利用层流条件下的 CNT 纳米流体评估移动冷却应用中跨后向台阶的传热和流体动力学

Q2 Mathematics CFD Letters Pub Date : 2024-06-02 DOI:10.37934/cfdl.16.10.140153
Afrah Turki Awad, Abdulelah Hameed Yaseen, Adnan M. Hussein
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引用次数: 0

摘要

在各种工程应用中,移动冷却系统的散热效果在很大程度上受到后向台阶的影响。后向台阶的设计和流体动力学对于最大限度地减少表皮摩擦和改善被动传热至关重要,这凸显了后向台阶在优化移动设备冷却解决方案方面的重要意义。在本文中,我们将对用于移动设备冷却的后向台阶传热和流体流动的先进数值模型进行验证。这项研究的目的是探索流体分离这一增强被动传热和减少表面摩擦的方法。ANSYS/FLUENT 软件用于求解充满纯水的水平管道中的后向台阶。碳纳米管(CNT)以 0.2%、0.65% 和 1% 的不同体积分数分散到基础流体中。这项研究的重点是雷诺数为 200 到 900 的层流条件。为了缩短计算时间并确保数值模拟的准确性和可靠性,进行了网格独立性研究。研究结果表明,随着雷诺数和纳米粒子体积分数的增加,平均努塞尔特数和传热系数大幅上升。具体而言,纳米流体(CNT/水)的平均努塞尔特数和传热系数在体积分数为 1%时最高。此外,研究还表明,随着雷诺数的增加和纳米粒子体积分数的降低,皮肤摩擦因数也在降低。纳米粒子浓度的增加会导致粘度增加,促进团聚,通过诱发湍流改变流动行为,并增强热传递。这些因素共同导致流体流动阻力增大和流线模式紊乱,从而增加了表皮摩擦力。
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Evaluation of Heat Transfer and Fluid Dynamics across a Backward Facing Step for Mobile Cooling Applications Utilizing CNT Nanofluid in Laminar Conditions
In a variety of engineering applications, the efficacy of heat dissipation in mobile cooling systems is greatly influenced by the Backward Facing Step. Its significance in optimizing cooling solutions for mobile devices is highlighted by the fact that its design and fluid dynamics are crucial in minimizing skin friction and improving passive heat transfer. In this paper, we present a verification of an advanced numerical model for heat transfer and fluid flow through a Backward Facing Step, used in mobile cooling. The objective of this study is to explore fluid separation, a method enhancing passive heat transfer and reducing skin friction. ANSYS/FLUENT software has been used to solve the backward facing step in a horizontal duct filled with pure water. Carbon nanotube (CNT) dispresed into the base fluid at different volume fractions of 0.2%, 0.65%, and 1%. This study focused on laminar flow conditions ranging from Reynolds numbers 200 to 900. In order to reduce the computation time and ensuring the accuracy and reliability of numerical simulations, a grid independence study has been conducted. The findings revealed a substantial rise in the average Nusselt number and heat transfer coefficient with increased Reynolds number and volume fraction of nanoparticles. Specifically, the nanofluid (CNT/water) exhibited the highest average Nusselt number and heat transfer coefficient with volume fractions 1%. Furthermore, the research showed a decrease in the skin friction factor as both Reynolds number increased and nanoparticles’ volume fraction decreased. The increments of nanoparticles' concentrations lead to increase viscosity, promotes agglomeration, alters flow behaviour by inducing turbulence, and enhances heat transfer. These factors collectively contribute to higher skin friction due to increased resistance to fluid flow and disrupted streamline patterns
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来源期刊
CFD Letters
CFD Letters Chemical Engineering-Fluid Flow and Transfer Processes
CiteScore
3.40
自引率
0.00%
发文量
76
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