Microstructures and properties of submicron structural WC-12Co coatings deposited by HVOF 被引量：6

Microstructures and properties of submicron structural WC-12Co coatings deposited by HVOF

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摘要 In this study, WC-Co powder with WC submicron grain size of 0. 7 - 0. 9μm was used as feedstock powder to deposit wear resistant coating by home-made T J-9000 HVOF system. The deposition efficiency of the feedstock powder was examined. Influences of the High Velocity Oxy-Fuel （HVOF） spraying parameters on the microstructures, phase compositions, microhardness, and wear resistance of sprayed coatings were investigated. The deposition efficiency of the feedstock powder was very high, and reached to 58%. The sprayed coatings were very dense, and their porosities were lower than 1% and could be lowered than 0. 42% with optimal spraying parameters. According to the X-ray Diffraction （ XRD ） analysis, the phase compositions of the sprayed coatings consisted of WC, Co, W2 C, and Co6 W6 C. W appeared at high flame power. The average microhardness of the coating was 1 100 HVo 1 and had reversely linear relationship with the porosity of coatings. The weight loss of the counter wear ring GCrl5 was 20 times than that of the sprayed WC-Co coating. At the load of 15 kg and rotational speed of 200 r/min of GCr15 counter wear ring, the friction coefficient was 0. 68 in the dry wear conditions. It was concluded that the sprayed submicron structural WC-12Co coating had good wear resistance. In this study, WC-Co powder with WC submicron grain size of 0. 7 - 0. 9μm was used as feedstock powder to deposit wear resistant coating by home-made T J-9000 HVOF system. The deposition efficiency of the feedstock powder was examined. Influences of the High Velocity Oxy-Fuel （HVOF） spraying parameters on the microstructures, phase compositions, microhardness, and wear resistance of sprayed coatings were investigated. The deposition efficiency of the feedstock powder was very high, and reached to 58%. The sprayed coatings were very dense, and their porosities were lower than 1% and could be lowered than 0. 42% with optimal spraying parameters. According to the X-ray Diffraction （ XRD ） analysis, the phase compositions of the sprayed coatings consisted of WC, Co, W2 C, and Co6 W6 C. W appeared at high flame power. The average microhardness of the coating was 1 100 HVo 1 and had reversely linear relationship with the porosity of coatings. The weight loss of the counter wear ring GCrl5 was 20 times than that of the sprayed WC-Co coating. At the load of 15 kg and rotational speed of 200 r/min of GCr15 counter wear ring, the friction coefficient was 0. 68 in the dry wear conditions. It was concluded that the sprayed submicron structural WC-12Co coating had good wear resistance.

作者叶福兴崔崇杨雪王惜宝中田一博

机构地区 School of Materials Science and Engineering Tianjin Key Laboratory of Advanced Joining Technology

出处《China Welding》 EI CAS 2011年第4期22-27,共6页 中国焊接（英文版）

关键词 high velocity oxy-fuel spraying submicron WC mierohardness POROSITY wear resistance high velocity oxy-fuel spraying, submicron WC, mierohardness, porosity, wear resistance

分类号 TG174.442 [金属学及工艺—金属表面处理] TQ174.758 [化学工程—陶瓷工业]

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参考文献9

1Chivavibul P, Watanabe M, Kuroda S, et al. Effects of carbide size and Co content on the microstructure and mechanical propdrties of HVOF-sprayed WC-Co coatings. Surface and Coatings Technology, 2007, 202( 3): 509-521.
2Li C J, Ohmori A, Harata Y. Effect of powder structure of thermally sprayed WC-Co coatings. Journal of Materials Science, 1996, 31( 3): 785-794.
3Upadhyaya G S. Cemented tungsten carbides. New Jersey: NOYES, 1998.
4Jia K, Fischer T E, Gallois B. Microstructure, hardness and toughness of nanostructured and conventional WC-Co composites. Nanophase and Nanocrystalline Materials, 1998, 10 (5): 875 -891.
5Yang Q, Senda T, Hirose A. Sliding wear behavior of WC- 12% Co coatings at elevated temperatures. Surface and Coatings Technology, 2006, 200( 14- 15): 4208-4212.
6Stewart D A, Shipway P H, McCartney D G. Microstructural evolution in thermally sprayed WC-Co coatings: comparison between nanocomposite and conventional starting powder. Acta Materialia, 2000, 48(7) : 1593 - 1604.
7Kear B H, Skandan G, Sadangi R K. Factors controlling decarburization in HVOF sprayed nano-WC/Co hardcoatings. Scripta Materialia, 2001, 44( 8 -9) : 1703 -1707.
8Zhu Y C, Yukimura K, Ding C X, et al. Tribological proper- ties of nanostructured and conventional WC/Co coatings deposited by plasma spraying. Thin Solid Films, 2001, 388 ( 1 - 2): 277-282.
9Wang Q, Chen Z H, Ding Z X. Performance of abrasive wear of WC-12Co coatings sprayed by HVOF. Tribology International, 2009, 42(7) : 1046 - 1051.

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Microstructures and properties of submicron structural WC-12Co coatings deposited by HVOF 被引量：6

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