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Development of High-Strength-Fabricable Tantalum-Base Alloys

Published online by Cambridge University Press:  25 February 2011

R. W. Buckman Jr.
R. W. Buckman Jr.*
Affiliation:
Refractory Metals Technology Pittsburgh, PA 15236
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Abstract

In the 1950s, Ta-7.5%W and the Ta-2.5%W were the only tantalum alloys of commercial significance. An intensive alloy development effort occurred between 1958 and 1968 in response to Air Force and Navy aerospace needs for high-temperature, oxidation-resistant alloys for rocket and air-breathing engines and airframe applications. Compatibility with oxidation-resistant coatings, high-temperature short-time strength, fabricability and weldability were of prime importance. These programs led to the development of Ta-10w%W, Ta-30w%Nb-7.5w%V, T-111(Ta-8w%W-2w%Hf), and T-222(Ta-10w%W-2.5w%Hf-O.Olw%C). T-111, with its demonstrated compatibility with liquid alkali metals, and combination of strength, fabricability and weldability, was selected by NASA as the baseline reference alloy for space nuclear power systems studies. Significant quantities of T- 111 and T-222 were produced in the 1960s. Today, however, production is limited to unalloyed tantalum and the tantalum-tungsten binaries because of the demand of the chemical industry for materials with outstanding acid corrosion resistance. To again produce T-11 and T-222 on a commercial basis will require relearning by the refractory metal alloy producers. The current lack of experience in the refractory metal industry with these high temperature alloys will necessitate recovery of the expertise needed for the United States to effectively compete in this technology arena.

Type
Research Article
Information
MRS Online Proceedings Library (OPL) , Volume 322: Symposium F – High-Temperature Silicides and Refractory Alloys , 1993 , 329
Copyright
Copyright © Materials Research Society 1994

