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Key Microstructures Controlling the Mechanical Properties of Two-Phase TiAl Alloys with Lamellar Structures

Published online by Cambridge University Press:  15 February 2011

C. T. Liu ,
P. J. Maziasz  and
J. L. Wright
C. T. Liu
Affiliation:
Metals and Ceramics Division, Oak Ridge National Laboratory, Oak Ridge, TN 37831–6115, USA
P. J. Maziasz
Affiliation:
Metals and Ceramics Division, Oak Ridge National Laboratory, Oak Ridge, TN 37831–6115, USA
J. L. Wright
Affiliation:
Metals and Ceramics Division, Oak Ridge National Laboratory, Oak Ridge, TN 37831–6115, USA
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Abstract

The objective of this study is to identify key microstructural parameters which control the mechanical properties of two-phase γ-TiAl alloys with lamellar structures. TiAl alloys with the base composition of Ti-47Al-2Cr-2Nb (at. %) were prepared by arc melting and drop casting, followed by hot extrusion at temperatures above the oc-transus temperature, Tα. The hot extruded materials were then heat treated at various temperatures above and below Tα in order to control microstructural features in these lamellar structures. The mechanical properties of these alloys were determined by tensile testing at temperatures to 1000° C. The tensile elongation at room temperature is strongly dependent on grain size, showing an increase in ductility with decreasing grain size. The strength at room and elevated temperatures is sensitive to interlamellar spacing, showing an increase in strength with decreasing lamellar spacing. Hall-Petch relationships hold well for the yield strength at room and elevated temperatures and for the tensile elongation at room temperature. Tensile elongations of about 5% and yield strengths around 900 MPa are achieved by controlling both colony size and interlamellar spacing. The mechanical properties of the TiAl alloys with controlled lamellar structures produced directly by hot extrusion are much superior to those produced by conventional thermomechanical treatments.

Type
Research Article
Information
MRS Online Proceedings Library (OPL) , Volume 460: Symposium Z – High-Temperature Ordered Intermetallic Alloys VII , 1996 , 83
Copyright
Copyright © Materials Research Society 1997

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References

REFERENCES

1. Kim, Y.-W., Trends in the Development of Gamma TiAl Alloys, Gamma Titanium Aluminides, eds. Kim, Y.-W., Wagner, R. & Yamaguchi, M., TMS, 1995, pp. 637–54.Google Scholar
2. Liu, C. T., Maziasz, P. J., Clemens, D. R., Schneibel, J. H., Sikka, V. K., Nieh, T. G., Wright, J. L. & Walker, L. R., Gamma Titanium Aluminides, eds Kim, Y.-W., Wagner, R. & Yamaguchi, M., TMS, 1995, pp. 679–88.Google Scholar
3. Huang, S. C., Structural Interme tallies, eds Darolia, R., Lewandowski, J., Liu, C. T., Martin, P., Miracle, D. & Nathal, M., TMS, Warrendale, 1993, pp. 299307.Google Scholar
4. Yamaguchi, M. & Inui, H., Structural Interme tallies, eds Darolia, R., Lewandowski, J., Liu, C. T., Martin, P., Miracle, D. and Nathal, M., TMS, Warrendale, 1993, pp. 127–42.Google Scholar
5. Kim, Y.-W., Effect of Microstructure on the Deformation and Fracture of Gamma TiAl Alloys, Mat. Sci. Engr., A192/193, (1995) pp. 518–33.Google Scholar
6. Kim, Y.-W., Wagner, R. & Yamaguchi, M., Gamma Titanium Aluminides, TMS, 1995.Google Scholar
7. Huang, S. C., Metall. Trans. A., 23A (1992) 375.Google Scholar
8. Wang, J. N.. Schwartz, A. J., Nieh, T. G., Liu, C. T., Sikka, V. K. & Clemens, D., Gamma Titanium Aluminides, eds Kim, Y.-W., Wagner, R. & Yamaguchi, M., TMS, 1995, pp. 949–57.Google Scholar
9. Liu, C. T., Schneibel, J. H., Maziasz, P. J., Wright, J. L. and Easton, D. S., Interme tallies, 4 (1996) pp. 429440.Google Scholar
10. Nakano, T. & Umakoshi, Y., Intermetallics, 2 (1994) 185.Google Scholar
11. Ramanujan, R. V., Maziasz, P. J. & Liu, C. T., The Thermal Stability of the Microstructure of γ-based Titanium Aluminides, Acta Metall, 44, (1996) 2611.Google Scholar
12. Godfrey, A. B. and Loretto, M. H., Intermetallics, 4 (1996) 47.Google Scholar
13. Liu, C. T., Inouye, H. and Schaffhauser, A. C., Metall. Trans. 12A, (1981) pp. 9931002.Google Scholar
14. Kim, Y.-W., J. Metals, 46(7) (1994) 30.Google Scholar
15. Chan, K. S. & Kim, Y.-W., Acta Metall, 43 (1995) 439.Google Scholar
16. Kim, Y.-W., Intermetallic Compounds, eds Yamaguchi, M. & Fukutomi, H., 3rd Japan Int'l. SAMPE Symp., Chiba, Japan, Dec. 7–9, 1993, pp. 1310–17.Google Scholar
17. Liu, C. T., unpublished results, Nov. 1996, Oak Ridge National Laboratory, Oak Ridge, TN, 37831–6115.Google Scholar