评估纳米层和颗粒大小对流体通过旋转盘的影响

IF 2.8 Q2 THERMODYNAMICS Heat Transfer Pub Date : 2024-04-11 DOI:10.1002/htj.23059
Akinbowale T. Akinshilo
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引用次数: 0

摘要

本文研究了纳米层对旋转系统中流体传输和热传递的影响,纳米层显示了纳米粒子和纯液体之间的关系。纳米层显示了纳米粒子与基液之间的关系,表明其导热性高于纳米粒子,而导热性低于基液。此外,还考虑了较大的纳米颗粒尺寸和体积对液体热分布的影响。纳米粒子提高了流体的热传导率,目的是在流体传输过程中保护热传导,从而节约能源。流体力学采用高阶耦合非线性模型系统,借助同调扰动法进行求解。分析结果表明,纳米层膨胀对热分布的影响增加了边界层厚度。此外,当纳米粒子的尺寸在 10 纳米到 40 纳米之间变化时,圆盘中心的传热增加了 17.02%。颗粒尺寸的增加表明,随着纳米颗粒所在纳米层尺寸的增加,温度也随之升高。所获得的结果与文献比较,结果一致。这项研究可用于冷却剂和润滑剂加工以及其他实际应用领域。
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Evaluation of nanolayer and particle size on fluid transport through rotating disks

In this paper, the impact of nanolayer which shows the relationship between the nanoparticle and pure fluid is investigated on the fluid transport and thermal transfer through a rotating system. The nanolayer shows the relationship between the nanoparticle and base liquid, signifying a higher thermal conductivity than the nanoparticle and lower conductivity than the base fluid. Also, the effect of larger nanoparticle size and volume on fluid thermal distribution is considered. The nanoparticle raises the fluid thermal conductivity with the aim of conserving thermal transfer during fluid transport, consequently saving energy. The mechanics of the fluid is developed using a higher-order coupled system of nonlinear models, solved with the aid of the Homotopy perturbation method. Obtained results from the analysis show the impact of nanolayer expansion on thermal distribution increases boundary layer thickness. Also, the size of the nanoparticle when varied from 10 to 40 nm shows a heat transfer increase of 17.02% at the center of the disk. Particle size increase indicates temperature rise as nanolayer size encompassing the nanoparticle increases. Obtained results when compared against literature give good agreement. The study finds useful applications in coolant and lubricant processing amongst other practical applications.

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来源期刊
Heat Transfer
Heat Transfer THERMODYNAMICS-
CiteScore
6.30
自引率
19.40%
发文量
342
期刊最新文献
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