Experimental study of temperature effect on the growth and collapse of cavitation bubbles near a rigid boundary

LIU Xiu-mei; LONG Zheng; HE Jie; LI Bei-bei; LIU Xin-hua; ZHAO Ji-yun; LU Jian; NI Xiao-wu

doi:doi:10.1007/s11801-013-2422-y

光电子快报（英文版）, 2013, 9 (4): 317, Published Online: Oct. 12, 2017

Experimental study of temperature effect on the growth and collapse of cavitation bubbles near a rigid boundary

论文大纲

LIU Xiu-mei ^1,*LONG Zheng ¹HE Jie ¹LI Bei-bei ¹LIU Xin-hua ¹ZHAO Ji-yun ¹LU Jian ²NI Xiao-wu ²

Author Affiliations

¹ School of Mechatronic Engineering, China University of Mining and Technology, Xuzhou 221116, China

² Department of Applied Physics, Nanjing University of Science &Technology, Nanjing 210094, China

Abstract

The effect of temperature on the dynamics of a laser-induced cavitation bubble is studied experimentally. The growth and collapse of the cavitation bubble are measured by two sensitive fiber-optic sensors based on optical beam deflection (OBD). Cavitation bubble tests are performed in water at different temperatures, and the temperature ranges from freezing point (0 °C) to near boiling point. The results indicate that both the maximum bubble radius and bubble lifetime are increased with the increase of temperature. During the stage of bubble rapidly collapsing in the vicinity of a solid surface, besides laser ablation effect, both the first and second liquid-jet-induced impulses are also observed. They are both increased with liquid temperature increasing, and then reach a peak, followed by a decrease. The peak appears at the temperature which is approximately the average of freezing and boiling points. The mechanism of liquid temperature influence on cavitation erosion is also discussed.

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LIU Xiu-mei, LONG Zheng, HE Jie, LI Bei-bei, LIU Xin-hua, ZHAO Ji-yun, LU Jian, NI Xiao-wu. Experimental study of temperature effect on the growth and collapse of cavitation bubbles near a rigid boundary[J]. 光电子快报（英文版）, 2013, 9(4): 317.

Experimental study of temperature effect on the growth and collapse of cavitation bubbles near a rigid boundary

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