Parametric analysis of magnetic field-dependent viscosity and advection–diffusion between rotating discs

IF 1.7 4区材料科学 Q3 MATERIALS SCIENCE, COMPOSITES

Advanced Composites Letters Pub Date : 2020-01-31 DOI:10.1177/2633366X19896373

R. Shah, Aamir Khan, Amjad Ali

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引用次数: 1

Abstract

The constitutive expressions of unsteady Newtonian fluid are employed in the mathematical formulation to model the flow between the circular space of porous and contracting discs. The flow behavior is investigated for magnetic field-dependent (MFD) viscosity and heat/mass transfers under the influence of a variable magnetic field. The equation for conservation of mass, modified Navier–Stokes, Maxwell, advection diffusion and transport equations are coupled as a system of ordinary differential equations. The expressions for torques and magnetohydrodynamic pressure gradient equation are derived. The MFD viscosity ϑ , magnetic Reynolds number ℵ e m , squeezing Reynolds number ℵ b , rotational Reynolds number ℵ a , magnetic field components ℵ c , ℵ d , pressure F pres and the torques ϱ ′ 0 , ϱ 1 which the fluid exerts on discs are discussed through numerical results and graphical aids. It is concluded that magnetic Reynolds number causes an increase in magnetic field distributions and decrease in tangential velocity of flow field, also the fluid temperature is decreasing with increase in magnetic Reynolds number. The azimuthal and axial components of magnetic field have opposite behavior with increase in MFD viscosity.

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旋转圆盘间磁场依赖粘度和平流扩散的参数分析

数学公式中采用了非定常牛顿流体的本构表达式来模拟多孔圆盘和收缩圆盘之间的流动。研究了在可变磁场影响下，磁场相关（MFD）粘度和热/质量传递的流动行为。质量守恒方程、修正的Navier-Stokes方程、Maxwell方程、平流扩散方程和输运方程被耦合为一个常微分方程组。推导了力矩和磁流体压力梯度方程的表达式。MFD粘度，磁雷诺数ℵ e m，压缩雷诺数ℵ b，旋转雷诺数ℵ a、磁场分量ℵ cℵ 通过数值结果和图形辅助讨论了流体作用在圆盘上的压力F pres和力矩ϱ′0，\1009；1。结果表明，磁雷诺数使磁场分布增加，流场切向速度降低，流体温度也随着磁雷诺数的增加而降低。磁场的方位角分量和轴向分量随着MFD粘度的增加而具有相反的行为。

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来源期刊

Advanced Composites Letters 工程技术-材料科学：复合

自引率

0.00%

发文量

审稿时长

4.2 months

期刊介绍： Advanced Composites Letters is a peer reviewed, open access journal publishing research which focuses on the field of science and engineering of advanced composite materials or structures.