在疏水性液体中形成自带电场的三相空化气泡

IF 1 4区 工程技术 Q4 MECHANICS Fluid Dynamics Pub Date : 2024-11-07 DOI:10.1134/S0015462824603243
A. A. Monakhov
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引用次数: 0

摘要

本文介绍了非同心圆柱体之间疏水性液体流动的实验研究结果。在流动膨胀区域,根据圆柱体之间的间隙大小,可以观察到溶解气体的气穴现象。如果液体中含有水,还可以观察到杂质的蒸汽空化。当间隙较小的气缸表面相互滑动时,就会产生水的蒸汽空化。水蒸气在停止流动时凝结成微滴。带水微滴的三相气泡在气液界面形成。这种气泡设计具有自己的电场。当气泡上升时,气泡中的水微滴会沿着气液界面移动,并与相邻气泡的表面保持最小距离。如果附近有几个三相气泡,其中的水微滴就会分裂,从而显示出相邻电场源的方向。根据已完成的研究,获得了准静态电场源注册方法的专利。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

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Formation of Three-Phase Cavitation Bubbles with Their Own Electric Field in a Hydrophobic Liquid

In the paper, we present the results of an experimental study of a hydrophobic liquid flow between non-concentric cylinders. In the region of flow expansion, gas cavitation of the dissolved gas can be observed depending on the gap size between the cylinders. If the liquid contains water, steam cavitation of the impurity can be also observed. Steam cavitation of water occurs when the surfaces of the cylinders with a small gap slide between each other. Water vapor condenses into microdroplets when the flow stops. Three-phase gas bubbles with water microdroplets are formed at the gas-liquid interface. This gas bubble design is shown to have its own electric field. When a bubble rises, its water microdroplet moves along the gas-liquid interface and occupies a minimal distance from the surface of the neighboring bubble. In the case of several three-phase bubbles located nearby, the water microdroplets in them split, indicating the direction of the neighboring electric field sources. A patent for a method of registering sources of quasi-static electric fields was obtained based on the performed research.

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来源期刊
Fluid Dynamics
Fluid Dynamics MECHANICS-PHYSICS, FLUIDS & PLASMAS
CiteScore
1.30
自引率
22.20%
发文量
61
审稿时长
6-12 weeks
期刊介绍: Fluid Dynamics is an international peer reviewed journal that publishes theoretical, computational, and experimental research on aeromechanics, hydrodynamics, plasma dynamics, underground hydrodynamics, and biomechanics of continuous media. Special attention is given to new trends developing at the leading edge of science, such as theory and application of multi-phase flows, chemically reactive flows, liquid and gas flows in electromagnetic fields, new hydrodynamical methods of increasing oil output, new approaches to the description of turbulent flows, etc.
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