Experimental Study on Ultrasonic Cavitation Assisted Micro Drilling of Stainless Steel

被引:0
|
作者
Liang Z. [1 ]
Ma Y. [2 ]
Nie Q. [2 ]
Wang X. [1 ]
Zhou T. [1 ]
Guo H. [2 ]
Li Y. [3 ]
Chen J. [3 ]
机构
[1] Key Laboratory of Fundamental Science for Advanced Machining, Beijing Institute of Technology, Beijing
[2] School of Mechanical Engineering, Beijing Institute of Technology, Beijing
[3] Shanxi Diesel Engine Industoy Co., Ltd., Datong
来源
Jixie Gongcheng Xuebao/Journal of Mechanical Engineering | 2020年 / 56卷 / 01期
关键词
Micro-hole morphology; Roundness error; Surface roughness; Ultrasonic cavitation;
D O I
10.3901/JME.2020.01.205
中图分类号
学科分类号
摘要
This paper proposes a micro-hole ultrasonic cavitation assisted drilling method to improve chip removal performance and micro-hole machining quality during micro-drilling of difficult-to-machine materials. The mechanism of ultrasonic cavitation is analyzed. Through the observation of ultrasonic cavitation process by high-speed camera, the taper cavitation area is formed on the end face of the horn, and its range of action reaches more than 10mm. Cavitation drilling experiments of resin workpieces with diameters of 3 mm and 0.5 mm are carried out respectively, and it is found that the ultrasonic cavitation effect significantly improves the adhesion and entanglement of the chips to the cutter. Ultrasonic cavitation drilling experiments of stainless steel micro-holes with different spindle speeds are conducted. The entrance morphology, roundness, pore wall morphology and surface roughness of micro-holes are observed and measured by laser scanning microscopy. Compared with ordinary drilling, ultrasonic cavitation drilling reduces the aperture error by 8.5%-15.6%, the entrance roundness error decreases by 20.0%-37.8%, and the hole wall roughness decreases by 12.7%-18.6%. The results show that ultrasonic cavitation effect can effectively improve the quality and accuracy of micro-hole machining. © 2020 Journal of Mechanical Engineering.
引用
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页码:205 / 212
页数:7
相关论文
共 15 条
  • [1] Lauterborn W., Kurz T., Geisler R., Et al., Acoustic cavitation bubble dynamics and sonoluminescence, Ultrasonics Sonochemistry, 14, 4, pp. 484-491, (2007)
  • [2] Mo R., Lin S., Wang C., Methods of study on sound cavitation, Applied Acoustics, 28, 5, pp. 389-400, (2009)
  • [3] Liew P.J., Yan J., Kuriyagawa T., Fabrication of deep micro-holes in reaction-bonded SiC by ultrasonic cavitation assisted micro-EDM, International Journal of Machine Tools and Manufacture, 76, 1, pp. 13-20, (2014)
  • [4] Liu K., Yasutomo K., Ding X., Et al., Ultrasonic vibration assisted electro-discharge machining of deep micro holes, The 6th International Conference European Society for Precision Engineering and Nanotechnology (EUSPEN 2006), (2006)
  • [5] Toh C.K., The use of ultrasonic cavitation peening to improve micro-burr-free surfaces, The International Journal of Advanced Manufacturing Technology, 31, 7-8, pp. 688-693, (2007)
  • [6] Xu W., Lu X., Pan G., Et al., Effects of the ultrasonic flexural vibration on the interaction between the abrasive particles
  • [7] pad and sapphire substrate during chemical mechanical polishing (CMP), Applied Surface Science, 257, 7, pp. 2905-2911, (2011)
  • [8] Xu W., Lu X., Pan G., Et al., Ultrasonic flexural vibration assisted chemical mechanical polishing for sapphire substrate, Applied Surface Science, 256, 12, pp. 3936-3940, (2010)
  • [9] Ye L., Zhu X., Wang J., Et al., Cavitation micro-jet impact in ultrasonic honing based on SPH-FEM, Journal of Vibration and Shock, 35, 13, pp. 72-77, (2016)
  • [10] Zhu X., Ye L., Analysis of power ultrasonic honing cavitation test, Journal of Mechanical Engineering, 53, 19, pp. 136-142, (2017)
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