Experimental investigation on surface quality in ultrasonic vibration assisted high speed grinding of BK7 optical glass

被引：0

作者：

Zhou M. ^{[1
]}

Zhao P. ^{[2
]}

Huang S. ^{[3
]}

机构：

[1] School of Mechanical and Electrical Engineering, Harbin Institute of Technology, Harbin

[2] School of Mechanical Engineering, Harbin University of Science and Technology, Harbin

[3] School of Applied Technology, Jiamusi University, Jiamusi

来源：

Zhao, Peiyi (653825080@qq.com) | 2018年 / Inderscience Publishers, 29, route de Pre-Bois, Case Postale 856, CH-1215 Geneva 15, CH-1215, Switzerland卷 / 11期

基金：

中国国家自然科学基金;

关键词：

Grinding; Optical glass; Surface formation; Surface roughness; Ultrasonic vibration;

D O I：

10.1504/IJMMS.2018.095459

中图分类号：

学科分类号：

摘要：

Knowledge of surface formation mechanism plays a key role in implementing precision machining of optical glass materials. In order to evaluate the surface quality and to explore surface formation mechanism, in this paper, ultrasonic vibration assisted grinding (UVAG) experiments were carried out on BK7 optical glass by employing diamond wheel. Quite a few micro and macro brittle-fractured pits of different shapes, sizes and morphologies were observed on machined surfaces by using scanning electron microscope. Spindle rotation speed, feed rate, grinding depth and ultrasonic vibration amplitude had be found to exert significant effects on the surface generation and machined surface roughness in ultrasonic vibration assisted grinding of this kind of materials. It was also demonstrated that the value of machined surface roughness would become much smaller if the pits size was small. Based on the observation and classification of pits morphologies, the machined surfaces forming mechanism was extensively investigated in this work. © Copyright 2018 Inderscience Enterprises Ltd.

引用

页码：299 / 313

页数：14

共 20 条

[1] Brinksmeier E., Mutlugunes Y., Klocke F., Aurich J.C., Shore P., Ohmori H., Ultra-precision grinding, Manufacturing Technology, 59, 2, pp. 652-671, (2010)
[2] Cao J.G., Wu Y.B., Lu D., Et al., Material removal behavior in ultrasonic-assisted scratching of SiC ceramics with a single diamond tool, International Journal of Machine Tools & Manufacture, 79, 4, pp. 49-61, (2014)
[3] Churi N.J., Pei Z.J., Treadwell C., Rotary ultrasonic machining of titanium alloy (Ti-6Al-4V): Effects of tool variables, Machining Science & Technology, 10, 3, pp. 301-321, (2006)
[4] Cong W.L., Pei Z.J., Sun X., Zhang C.L., Rotary ultrasonic machining of CFRP: A mechanistic predictive model for cutting force, Ultrasonics, 54, 2, pp. 663-675, (2014)
[5] Fang F.Z., Zhang G.X., An experimental study of optical glass machining, International Journal of Advanced Manufacturing Technology, 23, 3-4, pp. 155-160, (2004)
[6] Fang F.Z., Ni H., Gong H., Rotary ultrasonic machining of hard and brittle materials, Nanotechnology & Precision Engineering, 12, 3, pp. 227-234, (2014)
[7] Feng P.F., Liang G.Q., Zhang J.F., Ultrasonic vibration-assisted scratch characteristics of silicon carbide-reinforced aluminum matrix composites, Ceramics International, 40, 7, pp. 10817-10823, (2014)
[8] Gu W.B., Yao Z., Liang X., Material removal of optical glass BK7 during single and double scratch tests, Wear, 270, 3, pp. 241-246, (2011)
[9] Jiang C., Wang C.H., Li H.L., Experimental investigation of brittle material removal fraction on an optical glass surface during ultrasound-assisted grinding, International Journal of Advanced Manufacturing Technology, 86, 1, pp. 1-8, (2015)
[10] Komanduri R., On material removal mechanisms in finishing of advanced ceramics and glasses, Manufacturing Technology, 45, 1, pp. 509-514, (1996)

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