纳米结构陶瓷涂层的外圆磨削力以及磨削表面精度的实验研究(英文) 被引量：2

An Experimental Investigation on Forces and Surface Finish in Cylindrical Grinding of Nanostructured Ceramic Coatings

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摘要使用功率计监测磨削加工的能量消耗,探讨了纳米结构陶瓷涂层的外圆磨削过程;对纳米陶瓷涂层和传统陶瓷涂层在磨削力和磨削表面精度方面进行了比较.磨削实验使用了外圆磨床和陶瓷结合剂金刚石砂轮.通过测量主轴功率获得切向磨削力,讨论了加工参数,如切深、进给率以及砂轮粒度对切向磨削力的影响.还对磨削后的涂层表面用粗糙度仪和扫描电镜进行了评估,揭示了表面粗糙度与加工参数的关系. This study investigates cylindrical grinding of nanostructured ceramic coatings using a power cell to monitor spindle power consumption during grinding. It compares nan ostructured ceramic coatings to their conventional counterparts in terms of grinding forces and surface finish.Grinding is conducted on a cylindrical grinding machine with vitrified bond di amond wheels.Tangential grinding forces are obtained through monitoring spindle power and the ir variations are studied with process parameters such as depth of cut, feedrate and wheel gri t size. Surface finish of the ground coatings is evaluated using surface profilometry and scanni ng electron microscopy. Based on the applications of surface profilometry and scanning elect ron microscopy, the effects of the process parameters on the average roughness of th e ground coatings are investigated.

作者孟鉴谢万刚张璧

机构地区美国康涅狄格大学机械工程系

出处《纳米技术与精密工程》 CAS CSCD 2004年第4期266-273,共8页 Nanotechnology and Precision Engineering

关键词陶瓷涂层外圆磨削磨削力表面精度加工参数外圆磨床金刚石砂轮轴功率表面粗糙度功率计 cylindrical grinding nanostructured ce ramic coatings grinding force surface finish

分类号 TG580 [金属学及工艺—金属切削加工及机床]

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参考文献9

1[1]Meyer J E, Fang G. Effect of grinding parameters on strength and finish of ceramics[A]. In:Proceedings of the 1st International Machining and Grinding Conference[ C]. 1995. 153-164.
2[2]Dey K D. An experimental investigation of the grinding forces and surfaces finish on nanostructured ceramic coatings [ D ].Connecticut: University of Connecticut,2001.
3[3]Zhang Bi, Wang Jiexin, Yang Fulun, et al. The effect of machine stiffness on grinding of silicon nitride[J]. International Journal of Machine Tool and Manufacture, 1998,39(1): 1 263-1 283.
4[4]Malkin S, Cook N H. The wear of grinding wheels Part 1-Attritious wear[J] .ASME Paper, 1971,70: 1 120-1 128.
5[5]Bartalucci B, Lisini G G. Grinding process instability [ J].ASME Journal of Engineering for Industry, 1969,91: 597.
6[6]Kitajima K, Cai G Q, Kumagai N, et al. Study of mechanism of ceramic grinding[J]. Annals of the CIRP, 1992,41( 1 ): 367-371.
7[7]Lee E S, Kim N H. A study on the machining characteristics in the external plunge grinding using the current signal of the spindle motor [J]. International Journal of Machine Tools and Manufacture, 2001,41:937-951.
8[8]Jia K, Fischer T E, Gallois B. Microstructure, hardness and toughness of the nanostructured and conventional WCCo composites [ J ]. Nanostructured Materials, 1998,10 ( 5 ):875-891.
9[9]Wang You, Jiang Stephen, Wang Meidong, et al. Abrasive wear characteristics of plasma sprayed nanostructured alumina/titania coa-tings [ J ]. Wear, 2000,237:176-185.

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2蒋驰,肖云峰,税毅,王术刚.飞行粒子特征参量检测技术研究现状[J].新技术新工艺,2005(9):21-23. 被引量：3
3叶雄林,李占明,朱有利.基于CCD图像处理技术的等离子喷涂粒子温度研究[J].新技术新工艺,2005(9):59-60. 被引量：6
4J. Karthikeyan, C. C. Berndt, J. Tikkanen, Preparation of nanophase materials by thermal spray processing of liquid precursors. Nanostructured Materials, 1997, 9:137-140
5X.Q. Cao, R. Vassen, S. Schwartz , W. Jungen, F. Tietz, D. Sto ever. Spray-drying of ceramics for plasma-spray coating. Journal of the European Ceramic Society,2000, 20(14-15) : 2433-2439
6林新华．等离子喷涂纳米结构氧化铝-3wt．％氧化钛涂层的制备及表征．上海：中国科学院上海硅酸盐研究所，2003
7http://www. sunspraying. com/cn/ArticleShow. asp? ArticleID=530
8P Fauchais, Understanding plasma spraying, Journal of physics D: applied physics, 2004, 37(9): R86 R108
9M. Gell, E. H. Jordan, Y. H. Sohn, D. Goberman, L.Shaw, T. D. Xiao. Development and implementation of plasma sprayed nanostructured ceramic coatings. Surface and Coatings Technology, 2001,146 147(9): 48 54
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纳米结构陶瓷涂层的外圆磨削力以及磨削表面精度的实验研究(英文) 被引量：2

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