Scale Resistance of Titanium Silicide Ti5Si–Titanium-Aluminide TiAl3 Powder Composites

G. A. Pribytkov; Прибытков Г. А.; V. V. Korzhova; Коржова В. В.; I. A. Firsina; Фирсина И. А.; A. V. Baranovskiy; Барановский А. В.; V. P. Krivopalov; Кривопалов В. П.

doi:10.31857/S0044185623700225

Scale Resistance of Titanium Silicide Ti5Si–Titanium-Aluminide TiAl3 Powder Composites

作者: Pribytkov G.A.¹, Korzhova V.V.¹, Firsina I.A.¹, Baranovskiy A.V.¹, Krivopalov V.P.¹
隶属关系:
1. Federal State Budgetary Institution “Institute of Strength Physics and Materials Science”, Siberian Branch, Russian Academy of Sciences, 634055, Tomsk, Russia
期: 卷 59, 编号 2 (2023)
页面: 181-187
栏目: ФИЗИКО-ХИМИЧЕСКИЕ ПРОБЛЕМЫ ЗАЩИТЫ МАТЕРИАЛОВ
URL: https://vestnikugrasu.org/0044-1856/article/view/663872
DOI: https://doi.org/10.31857/S0044185623700225
EDN: https://elibrary.ru/SZBLFM
ID: 663872

如何引用文章

全文:

开放存取

##reader.subscriptionAccessGranted##
受限制的访问

订阅存取

详细
作者简介
参考
补充文件
统计

详细

The microstructure, phase composition, and resistance to oxidation upon heating in air in the temperature range of 600–1100°С for composites synthesized in the gasless combustion mode of reactive powder mixtures of titanium, aluminum, and silicon have been studied. Silicide Ti5Si3 and titanium trialuminide TiAl3 were synthesized from two-component mixtures. The combustion products of ternary mixtures contain Ti5Si3 and TiAl3, the ratio of which depends on the aluminum content in the reaction mixtures. The scale resistance of the synthesized powder composites is determined to a greater extent by the microstructure of the granules than by their phase composition. The composition was determined of the reaction powder mixture, the combustion products of which have a scale resistance 1.5–3 times higher than the combustion products of the other studied compositions.

关键词

titanium, titanium silicide, titanium trialuminide, gasless combustion, metal matrix composite, structure, scale resistance

参考

Головко Э.И. Высокотемпературное окисление металлов и сплавов. Справочник. Киев: Наук. Думка, 1980. 296 с.
Dai J., Zhu J., Chen C., Weng F. // J. Alloys and Compounds. 2016. V. 685. P. 784–798.
Mitra R. // Internal Materials Reviews. 2006. V. 51. P. 13–64.
Pribytkov G.A., Krinitsyn M.G., Korzhova V.V. et al. // Prot. Met. Phys. Chem. Surf. 2022. V. 58. P. 70–75.
Yoshihara M.M., Miura K. // Intermetallics. 1995. V. 3. P. 351–363.
Quiang S., Liu B., Li J. et al. // Materials Science and Engineering. Powder metallurgy. 2015. V. 20(4). P. 616–622.
Dong Z., Jiang H., Feng X., Wang Z. // Trans. Nonferrous Met. Soc. China. 2006. V. 16. P. 2004–2008.
Liang W., Zhao X.G. // Scripta mater. 2001. V. 44. P. 1049–1054.
Wu Y., Wang A.H., Zhang Z. et al. // Applied Surface Science. 2014. V. 305. P. 16–23.
Riley D.P. // Intermetallics. 2006. V. 14. P. 770–775.
Vojtech D., Kubatik T., Pavlickova M., Maixner J. // Intermetallics. 2006. V. 14. P. 1181–1186.
Udayashankar N.K., Rajasekaran S., Nayak Jagannath // Trans. Indian Inst. Met. 2008. V. 61. № 2–3. P. 231–233.
Li Z., Gao W., He Y., Li S. // High Temperature Materials and Processes. 2002. V. 21. № 1–2. P. 35–45.
Lavrenko V.O., Firstov S.O., Panasyuk A.D. et al. // Powder Metallurgy and Metal Ceramics. 2003. V. 42. № 3–4. P. 184–188.
Sun F.S., Kim S.E., Cao C.X. et al. // Scripta Materialia. 2001. V. 456. P. 383–389.
Sun F.S., Froes F.H. (Sam) // Materials Science and Engineering A. 2003. V. 345. P. 262–269.
Tkachenko S., Datskevich O., Dvorak K., Kulak L. // J. Alloys and Compounds. 2017. V. 694. P. 1098–1108.
Nov’ak P., Michalcov’a A., Šeráak J. et al. // J. Alloys and Compounds. 2009. V. 470. P. 123–126.
Novak P., Pruša F., Šerak J. et al. // J. Alloys and Compounds. 2010. V. 504. P. 320–324.
Zha M., Wang H.Y., Li S.T. et al. // Materials Chemistry and Physics. 2009. V. 114. P. 709–715.
Zha M., Wang H.Y., Li S.T. et al. // ISIJ International. 2009. V 49. № 3. P. 453–457.