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Superplasticity in Use: A Critical Review of Its Status, Trends and Limits

Published online by Cambridge University Press:  16 February 2011

Peter-J. Winkler
Peter-J. Winkler*
Affiliation:
Messerschmitt-Bölkow-Blohm GmbH, Central Laboratory, Munich, West Germany
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Abstract

The transformation of the phenomenon Superplasticity into a manufacturing technique has been pushed ahead over the last two decades mainly by the aerospace industries. The possibility of producing complicated structures in one step offers well known economic advantages. The combination of superplastic forming and diffusion bonding further enhances design flexibility thanks to the ability of fabricating multisheet structures.

This paper provides an overview of the practical application of Superplasticity in forming components. It focusses on the major aerospace materials i.e. Ti alloys and Al alloys and discusses specific characteristics, the material specifications, and supply situation.

Superplastic forming processing is presented including the techniques used for diffusion bonding; design concepts and exemplary SPF and SPF/DB parts are presented.

Finally a critical discussion concerning current development trends, and the factors limiting broad application of this manufacturing technique are given. Future prospects are outlined and further research needs emphasized.

Type
Research Article
Information
MRS Online Proceedings Library (OPL) , Volume 196: Symposium T – Superplasticity in Metals, Ceramics, and Intermetallics , 1990 , 123
Copyright
Copyright © Materials Research Society 1990

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References

REFERENCES

1. Hamilton, C.H. and Paton, N.E., Superplasticity and Superplastic Forming, Proc. of an Int. Conf. Blaine, Washington 1988, TMS/AIME Google Scholar
2. Superform Metals Ltd., Publ. No 307, 9/81 SMGoogle Scholar
3. Pertler, H. and Winkler, P.-J., (Titanium 1986: Products and Applications; Proceedings of the International Conference, San Francisco, CA, Oct. 19-22, 1986. Volume 2. Dayton, OH, Titanium Development Association, 1987), 1060Google Scholar
4. RMJ-MS-005, Mat spec, Sept. 17. 1987, (Ti6Al4V Titanium Alloy Sheet Intended for Superplastic Forming)Google Scholar
5. Timet-Material-Specification, TMS-SD 1571, issued 7/01/86Google Scholar
6. MBB N343 Werkstoffleistungsblatt DRAFT 03/88Google Scholar
7. Paton, N.E. and Wert, J.A., (Met. Trans. A Dec. 1983; 14A), 2535 Google Scholar
8. Leader, J.R., Neal, D.F. and Hammond, C., (Metallurgical Transaction A - Physical Metallurgy and Materials Science, vol.17A. Jan. 1986), 93 Google Scholar
9. Richards, H., Aluminium, 63, 1987, 360 Google Scholar
10. Ricks, R.A. and Winkler, P.-J. in Superplasticity and Superplastic Forming edited by Hamilton, C.H. and Paton, N.E., Proc. of on Int. Conf. Blaine, Washington, 1988 TMS/AIME, 377381 Google Scholar
11. Bampton, C.C.; Cheney, B.A.; Cho, A.; Ghosh, A.K. Gandi, C. Superplasticity in Aerospace, Phoenix, Arizona USA, 1988. TMS/AIME, 247259 Google Scholar
12. Miller, W.; White, J. Superplasticity in Aerospace, Phoenix, Arizona USA, 1988. TMS/AIME, 211228 Google Scholar
13. Wadsworth, J.; Nieh, T.G.; Sherby, O.D. in Superplasticity and Superplastic Forming edited by Hamilton, C.H. and Paton, N.E., Proc. of on Int. Conf. Blaine, Washington, 1988 TMS/AIME, 5761 Google Scholar
14. Bellet, M. and Chenot, J.L., (Titanium 1986: Products and Applications; Proceedings of the International Conference, San Francisco, CA, Oct. 19-22, 1986. Volume 2. Dayton OH, Titanium Development Association, 1987), 1175Google Scholar
15. Lederich, R.J., Sastry, S.M.L. and O'Neal, J.E., (Titanium: Science and Technology; Proceedings of the Fifth International Conference on Titanium, Munich, West Germany, 1984. Deutsche Gesellschaft fur Metallkunde, 1985), 695Google Scholar
16. Ward, D.M., (Metals and Materials, Vol.2, Sept. 1986), 560 Google Scholar
17. Royster, D.M.; Davis, R.C.; Shinn, J.M. Jr.; Bales, T.T.; Wiant, H.R.; Adv. Mater. Manuf. Process. 1988, 3, 469491 Google Scholar
18. Ricks, R.A.; Ball, J.; Stoklossa, H.; Winkler, P.J.; Grimes, R.; in Superplasticity and Superplastic Forming edited by Hamilton, C.H. and Paton, N.E., Proc. of on Int. Conf. Blaine, Washington, 1988 TMS/AIME, 557561 Google Scholar
19. Tober, G. and Elze, S., (AGARD, Advanced Joining of Aerospace Metallic Materials, Conc. Proc. No. 398; 1986), 11.1.Google Scholar
20. Williamson, J.R., (Titanium 1986: Products and Applications; Proceedings of the International Conference, San Francisco, CA, Oct. 19-22, 1986. Volume 2. Dayton, OH, Titanium Development Association, 1987), 1087Google Scholar
21. Hughes, G.W.; Johnston, S.H.; Ginty, B. in Superplasticity and Superplastic Forming edited by Hamilton, C.H. and Paton, N.E., Proc. of on Int. Conf. Blaine, Washington, 1988 TMS/AIME, 643648 Google Scholar
22. Friedrich, H.E.; Furlan, R.; Kullick, M. in Superplasticity and Superplastic Forming edited by Hamilton, C.H. and Paton, N.E., Proc. of on Int. Conf. Blaine, Washington, 1988 TMS/AIME, 649664 Google Scholar
23. Rolland, B. in Superplasticity and Superplastic Forming edited by Hamilton, C.H. and Paton, N.E., Proc. of on Int. Conf. Blaine, Washington, 1988 TMS/AIME, 601612 Google Scholar