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References

1. Buckman, R. W. Jr., and Ammon, R. L.Evolution of Tantalum Alloy Development” Presented at 1993 TMS Annual Meeting, Denver, CO, February 21, To be Published.Google Scholar
2. Michael, A.B., in Refractory Metals and Alloys, 11, ed. Semchyshen, M. and Harwood, J.J., Interscience Publishers, New York, Metallurgical Society Conferences, 1961, pp. 357381.Google Scholar
3. Cunningham, L.D., “Columbium (Niobium) and Tantalum” (Annual Report, U.S. Department of the Interior Bureau of Mines, 1991).Google Scholar
4. Fansteel Metallurgical Corp., (U.S. Patents 1,701,299 and 2,015,509).Google Scholar
5. Fansteel Metals Brochure, “Tantaloy 61 Metal”, (Published by Fansteel Inc. 1972).Google Scholar
6. Torti, M.L., “Development of Tantalum-Tungsten Alloys for High Performance Propulsion System Components” (Second Quarterly Report, Contract NOrd-18787, November 1958).Google Scholar
7. Feild, A.L. et al. , “Research and Development of Tantalum and Tungsten-Base Alloys” (Contract NOas 58-852-C, Westinghouse Research Laboratories, May 26, 1961).Google Scholar
8. Ammon, R.L. and Begley, R.T., “Pilot Production and Evaluation of Tantalum Alloy Sheet” (WANL-PR-M-004, Contract NOw-62-0656-d, Westinghouse Astronuclear Laboratory, 15 June 1963).Google Scholar
9. Schmidt, F.F. et al. , “Investigation of the Properties of Tantalum and Its Alloys” (Report WADD-TR-59-13, Battelle Memorial Institute, 1959).Google Scholar
10. Schmidt, F.F. et al. , “Investigation of the Properties of Tantalum and Its Alloys” (WADD Technical Report 61-106, Battelle Memorial Institute, 1961).Google Scholar
11. Maykuth, D.J., Imgram, A.G., and Ogden, H.R., “Development of Techniques for the Production of Tantalum Alloy Sheet” (AF 33(657)-7015, Wah Chang Corporation, 1961).Google Scholar
12. Anon, Columbium, Tantalum and Tungsten Alloys Technical Information. vol. 3 (Wah Chang, Albany, A. Teledyne Co., Albany, Oregon 1968.Google Scholar
13. Ammon, R.L. and Begley, R.T., “Pilot Production and Evaluation of Tantalum Alloy Sheet” (Part II, WANL-PR-M-009, July 1, 1964).CrossRefGoogle Scholar
14. Ammon, R.L., Filippi, A.M. and Harrod, D.L., “Pilot Production and Evaluation of Tantalum Alloy Sheet” (WANL-PR-M-014, Part III, Contract NOw-64-0394-d, Westinghouse Astronuclear Laboratory, October 1965).Google Scholar
15. Filippi, A.M., “Production and Quality Evaluation of T-222 Tantalum Alloy Sheet” (WANLPR- 9KKO-003, Westinghouse Astronuclear Laboratory, 1968).Google Scholar
16. Ogden, H.R. et al. , “Scale-Up Development of Tantalum-Base Alloys” (Report No. ASD TR 61-684, Battelle Memorial Institute, 1962).Google Scholar
17. Maykuth, D.J. et al. , “Development of Techniques for The Production of Tantalum Alloy Sheet”(AF33(657)-7015-Wah Chang Corporation, November 1961)Google Scholar
18. Torti, M.L., in High Temperature Materials II, (Met. Soc. Conf. 18, 1963), pp. 161169.Google Scholar
19. Ault, G.M., “A Decade of Progress in Refractory Metals” (Presented at the 68th ASTM Annual Meeting, Lafayette, Ind., 13-18 June 1965).Google Scholar
20. Lane, J.R. and Ault, G.M., in Metals Engineering Quarterly (American Society for Metals, August 1965), pp. 2329.Google Scholar
21. Ammon, R.L. and Harrod, D.L., in Refractory Metals and Alloys IV-Research and Development, ed. Jaffee, R.I. et al. , (French Lick, IN, 3-5 October 1965), pp. 423442.Google Scholar
22. Begley, R.T. et al. , in Refractory Metal Alloys, ed. Machlin, I., Begley, R.T., and Weisert, E.D. (Plenum Press, New York, 1961), pp. 4184.Google Scholar
23. Moss, T.A., Davies, R.L., and Barna, G.J., in Recent Advances in Refractory Alloys for Space Power Systems,(Report NASA SP-245, 1969), pp. 118.Google Scholar
24. Sherby, O.D., “Factors Affecting the High Temperature Strength of Polycrystalline Solids”, (Acta Met. vol. 10, 1962), pp. 135147.Google Scholar
25. Buckman, R.W. Jr., in Proceedings of Refractory Alloy Technology for Space Nuclear Power Applications (CONF-8308130, January 1984), pp. 8697.Google Scholar
26. Hoffman, E.E. in Proceedings of Refractory Alloy Technology for Space Nuclear Power Applications (CONF-8308130, January 1984), pp. 1833.Google Scholar
27. DeVan, J.H. et al. in Proceedings of Refractory Alloy Technology for Space Nuclear Power Applications (CONF-8308130, January 1984), pp. 3485.Google Scholar
28. DiStefano, J.R. and Hoffman, E.E. in The Science and Technology of Tungsten, Tantalum, Molybdenum, Niobium and Their Alloys, ed. Promisel, N. E., (The MacMillan Company, New York, 1964), pp. 257289.Google Scholar
29. Filippi, A.M. “Evaluation of Mechanical Properties, Oxidation Resistance, and Structure of Slurry Silicide Coated T-222” NASA-CR-72713, December 1969.Google Scholar
30. Hoffmanner, A.L. in Refractory Metals and Alloys IV-Research and Development, ed. Jaffee, R.I. et al. (French Lick, IN, 3-5 October 1965), pp. 639657.Google Scholar
31. Buckman, R.W. Jr., in Alloying, ed. Walter, J.L., Jackson, M.R., and Sims, C.T. (ASM International, 1988), pp. 419446.Google Scholar
32. Titran, R.H., “Creep Behavior of Tantalum Alloy T-222 at 1365 to 1700 K” (NASA TN D- 7673) June 1974.Google Scholar
33. Smith, H.R., in Transactions of The Vacuum Metallurgy Conference-1960 (Interscience Publishers, New York, 1961), pp. 255266.Google Scholar
34. Smith, H.R., in Transactions of The Vacuum Metallurgy Conference-1962 (Publisher American Vacuum Society, Boston MA, 1963), pp. 95102.Google Scholar
35. Timmons, G.C., Climax Metals-Private communication January 1992.Google Scholar
36. Ekvall, R.A. et al. in Recent Advances in Refractory Alloys for Space Power Systems, (NASA SP-245, 1970, pp. 221261.Google Scholar
37. Buckman, R.W. Jr., Unpublished Data.Google Scholar