Process mechanism in ultrasonic cavitation assisted fluid jet polishing

Anthony Beaucamp; Tomoya Katsuura; Kie Takata

doi:10.1016/j.cirp.2018.04.075

Process mechanism in ultrasonic cavitation assisted fluid jet polishing

Anthony Beaucamp, Tomoya Katsuura, Kie Takata

研究成果: Article › 査読

28 被引用数 (Scopus)

抄録

Material removal rate in fluid jet polishing is significantly enhanced when ultrasonic cavitation bubbles are introduced at the nozzle outlet. In this paper, two theories are put forward to explain the process mechanism: a micro-scale hypothesis in which the surface is micro-jetted by collapsing bubbles, and a macro-scale hypothesis in which vibration of the fluid in the impingement region increases abrasive particle erosive action. Experimental investigation suggests the higher likelihood of the macro-scale phenomenon, and a material removal model is proposed accordingly. Process footprints simulated by this model were found to agree well with experimental measurements.

本文言語	English
ページ（範囲）	361-364
ページ数	4
ジャーナル	CIRP Annals
巻	67
号	1
DOI	https://doi.org/10.1016/j.cirp.2018.04.075
出版ステータス	Published - 2018 1月 1
外部発表	はい

ASJC Scopus subject areas

機械工学
産業および生産工学

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10.1016/j.cirp.2018.04.075

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title = "Process mechanism in ultrasonic cavitation assisted fluid jet polishing",

abstract = "Material removal rate in fluid jet polishing is significantly enhanced when ultrasonic cavitation bubbles are introduced at the nozzle outlet. In this paper, two theories are put forward to explain the process mechanism: a micro-scale hypothesis in which the surface is micro-jetted by collapsing bubbles, and a macro-scale hypothesis in which vibration of the fluid in the impingement region increases abrasive particle erosive action. Experimental investigation suggests the higher likelihood of the macro-scale phenomenon, and a material removal model is proposed accordingly. Process footprints simulated by this model were found to agree well with experimental measurements.",

keywords = "Finishing, Fluid jet polishing, Ultrasonic",

author = "Anthony Beaucamp and Tomoya Katsuura and Kie Takata",

note = "Funding Information: This work was supported by the Grant-in-Aid for Scientific Research No. 17K14571 from the Japan Society for Promotion of Science. The authors acknowledge support from Zeeko Ltd. in loaning the FJP system, Kaijo KK for manufacturing the custom transducer and acoustic lens, Kyowa Industrial Co. for providing work samples, and finally the invaluable advice and support from Prof. Koji Eriguchi and Kazuya Tatsumi of Kyoto University. Funding Information: This work was supported by the Grant-in-Aid for Scientific Research No. 17K14571 from the Japan Society for Promotion of Science . The authors acknowledge support from Zeeko Ltd. in loaning the FJP system, Kaijo KK for manufacturing the custom transducer and acoustic lens, Kyowa Industrial Co. for providing work samples, and finally the invaluable advice and support from Prof. Koji Eriguchi and Kazuya Tatsumi of Kyoto University. Publisher Copyright: {\textcopyright} 2018",

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AU - Katsuura, Tomoya

AU - Takata, Kie

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Y1 - 2018/1/1

N2 - Material removal rate in fluid jet polishing is significantly enhanced when ultrasonic cavitation bubbles are introduced at the nozzle outlet. In this paper, two theories are put forward to explain the process mechanism: a micro-scale hypothesis in which the surface is micro-jetted by collapsing bubbles, and a macro-scale hypothesis in which vibration of the fluid in the impingement region increases abrasive particle erosive action. Experimental investigation suggests the higher likelihood of the macro-scale phenomenon, and a material removal model is proposed accordingly. Process footprints simulated by this model were found to agree well with experimental measurements.

AB - Material removal rate in fluid jet polishing is significantly enhanced when ultrasonic cavitation bubbles are introduced at the nozzle outlet. In this paper, two theories are put forward to explain the process mechanism: a micro-scale hypothesis in which the surface is micro-jetted by collapsing bubbles, and a macro-scale hypothesis in which vibration of the fluid in the impingement region increases abrasive particle erosive action. Experimental investigation suggests the higher likelihood of the macro-scale phenomenon, and a material removal model is proposed accordingly. Process footprints simulated by this model were found to agree well with experimental measurements.

KW - Finishing

KW - Fluid jet polishing

KW - Ultrasonic

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Process mechanism in ultrasonic cavitation assisted fluid jet polishing

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