Numerical Analysis of Thermal Convection in a CPU Chassis

建模与仿真(英文) Pub Date : 2021-01-01 DOI:10.4236/OJMSI.2021.91003

M. Bangalee, M. M. Rahman, M. Ferdows, M. S. Islam

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Abstract

Flow distribution and the effects of different boundary conditions are achieved for a steady-state conjugate (Conduction & Convection) heat transfer process. A plate fin heat sink with horizontal fin orientation along with a computer chassis is numerically investigated and simulated using software ANSYS CFX. Fin orientation of a heat sink changes the direction of fluid flow inside the chassis. For predicting turbulence of the flow inside the domain, a two-equation based k-e turbulence model is chosen. The Reynolds number based on inflow velocity and geometry is found 4.2 × 103 that indicates that the flow is turbulent inside the chassis. To get proper thermal cooling, the optimum velocity ratio of inlet/outlet, dimension of inlet/outlet and different positions of outlet on the back sidewall of the chassis are predicted. Aspect velocity ratio between the inlet airflow and the outlet airflow has an effect on the steadiness of the flow. Mass flow rate depends on the dimension of the inlet/outlet. The horizontal fin orientation with 1:1.6 inlet-outlet airflow velocity ratio gives better thermal performance when outlet is located at the top corner of the chassis, near to the inner sidewall. Flow distribution and heat transfer characteristics are also analyzed to obtain the final model.

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CPU机箱内热对流数值分析

研究了稳态共轭(传导和对流)传热过程的流动分布和不同边界条件的影响。利用ANSYS CFX软件对一种水平翅片方向的平板翅片散热器进行了数值模拟研究。散热器翅片的方向改变了机箱内部流体的流动方向。为了预测区域内流动的湍流，选择了基于两方程的k-e湍流模型。基于来流速度和几何形状的雷诺数为4.2 × 103，表明底盘内部的流动是湍流的。为了获得合适的热冷却效果，对进风口的最佳速度比、进风口的尺寸以及出风口在底盘后侧壁上的不同位置进行了预测。进口气流与出口气流的展弦速比对气流的稳定性有影响。质量流量取决于进口/出口的尺寸。当出口位于底盘顶角，靠近内侧壁时，水平翅片的进、出口流速比为1:6 .6，散热性能较好。并对流动分布和换热特性进行了分析，得到了最终模型。

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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建模与仿真(英文)

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