Breakdown and interface dynamics of pulsed discharge plasma across air-water interface: From single to repetitive stimulation

IF 3.6 2区 工程技术 Q1 MECHANICS International Journal of Multiphase Flow Pub Date : 2024-08-18 DOI:10.1016/j.ijmultiphaseflow.2024.104960
Ruoyu Han , Jie Bai , Sichao Qin , Menglei Wang , Jingran Li , Wei Yuan , Xi Chen , Yuan Li
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Abstract

Pulsed discharge in the vicinity of a multi-phase interface, where a discontinuity of physical properties exists, can be a joint problem of both electro- and thermo-physics. This study shows a comprehensive analysis of electric breakdown across an air-water interface and its successive multi-physical effects. The scenario is constructed via a pair of pin electrodes positioned on both sides of the interface, and the transient discharge is analyzed using high-speed backlight photography synchronized with electrical and optical diagnostics. It is observed that the corona/streamer develops from either side of the pin electrode. Electrostatic instability causes the interface to fluctuate and a water column to form above the interface. By increasing the applied voltage, discharge evolves from “dielectric barrier” mode (pin to interface) to “through breakdown” mode (pin to pin). Once the conductive channel bridges two electrodes, electric power of ∼40 kW peak and deposited energy of 100 mJ will be injected into the channel and promote the “streamer-spark” transition, resulting in a crown-like splash (100 m s-1) near the interface and cavity formation. As the quenching of diffused plasmas, the over-expanded splash (5 mm in diameter) would be re-compressed by the ambient air. Particularly, the shrinkage of the thin water film of the splash can reach a 20 mm jet near the axis and develop Rayleigh-Taylor instability, along with the formation of micro-jets eruption during the convergent collision. More sophisticated interactions will appear at higher repetitive frequency (>100 Hz), where the perturbation caused by one pulse will influence the next, namely the “memory” effect. Furthermore, periodic loading on the interface effectively changes the cavity characteristics, showing an attractive prospect in fluid control applications.

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脉冲放电等离子体在空气-水界面上的分解和界面动力学:从单一刺激到重复刺激
在物理特性不连续的多相界面附近发生脉冲放电,可能是一个电物理和热物理的共同问题。本研究全面分析了空气-水界面上的电击穿及其连续的多物理效应。通过在界面两侧设置一对针电极来构建场景,并使用与电气和光学诊断同步的高速背光摄影来分析瞬态放电。据观察,电晕/流体从针电极的两侧产生。静电不稳定性导致界面波动,并在界面上方形成水柱。通过增加外加电压,放电从 "介质阻隔 "模式(引脚到界面)演变为 "击穿 "模式(引脚到引脚)。一旦导电通道桥接两个电极,峰值为 40 kW、沉积能量为 100 mJ 的电力将注入通道,并促进 "流星-火花 "转换,从而在界面附近产生冠状飞溅(100 m s-1)并形成空腔。随着扩散等离子体的淬火,过度膨胀的飞溅物(直径 5 毫米)将被环境空气重新压缩。特别是,飞溅的薄水膜收缩后可在轴附近形成 20 毫米的射流,并产生瑞利-泰勒不稳定性,同时在会聚碰撞过程中形成微射流喷发。在更高的重复频率(100 赫兹)下,会出现更复杂的相互作用,一个脉冲造成的扰动会影响下一个脉冲,即 "记忆 "效应。此外,对界面的周期性加载可有效改变空腔特性,在流体控制应用中展现出诱人的前景。
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来源期刊
CiteScore
7.30
自引率
10.50%
发文量
244
审稿时长
4 months
期刊介绍: The International Journal of Multiphase Flow publishes analytical, numerical and experimental articles of lasting interest. The scope of the journal includes all aspects of mass, momentum and energy exchange phenomena among different phases such as occur in disperse flows, gas–liquid and liquid–liquid flows, flows in porous media, boiling, granular flows and others. The journal publishes full papers, brief communications and conference announcements.
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