INVESTIGATION ON THE EFFECT OF OSCILLATING MAGNETIC FIELDS ON FLUID FLOW AND FORCED-CONVECTION HEAT TRANSFER AROUND A SPHERE

IF 1.5 4区 工程技术 Q3 ENGINEERING, MECHANICAL
Zeinab Abbasi, A. Dehkordi
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Abstract

In this article, the heat transfer of magnetic nanofluids over a sphere has been considered in the presence of an external oscillating uniform magnetic field for a wide range of Reynolds number values (Re). This study incorporates the effect of magnetic permeability and purposes the optimal operating condition for the first time. The significant difference between the magnetic property of the nanofluid and the heated sphere makes a non-uniform magnetic field around the sphere resulting in a significant alteration in the distribution of velocity and temperature around sphere. The variations of average Nusselt number (Nuavg) and drag coefficient (Cd) have been studied to demonstrate the influence of magnetic field frequency and intensity, Re, and the relative magnetic permeability of the sphere. It has been found that the magnetic field causes the vortices to appear or grow behind the sphere. This leads to fluid separation even for low Re values in the presence of magnetic field. Local Nu value is minimum at the separation point. This point moves towards the front of sphere as the magnetic field intensity increases. These vortices lead to boundary layer distortion, thereby increasing heat-transfer rate and drag force. In addition, the obtained results clearly indicate that there is an optimal frequency at which Nuavg and Cd can be maximized. The dimensionless optimal frequency (Ωτ) is about 0.6 regardless of Re value or magnetic field intensity. Moreover, the influence of the applied magnetic field is more noticeable for low Re values and/or frequencies near the optimum value. For instance, Nuavg and Cd increase by 150% and 50%, respectively, for Re value of 30 while they are three times smaller for Re value of 200. Increase in the magnetic permeability of sphere enhances the Nuavg up to 170% (at Re = 50) close to the optimal frequency, whereas its effect is almost negligible for frequencies far away from the optimal one. Furthermore, the obtained results clearly demonstrate that the heat-transfer increase is much larger than the penalty due to the drag force increase for frequencies close to the optimal value.
振荡磁场对球体周围流体流动和强制对流传热影响的研究
在这篇文章中,磁性纳米流体在一个广泛的雷诺数(Re)范围内的外部振荡均匀磁场的存在下,在一个球体上的传热被考虑。本研究首次考虑了磁导率的影响,并以最佳操作条件为目的。由于纳米流体的磁性与加热后的球体磁性的显著差异,使得球体周围的磁场不均匀,从而导致球体周围的速度和温度分布发生显著变化。研究了平均努塞尔数(Nuavg)和阻力系数(Cd)的变化,以证明磁场频率和强度、Re和球的相对磁导率的影响。已经发现,磁场导致漩涡在球体后面出现或生长。这导致即使在磁场存在的低Re值下流体也会分离。局部Nu值在分离点处最小。随着磁场强度的增大,这一点向球体的前方移动。这些涡旋导致边界层变形,从而增加传热速率和阻力。此外,得到的结果清楚地表明,存在一个最优频率,Nuavg和Cd可以最大化。无因次优化频率(Ωτ)与Re值或磁场强度无关,约为0.6。此外,对于低Re值和/或接近最佳值的频率,外加磁场的影响更为明显。例如,当Re值为30时,Nuavg和Cd分别增加150%和50%,而当Re值为200时,它们会减少3倍。球体磁导率的增加可使Nuavg在接近最佳频率时达到170% (Re = 50),而在远离最佳频率时,其影响几乎可以忽略不计。此外,得到的结果清楚地表明,当频率接近最优值时,传热的增加远大于阻力的增加所造成的损失。
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
Journal of Enhanced Heat Transfer
Journal of Enhanced Heat Transfer 工程技术-工程:机械
CiteScore
3.60
自引率
8.70%
发文量
51
审稿时长
12 months
期刊介绍: The Journal of Enhanced Heat Transfer will consider a wide range of scholarly papers related to the subject of "enhanced heat and mass transfer" in natural and forced convection of liquids and gases, boiling, condensation, radiative heat transfer. Areas of interest include: ■Specially configured surface geometries, electric or magnetic fields, and fluid additives - all aimed at enhancing heat transfer rates. Papers may include theoretical modeling, experimental techniques, experimental data, and/or application of enhanced heat transfer technology. ■The general topic of "high performance" heat transfer concepts or systems is also encouraged.
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