利用BUONGIORNO拖曳相模型对CPU散热器中纳米流体自然对流的数值研究

IF 0.5 Q4 ENGINEERING, MULTIDISCIPLINARY Journal of the Serbian Society for Computational Mechanics Pub Date : 2022-12-01 DOI:10.24874/jsscm.2022.16.02.02
Yamina Anouar, Abderrahim Mokhefi
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引用次数: 0

摘要

本文采用有限元方法对电子散热器的冷却能力进行了数值研究。该散热器适用于微型计算机CPU的冷却应用。它处理的是一个带有矩形翅片的平行六面体块,填充有纳米流体,由四根圆柱形管道穿过,冷却气体在其中流动并消散处理器产生的热量。事实上,冷却通过三种方式进行:第一种将热量从处理器排出到气体中,第二种将热量转移到纳米流体中,最后一种通过横向布置在块上的散热片从环境空气中冷却。这项工作计划有助于研究在均匀磁场存在下散热器中纳米流体的行为,以提高操作和冷却性能。一些控制参数对纳米流体的流体动力学、热学和质量行为的影响已经得到强调,即:瑞利数(103‰Ra‰105)、哈特曼数(0‰Ha‰100)、磁场倾角(0‰Isla³90°)和纳米颗粒直径(1 nm‰dp‰10 nm)。另一方面,本研究提出了一种新的翅片设计,可以提高与环境介质的热交换率。所研究的现象由Buongiorno提出的两相纳米流体模型方程控制,该方程描述了以下平衡:质量、动量、能量和纳米颗粒。用有限元方法求解了具有初始边界条件的偏微分方程组。在进行了网格独立性检查并与以前的论文进行了验证后,给出了研究结果。他们表明,磁场的应用显著降低了热交换的速率。然而,增加该场的倾角会促进对流传热。此外,与标准配置相比,锯齿形翅片的使用将振幅为0.05的冷却率提高了约4%。
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NUMERICAL INVESTIGATION OF THE NANOFLUID NATURAL CONVECTION FLOW IN A CPU HEAT SINK USING BUONGIORNO TOW-PHASE MODEL
In this paper, a numerical investigation using the finite element method on the cooling capacity of an electronic heat sink has been presented. This heat sink is intended for cooling applications of micro-computer CPUs. It deals with a parallelepipedal block with rectangular fins, filled with a nanofluid and crossed by four cylindrical pipes in which a cooling gas flows and dissipates the heat generated by the processor. Indeed, the cooling occurs by three transfers: the first one evacuates the heat from the processor towards the gas, the second one transfers this heat towards the nanofluid and the last one is cooled from the ambient air by means of the fins laterally arranged on the block. From this work, it has been planned to contribute to the study of the behavior of a nanofluid in the heat sink in the presence of a uniform magnetic field in order to enhance the operating and cooling performances. The effects of some control parameters have been highlighted on the hydrodynamic, thermal, and mass behavior of the nanofluid, namely: the Rayleigh number (103 ≤ Ra ≤ 105), the Hartmann number (0 ≤ Ha ≤ 100), the angle of inclination of the magnetic field (0 ≤ γ ≤ 90°) and the nanoparticles diameter (1 nm ≤ dp ≤ 10 nm). On the other hand, a new fin design has been proposed in this study allowing the enhancement of the heat exchange rate with ambient medium. The studied phenomenon is governed by the equations of the two-phase nanofluid model proposed by Buongiorno and which describe the following balances: mass, momentum, energy and nanoparticles. The system of partial differential equations with initial-boundary conditions has been solved by the finite element method. After performing a mesh independence check and validating with previous papers, the results of the investigation were presented. They showed that the application of a magnetic field significantly reduces the rate of heat exchange. However, increasing the angle of inclination of this field promotes convective heat transfer. Moreover, the use of zigzag fins improves the cooling rate by about 4% for amplitude of 0.05 compared to the standard configuration.
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