通过氧化铜纳米流体提高封闭系统效率:研究热物理性质和传热性能

Nadhum H. Safir, Zuradzman Mohamad Razlan, Shahriman Abu Bakar, Muhammmad Hussein Akbar Ali, Mohd Zulkifly Abdullah, Girrimuniswar Ramasamy, Rodhiyathul Ahyaa Akbar Ali
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引用次数: 0

摘要

工作流体在封闭系统中起着确保高效性能的关键作用,特别是在用于加热、冷却或发电的系统中,传热系数至关重要。本研究深入探讨了氧化铜(CuO)纳米流体作为封闭系统中替代工作流体的热力学特性和稳定性。该研究调查了 CuO 纳米粒子的胶体悬浮液,旨在提高传热效率。尺寸为 40nm 和 80nm 的氧化铜纳米颗粒被分散在水、乙二醇和油等不含表面活性剂的基础流体中。研究分为静态和动态两个阶段,考察了纳米流体的主要特性,包括粘度、导热性、比热和传热速率。通过 KD2 Pro(热导率)、流变仪(粘度)和小型热交换器(传热速率)等方法,评估了体积浓度、温度和纳米粒子大小对纳米流体性能的影响。沉积分析采用了定量(标准偏差计算)和定性(沉积物捕获方法)两种方法。研究结果表明,体积浓度为 0.467% 的 40nm CuO 纳米流体的传热速率高达 9.08 kJ/s,这表明它具有优化系统效率的潜力,尤其是在加热、冷却和发电应用中。
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Enhancing Closed System Efficiency through CuO Nanofluids: Investigating Thermophysical Properties and Heat Transfer Performance
Working fluids play a crucial role in closed systems to ensure efficient performance, particularly in systems for heating, cooling, or power generation, where the heat transfer coefficient is pivotal. This study delves into the thermodynamic properties and stability of copper oxide (CuO) nanofluids as alternative working fluids in closed systems. Investigating colloidal suspensions of CuO nanoparticles, the research aims to enhance heat transfer efficiency. CuO nanoparticles, sized at 40nm and 80nm, were dispersed in base fluids like water, ethylene glycol, and oil sans surfactants. The study, divided into static and dynamic phases, examines key nanofluid properties including viscosity, thermal conductivity, specific heat, and heat transfer rate. Through methodologies such as KD2 Pro for thermal conductivity, rheometer for viscosity, and small heat exchanger for heat transfer rate analysis, the effects of volume concentration, temperature, and nanoparticle size on nanofluid performance were evaluated. Sedimentation analysis employed both quantitative (standard deviation calculations) and qualitative (sediment capture methods) approaches. The findings highlight the superior heat transfer rate of 40nm CuO nanofluid at 0.467% volume concentration which is 9.08 kJ/s, suggesting its potential to optimize system efficiency, particularly in heating, cooling, and power generation applications.
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来源期刊
Journal of Advanced Research in Fluid Mechanics and Thermal Sciences
Journal of Advanced Research in Fluid Mechanics and Thermal Sciences Chemical Engineering-Fluid Flow and Transfer Processes
CiteScore
2.40
自引率
0.00%
发文量
176
期刊介绍: This journal welcomes high-quality original contributions on experimental, computational, and physical aspects of fluid mechanics and thermal sciences relevant to engineering or the environment, multiphase and microscale flows, microscale electronic and mechanical systems; medical and biological systems; and thermal and flow control in both the internal and external environment.
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