Study on the Influence of the New Type of Powder Metallurgy Ti-Al-Nb Alloy Hot Press Sintering Process on the Microstructure

Shuang Fang; Mincong Zhang; Qiuying Yu; Huaping Xiong

doi:10.1051/e3sconf/202129903010

All issues

Volume 299 (2021)

E3S Web Conf., 299 (2021) 03010

References

Open Access

Issue		E3S Web Conf. Volume 299, 2021 4^th Annual International Conference on Energy Development and Environmental Protection (EDEP 2021)


Article Number		03010
Number of page(s)		9
Section		Development and Utilization of Resources
DOI		https://doi.org/10.1051/e3sconf/202129903010
Published online		05 August 2021

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[1] Mao Yong, Li Shiqiong, Zhang Jianwei, Peng Jihua, Zou Dunxu, Zhong Zengyong. Acta Metall Sinica, 2000, 36(2): 135–140. [Google Scholar]

[2] Zhang Yonggang, Han Yafang, Chen Guoliang, Guo Jianting, Wan Xiaojing, Editorin-Chief Feng Di, Intermetallic Structural Materials, National Defense Industry Press, January 2001 [Google Scholar]

[3] C.H. Koo and T.H. Yu. Pack cementation coatings on Ti3Al-Nb alloys to modify the high-temperature oxidation properties. Surface and Coatings Technology, 126, 2000, p171–180. [Google Scholar]

[4] Y. W. Kim, D. M. Dimiduk. Progress in the understanding of gamma titanium aluminides, JOM, 43(8), 1991, p40–47. [Google Scholar]

[5] C. Koepee, A. Bartels, J. Seeger and H. Mecking. General aspects of the thermomechanical treatment of two-phase intermetallic TiAl compounds. Metallurgical and Materials Transaction A, 24(8), 1993, p1795–1806. [Google Scholar]

[6] W. Gao, Z. Li, D. Zhang. A new high-temperature, oxidation-resistant Ti-based materials. Oxidation of Metals, 57(1-2), 2002, p99–114. [Google Scholar]

[7] S. L. Semiatin. Wrought processing of ingot-metallurgy gamma titanium aluminide alloys [A]. Kim Y. W., Wagner, R., Yamaguchi, M., ed. Gamma Titanium Aluminides [C]. TMS, Wrarrendale, PA, 1995: p509–524. [Google Scholar]

[8] Y.W. Kim. Intermetallic alloys based on gamma titanium aluminum [J]. JOM. 1989, 41(7): 24. [Google Scholar]

[9] C. Scheu, E. Stergar, M. Schober, L. Cha, H. Clemens, A. Bartels, F.P. Schimansky, A. Cerezo. High carbon solubility in a y-TiAl-based Ti-45Al-5Nb-0.5C alloy and its effect on hardening [J]. Acta Materialia. 2009, 57: 1504–1511. [Google Scholar]

[10] Y.Y. Chen, H.Z. Niu, F.T. Kong, S.L. Xiao. Microstructure and fracture toughness of a ß phase containing TiAl alloy [J]. Intermetallics. 2011,19: 1405–1410. [Google Scholar]

[11] D. Vujic. Effect of rapid solidification and alloying addition on lattice distortion and atomic ordering in L10 TiAl alloys and their temporary alloys [J]. Metall Trans A. 1988, 19(10): 2445. [Google Scholar]

[12] T. Kawabata, T. Abumiya, T. Kami, et al. Mechanical properties and dislocation structures of TiAl single crystals deformed at 4.2-293K [J]. Acta Metall Mater. 1990, 38(8): 1381–1393. [Google Scholar]