Non-spherical multi-oscillations of a bubble in a compressible liquid

Bubble dynamics are associated with wide and important applications in cavitation erosion in many industrial systems, medical ultrasonics and underwater explosions. Two recent developments to this classical problem are reviewed in this paper. Firstly, computational studies on the problem have common...

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Veröffentlicht in:	Journal of hydrodynamics. Series B 2015-01, Vol.26 (6), p.848-855
Hauptverfasser:	WANG, Qian-xi, YANG, Yuan-xiang, TAN, Danielle Sweimann, SU, Jian, TAN, Soon Keat
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Sprache:	eng
Schlagworte:	boundary integral method Bubbles Cavitation erosion Compressibility compressible bubble dynamics Computation Dynamical systems Dynamics Engineering Engineering Fluid Dynamics Hydrology/Water Resources Mathematical models Medical Numerical and Computational Physics Oscillations Review Article Simulation weakly compressible theory 可压缩液体工业系统气泡动力学水下爆炸流体模型边界积分法阻尼振荡非球面
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container_title	Journal of hydrodynamics. Series B
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creator	WANG, Qian-xi YANG, Yuan-xiang TAN, Danielle Sweimann SU, Jian TAN, Soon Keat
description	Bubble dynamics are associated with wide and important applications in cavitation erosion in many industrial systems, medical ultrasonics and underwater explosions. Two recent developments to this classical problem are reviewed in this paper. Firstly, computational studies on the problem have commonly been based on an incompressible fluid model. However, a bubble usually undergoes significantly damped oscillation due to the compressible effects. We model this phenomenon using weakly compressible theory and a modified boundary integral method. This model considers the energy loss due to shock waves emitted at minimum bubble volumes. Secondly, the computational studies so far have largely been concerned with the first-cycle of oscillation. However, a bubble usually oscillates for a few cycles before it breaks into much smaller ones. We model both the first- and second-cycles of oscillationand predict damped oscillations. Our computations correlate well with the experimental data.
doi_str_mv	10.1016/S1001-6058(14)60093-7
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Series B</title><addtitle>J Hydrodyn</addtitle><addtitle>Journal of Hydrodynamics</addtitle><description>Bubble dynamics are associated with wide and important applications in cavitation erosion in many industrial systems, medical ultrasonics and underwater explosions. Two recent developments to this classical problem are reviewed in this paper. Firstly, computational studies on the problem have commonly been based on an incompressible fluid model. However, a bubble usually undergoes significantly damped oscillation due to the compressible effects. We model this phenomenon using weakly compressible theory and a modified boundary integral method. This model considers the energy loss due to shock waves emitted at minimum bubble volumes. Secondly, the computational studies so far have largely been concerned with the first-cycle of oscillation. However, a bubble usually oscillates for a few cycles before it breaks into much smaller ones. 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subjects	boundary integral method Bubbles Cavitation erosion Compressibility compressible bubble dynamics Computation Dynamical systems Dynamics Engineering Engineering Fluid Dynamics Hydrology/Water Resources Mathematical models Medical Numerical and Computational Physics Oscillations Review Article Simulation weakly compressible theory 可压缩液体工业系统气泡动力学水下爆炸流体模型边界积分法阻尼振荡非球面
title	Non-spherical multi-oscillations of a bubble in a compressible liquid
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