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超疏水表面上空化气泡与气盾之间的相互作用。

Interaction between cavitation bubbles and plastrons on superhydrophobic surfaces.

作者信息

Huang Caisheng, He Xiaolong, Zhang Jianmin

机构信息

State Key Laboratory of Hydraulics and Mountain River Engineering, Sichuan University, Chengdu 610065, China.

State Key Laboratory of Hydraulics and Mountain River Engineering, Sichuan University, Chengdu 610065, China.

出版信息

Ultrason Sonochem. 2024 Oct;109:107016. doi: 10.1016/j.ultsonch.2024.107016. Epub 2024 Aug 8.

DOI:10.1016/j.ultsonch.2024.107016
PMID:39126991
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11369417/
Abstract

The interaction between cavitation bubbles and plastrons on superhydrophobic surfaces was investigated using a low-voltage discharge device and high-speed photography techniques. The plastron adhered to the superhydrophobic surface acts as a liquid-gas interface, giving the boundary the ability to repel cavitation bubbles. The direction of bubble collapse is determined by the vector synthesis of the Bjerknes repulsive force from the plastron and the Bjerknes attractive force from the rigid wall when the bubble collapses for the first time. Various collapse behaviors were observed, including bubbles moving away from the plastron, bubbles orienting towards the plastron, and bubbles splitting into sub-bubbles in opposite directions. During the subsequent evolution of the bubbles, the expansion of the plastron led to the reversal of the downward jet or reduced the impact velocity of the jet. Seven jet patterns were identified based on the evolution of the cavitation bubble. Starting from the impact velocity of the jet, three jet patterns, namely, the jet away from the plastron (JA), the funnel-shaped jet away from the plastron (JAF), and the funnel-shaped jet away from the plastron with vortex shedding (JAFV), were found to have a weaker effect on the boundary. Three criteria for the design of plastrons on superhydrophobic surfaces were established: V>0.25V, H>0.55R, D>1.2R. Passive pulsation of the plastron in response to the cavitation bubble exhibited similar behaviors across seven jet patterns except for the JAF pattern: torus-shaped, dish-shaped, and skirt-shaped. The dimensionless wall distance, volume ratio, and plastron morphology parameters were identified as significant factors influencing the interaction between cavitation bubbles and the plastron.

摘要

利用低压放电装置和高速摄影技术,研究了超疏水表面上空化气泡与气膜之间的相互作用。附着在超疏水表面的气膜充当液 - 气界面,使边界具有排斥空化气泡的能力。当气泡首次坍塌时,气泡坍塌的方向由来自气膜的毕克内斯排斥力和来自刚性壁的毕克内斯吸引力的矢量合成决定。观察到了各种坍塌行为,包括气泡远离气膜、气泡朝向气膜定向以及气泡分裂成相反方向的子气泡。在气泡的后续演化过程中,气膜的膨胀导致向下喷射流的反转或降低了喷射流的冲击速度。基于空化气泡的演化确定了七种喷射模式。从喷射流的冲击速度来看,发现三种喷射模式,即远离气膜的喷射流(JA)、远离气膜的漏斗形喷射流(JAF)和带有涡旋脱落的远离气膜的漏斗形喷射流(JAFV),对边界的影响较弱。建立了超疏水表面上气膜设计的三个标准:V>0.25V、H>0.55R、D>1.2R。除JAF模式外,气膜对空化气泡的被动脉动在七种喷射模式中表现出相似的行为:环形、盘形和裙形。无量纲壁距、体积比和气膜形态参数被确定为影响空化气泡与气膜相互作用的重要因素。

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