Ni-金刚石复合涂层的结构优化及基础磨削性能<sup>*</sup>

doi:10.11896/j.issn.1005-023X.2017.020.008

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Abstract Ni-diamond composite coating was prepared on 304 stainless steel substrates by electrodeposition technique. The diamond composite coating structure was optimized by adding the amount of diamond and thickening time. Grinding performance of the optimized diamond composite coating sliding against different counterparts (GCr15, SiC, 304 stainless steel) was evaluated by ball disc friction and wear tester. Results show that the diamond is uniform and dense when diamond concentration is 1.5 g/L. When the thickening time is 15 min, the embedding ratio of diamond is about 2/3, and the adhesion strength is better, which is suitable for the grinding process. The wear volume of GCr15, SiC, 304 stainless steel are decreased in turn, respectively, as follows: 0.353 76 mm³, 0.315 90 mm³, 0.194 01 mm³, and the diamond composite coating have better grinding performance for GCr15. Diamond composite coating grinding SiC, GCr15, 304 stainless steel have occurred abrasive wear, in addition, GCr15 also has a weak chemical wear, stainless steel has a serious chemical wear and adhesive wear.

Key words： nickel-diamond composite coating electrodeposition different coupling grinding performance

Published: 25 October 2017 Online: 2018-05-05

CLC number:	TG174
	TG441

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	Articles by authors
	ZHOU Yang
	JIN Qiu
	GONG Xiaoling
	NIE Chaoyin

Cite this article:

ZHOU Yang,JIN Qiu,GONG Xiaoling, et al. Structure Optimization and Basic Grinding Performance of Nickel-diamond Composite Coating[J]. Materials Reports, 2017, 31(20): 35-38.

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https://www.mater-rep.com/EN/10.11896/j.issn.1005-023X.2017.020.008 OR https://www.mater-rep.com/EN/Y2017/V31/I20/35

1 Wu Ying. Application status and improved research of electroplated diamond tools [J]. Hot Work Technol, 2015,44(18):18(in Chinese).
吴颖. 电镀金刚石工具的应用现状及改进研究[J]. 热加工工艺, 2015,44(18):18.
2 Liu Yongqi. Current research status and development of electroplated diamond wire saw [J]. Superhard Mater Eng, 2015,27(1):48(in Chinese).
刘永奇. 电镀金刚石线锯的研究现状与发展[J]. 超硬材料工程, 2015,27(1):48.
3 Suzuki T, Konno T. Improvement in tool life of electroplated diamond tools by Ni-based carbon nanotube composite coatings[J]. Precis Eng, 2014,38(3):659.
4 Lane B M, Dow T A, Scattergood R. Thermo-chemical wear model and worn tool shapes for single-crystal diamond tools cutting steel[J]. Wear, 2013,300(1-2):216.
5 Li Zhanjie, Gong Hu, Tong Weiping, et al. Experimental study of diamond turnability of iron nitride [J]. J Tianjin University, 2014(9):785(in Chinese).
李占杰, 宫虎, 佟伟平,等. 氮化铁材料的金刚石可切削性实验研究[J]. 天津大学学报, 2014(9):785.
6 Dai Pengfei, Study on diamond turning of steel alloys [J]. Tianjin: Tianjin University,2009(in Chinese).
代腾飞. 金刚石刀具车削钢铁材料的研究[D]. 天津: 天津大学, 2009.
7 Pavese M, Fino P, Ugues D, et al. High cycle fatigue study of me-tal-ceramic co-continuous composites [J]. Scr Mater, 2006,55(12):1135.
8 Chen Weiping, Yang Shaofeng, Han Mengyan. Research development of ceramic/Fe-based alloy composites [J]. Chin J Nonferrous Met, 2010,20(2):257(in Chinese).
陈维平, 杨少锋, 韩孟岩. 陶瓷/铁基合金复合材料的研究进展[J]. 中国有色金属学报, 2010,20(2):257.
9 Cao Lianjing, Sun Yuli, Zuo Dunwen, et al. Development on fixed abrasive diamond wire saw with electroplating method[J]. Diamond Abrasives Eng, 2013,33(1):53(in Chinese).
曹连静, 孙玉利, 左敦稳,等. 金刚石线锯的复合电镀工艺研究进展[J]. 金刚石与磨料磨具工程, 2013,33(1):53.
10Feng Canbo, Xie Guizhi, Sheng Xiaomin, et al. Process test research on stainless steel in ultra-high speed grinding [J]. China Mech Eng, 2013,24(3):322(in Chinese).
冯灿波, 谢桂芝, 盛晓敏,等. 不锈钢超高速磨削试验研究[J]. 中国机械工程, 2013,24(3):322.
11Huang Shaonan, Zhou Ming. Ultrasonic vibration cutting of stainless steel with polycrystalline diamond tools[J]. Tool Eng, 2008,42(5):6(in Chinese).
黄劭楠, 周明. 聚晶金刚石刀具振动切削不锈钢技术研究[J]. 工具技术, 2008,42(5):6.
12Guo Xiaoguang, Zhai Changheng, Jin Zhuji, et al. The study of diamond graphitization under the action of iron-based catalyst [J]. J Mech Eng, 2015,51(17):162(in Chinese).13郭晓光, 翟昌恒, 金洙吉,等. 铁基作用下的金刚石石墨化研究[J]. 机械工程学报, 2015,51(17):162.
13Paul E, Evans C J, Mangamelli A, et al. Chemical aspects of tool wear in single point diamond turning[J]. Precis Eng, 1996,18(1):4.
14Zhou Ming, Zou Lai. Tool wear mechanism of diamond cutting of ferrous metals in frictional wear experiments[J]. Optics Precis Eng, 2013,21(7):1786(in Chinese).
周明, 邹莱. 金刚石切削黑色金属时刀具磨损机理的摩擦磨损试验[J]. 光学精密工程, 2013,21(7):1786.
15Wen Xuelong, Gong Yadong, Cheng Jun, et al. Mechanism analysis and experimental research on wear of electroplated diamond micro-grinding tool[J]. J Mech Eng, 2015,51(11):177(in Chinese).
温雪龙, 巩亚东, 程军,等. 电镀金刚石微磨具磨损机理分析与试验研究[J]. 机械工程学报, 2015,51(11):177.