Features of the Behavior of a Plane Axisymmetric Mag-netic Fluid Drop in a Nonmagnetic Solvent and a Uni-form Magnetic Field

Q3 Energy

Energetika. Proceedings of CIS Higher Education Institutions and Power Engineering Associations Pub Date : 2022-12-07 DOI:10.21122/1029-7448-2022-65-6-551-561

V. Bashtovoi, A. Reks, A. A. Zahadskaya

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Abstract

The work is devoted to an experimental study of the process of dissolution of a magnetic fluid in a nonmagnetic solvent under the action of a uniform magnetic field. It is experimentally established that in a volume of magnetic fluid surrounded by a miscible solvent fluid, under the action of a uniform magnetic field, a mechanical movement arises, triggering deformation of this volume. Initially, the axisymmetric volume of the fluid takes an ellipsoidal shape, lengthening along the magnetic field direction. The main reason for this movement is the pressure differences in the magnetic fluid, caused by jumps and nonuniformities of the magnetic field at the interface between magnetic and nonmagnetic media. Simultaneously with the mechanical motion, the diffusion dissolution of the magnetic fluid occurs, which is also accompanied by the motion of the diffusion front at the interface between the fluids. The concentration gradients of magnetic particles that arise in this case cause gradients of the magnetization of the fluid and, as a consequence, gradients of the magnetic field intensity. Together, this triggers the appearance of a bulk magnetic force in the magnetic fluid, and the pressure gradients associated with it. The main regularities of this process have been established, viz. the dependence of change of the geometric characteristics of the volume and its deformation rate on time. It is shown that at the initial stage of the process, the rates of mechanical movement of the boundaries of the magnetic fluid volume are much higher than the rates of movement of the diffusion front. Thus, the initial rate of mechanical elongation of the droplet under the experimental conditions is 0.25 mm/min, and the diffusion front rate is 0.08 mm/min. Over time, these processes slow down and stop when the volume of the magnetic fluid is completely dissolved. Herewith, the mechanical elongation of the drop is the first to stop and, in the case under consideration, takes about ten minutes.

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平面轴对称磁流体滴在非磁性溶剂和均匀磁场中的行为特征

本文致力于在均匀磁场作用下，对磁性流体在非磁性溶剂中的溶解过程进行实验研究。实验证明，在被混溶溶剂流体包围的磁性流体体积中，在均匀磁场的作用下，产生机械运动，引起该体积的变形。最初，流体的轴对称体积呈椭球形状，沿磁场方向延长。这种运动的主要原因是磁性流体中的压力差，这是由磁性和非磁性介质之间的界面处磁场的跳跃和不均匀性引起的。在机械运动的同时，磁流体的扩散溶解也发生了，这一过程还伴随着流体界面处扩散锋的运动。在这种情况下产生的磁性颗粒的浓度梯度引起流体磁化强度的梯度，从而引起磁场强度的梯度。总之，这触发了磁性流体中大量磁力的出现，以及与之相关的压力梯度。建立了这一过程的主要规律，即体积几何特性的变化及其变形速率随时间的变化关系。结果表明，在过程的初始阶段，磁流体体积边界的机械运动速率远大于扩散锋的运动速率。因此，在实验条件下，液滴的初始机械伸长率为0.25 mm/min，扩散锋速率为0.08 mm/min。随着时间的推移，当磁性流体的体积完全溶解时，这些过程减慢并停止。因此，液滴的机械伸长首先停止，在考虑的情况下，大约需要十分钟。

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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来源期刊

Energetika. Proceedings of CIS Higher Education Institutions and Power Engineering Associations Energy-Nuclear Energy and Engineering

CiteScore

1.60

自引率

0.00%

发文量

审稿时长

8 weeks

期刊介绍： The most important objectives of the journal are the generalization of scientific and practical achievements in the field of power engineering, increase scientific and practical skills as researchers and industry representatives. Scientific concept publications include the publication of a modern national and international research and achievements in areas such as general energetic, electricity, thermal energy, construction, environmental issues energy, energy economy, etc. The journal publishes the results of basic research and the advanced achievements of practices aimed at improving the efficiency of the functioning of the energy sector, reduction of losses in electricity and heat networks, improving the reliability of electrical protection systems, the stability of the energetic complex, literature reviews on a wide range of energy issues.