Commenced in January 2007
Frequency: Monthly
Edition: International
Paper Count: 33122
Temperature-Dependence of Hardness and Wear Resistance of Stellite Alloys
Authors: S. Kapoor, R. Liu, X. J. Wu, M. X. Yao
Abstract:
A group of Stellite alloys are studied in consideration of temperature effects on their hardness and wear resistance. The hardness test is conducted on a micro-hardness tester with a hot stage equipped that allows heating the specimen up to 650°C. The wear resistance of each alloy is evaluated using a pin-on-disc tribometer with a heating furnace built-in that provides the temperature capacity up to 450°C. The experimental results demonstrate that the hardness and wear resistance of Stellite alloys behave differently at room temperature and at high temperatures. The wear resistance of Stellite alloys at room temperature mainly depends on their carbon content and also influenced by the tungsten content in the alloys. However, at high temperatures the wear mechanisms of Stellite alloys become more complex, involving multiple factors. The relationships between chemical composition, microstructure, hardness and wear resistance of these alloys are studied, with focus on temperature effect on these relations.Keywords: Stellite alloy, temperature, hardness, wear resistance
Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1060872
Procedia APA BibTeX Chicago EndNote Harvard JSON MLA RIS XML ISO 690 PDF Downloads 6461References:
[1] J. R. Davis, Cobalt-base alloys, in Nickel, Cobalt, and Their Alloys, ASM International, Materials Park, 2000.
[2] K. Ando, T. Omori, J. Sato, Y. Sutou, K. Oikawa, R. Kainuma and K. Ishida, 2006, Effect of alloying elements on fcc/hcp martensitic transformation and shape memory properties in Co Al alloys, Mater. Trans., 47(9), 2006, 2381-2386.
[3] I. Campos, G. Ramirez, U. Figueroa and C. Velazquez, Paste bonding process: Evaluation of boron mobility on borided steels, Surf. Eng., 23(3), 2007, 216 222.
[4] A. Frenk and J. D. Wagnière, Laser cladding with cobalt-based hardfacing, J. Phys. IV France, 1(C7), 1991, 65-68.
[5] A. Frenk and W. Kurz, Microstructural effects on the sliding wear resistance of a cobalt based alloy, Wear, 174(1-2), 1994, 81-91.
[6] C. J. Heathcock, A. Ball and B. E. Protheroe, Cavitation erosion of cobalt-based Stellite alloys, cemented carbides and surface-treated low alloy steels, Wear, 74(1), 1981, 11 26.
[7] L. C. Wang and D. Y. Li, Effects of yttrium on microstructure, mechanical properties, high temperature wear behaviour of cast Stellite 6 alloy, Wear, 255(1-6), 2003, 535 544.
[8] I. Radu, D. Y. Li and R. Llewellyn, Tribologocal behaviour of Stellite 21 modified with yttrium, Wear, 257(11), 2004, 1154-1166.
[9] I. Radu and D. Y. Li, The wear performance of yttrium-modified Stellite 712 at elevated temperatures, Tribo. Inter., 40(2), 2007, 254-265.
[10] H. Celik and M. Kaplan, Effects of silicon on the wear behaviour of cobalt-based alloys at elevated temperature, Wear, 257(5-6), 2004, 606-611.