions at the die-sheet interface. Results showed that increasing the side wall inclination angle reduced the forming time and provided a better thickness distribution.

Publisher

Trans Tech Publications, Ltd.

Subject

Mechanical Engineering,Mechanics of Materials,Condensed Matter Physics,General Materials Science

Link

https://www.scientific.net/MSF.735.155.pdf

Reference10 articles.

1. N. Chandra and K. Chandy: Superplastic Process Modeling of Plane Strain Components with Complex Shapes, J. Mater. Shaping Technol. Vol. 9 (1991), P. 27-37.

2. F. S. Jarrar, L. G. Hector, Jr., M. K. Khraisheh, A. F. Bower: New approach to gas pressure profile prediction for high temperature AA5083 sheet forming, Journal of materials processing technology, Vol. 210 (2010), pp.825-834.

3. A. K. Ghosh and C. H. Hamilton: Superplastic forming of a long rectangular box section – analysis and experiment, process modeling; fundamentals and applications to metals Proc of American Society for Metals, Process Modeling Sessions, Materials and Process (1980).

4. N. R. Harrison, et al: Influence of friction and die geometry on simulation of superplastic forming of Al-Mg alloys, edited by E. M. Taleff, et al. (TMS, Advances in superplasticity and superplastic forming 2004), pp.301-310.

5. J. M. Story: Incorporation of sliding friction into a closed-form model of plane strain superplastic forming, edited by C. H. Hamilton and N. E. Paton (TMS, Superplasticity and superplastic forming 1988), pp.297-302.

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