Stability effect of an axial magnetic field on fluid flow bifurcation between coaxial cylinders

IF 1.4 Q4 MATERIALS SCIENCE, MULTIDISCIPLINARY
H. Benhacine, B. Mahfoud, M. Salmi
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引用次数: 1

Abstract

Numerical simulations aim to investigate the bifurcation caused by swirling flow between two coaxial vertical cylinders, and the fluid layers produced by the thermal gradient. The stability of both bifurcation and fluid layers by an axial magnetic field is analyzed. The finite-volume method is used to solve the governing Navier–Stokes, temperature and potential equations. A conducting viscous fluid characterized by a small Prandtl number [Formula: see text] is placed in the gap between two coaxial cylinders. The combination of aspect ratio, [Formula: see text] and Reynolds number, [Formula: see text] for three annular gaps ([Formula: see text] and [Formula: see text]) is compared in terms of flow stability, and heat transfer rates. Without a magnetic field, the vortex breakdown takes place near the inner cylinder due to the increased pumping action of the Ekman boundary layer. Fluid layered structures are developed by the competition between buoyancy and viscous forces. The increase in the magnitude of the magnetic field retarders the onset of the oscillatory instability caused by the disappearance of the vortex breakdown and reduces the number of fluid layers. The limits in which a vortex breakdown bubble manifests and the limits of transition from the multiple fluid layers to the single fluid layer are established.
轴向磁场对同轴圆柱间流体分岔的稳定性影响
数值模拟的目的是研究两个同轴垂直圆柱之间的旋流引起的分岔,以及热梯度产生的流体层。分析了轴向磁场作用下分岔层和流体层的稳定性。用有限体积法求解了控制Navier-Stokes方程、温度方程和势方程。将具有小普朗特数特征的导电粘性流体[公式:见文本]置于两个同轴圆柱体之间的间隙中。对三个环形间隙([公式:见文]和[公式:见文])的展弦比、[公式:见文]和雷诺数[公式:见文]的组合进行流动稳定性和换热率的比较。在没有磁场的情况下,由于埃克曼边界层的泵送作用增加,涡流击穿发生在内筒附近。流体层状结构是由浮力和粘性力相互竞争而形成的。磁场强度的增加延缓了旋涡击穿消失引起的振荡不稳定性的发生,并减少了流体层数。建立了涡旋破裂泡的表现极限和由多流体层向单流体层过渡的极限。
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
CiteScore
2.10
自引率
15.40%
发文量
27
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