MHD磁场对铁磁流体晃动的数值研究:基于水平集法

R. Maroofiazar, M. Daryani, Amir Reza Vakhshouri
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引用次数: 1

摘要

晃动现象在各种生产过程中都有发生,其应用也非常广泛。这种现象发生在当一个容器部分充满了流体,并且在外力的影响下,液体的自由表面移动并与容器壁交换力。本文采用数值模拟方法研究了铁磁流体在长10 cm × 5 cm矩形容器内的晃动行为。推动容器的力是在x轴方向上的振荡运动。施加均匀磁力会在控制方程(如动量方程)中产生额外的模块,从而对这种现象和流体运动产生影响。本研究的主要目的是研究不同方向和角度的均匀磁流体场对铁磁流体晃动的影响。通过研究一些因素(如;确定了铁磁流体对容器壁上特定点的压力,任意时刻的最大表面,以及不同时刻表面情况的分析,确定了不同角度的磁场对铁磁流体晃动的影响。结果表明,在没有外加磁场的情况下,水和铁磁流体的晃动行为基本相同。施加高密度磁场,在0◦、45◦和90◦磁场角度下,液面最大高度分别降低了14.5%、25%和36%。因此,这些结果表明了磁场方向对铁磁流体晃动行为的影响。
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Numerical Investigation of Ferrofluid Sloshing by Applying MHD Magnetic Field: Using Level Set Method
The sloshing phenomenon has exceptional significance due to its occurrence in various processes as well as its application. This phenomenon occurs when a vessel is partly filled with a fluid and under the influence of external forces the free surface of the liquid moves and exchanges forces with the wall of the vessel. In this research, numerical modeling is used to study the behavior of ferrofluid in sloshing phenomenon in a rectangular container with a specified length and width of 10 cm × 5 cm respectively. The force that moves the vessel is the oscillatory motion in the x-axis direction. Applying a uniform magnetic force, which creates additional modules in the governing equations, such as the momentum equation, has effects on this phenomenon and fluid motion. The main aim of this research is to study the effects of the uniform MHD field in different directions and angles on the ferrofluid sloshing. By studying the results of some factors (such as; the pressure of the ferrofluid to the specific points on the vessel wall, the maximum surface at any time, and the analysis of the surface situation at different times) the impact of the magnetic field with different angles has been identified on the ferrofluid sloshing. The results showed that in the absence of an external magnetic field, the sloshing behavior of water and ferrofluid were approximately the same. Applying the MHDmagnetic field caused a 14.5%, 25% and 36% decrease in the maximum height of the fluid level at angles 0◦, 45◦ and 90◦ of magnetic field respectively. Therefore, these results indicate the influence of the magnetic field direction on the behavior of the ferrofluid sloshing.
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8.30%
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