Viscosity of nanofluids-A Review

Q3 Engineering
A. Patra, M. K. Nayak, A. Misra
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引用次数: 10

Abstract

In the present study a comprehensive review on rheological characteristics of nanofluids for their advanced heat transfer applications has been conducted and presented. The present article critically summarizes the recent research developments regarding the theoretical and experimental investigations about viscosity of different nanofluids. In addition, different reasonably attractive theoretical models and experimental correlations are explored and well discussed. Moreover, the current study analyzes several factors those strongly influencing viscosity of nanofluids include solid volume fraction, temperature, particle size, particle shape, different base fluids, surfactants addition, ultrasonication, nanoclustering and pH value. Important theoretical and experimental results from many researchers and predictions from a number of viscosity models are compared and discussed with appropriate justification. Most results reveal that the viscosity of nanofluid upsurges due to an increase in particle concentration while that belittles with diminishing temperature. Augmentation of nano-additives size leads to decreasing/increasing of nanofluid fluid viscosity. For the most nanofluids, Newtonian behavior is observed for low volume fractions, shear rates, concentrations and viscosity while non-Newtonian behavior is visualized for high volume fractions, shear rates, concentrations and viscosity. Nanofluids used carbon nanotubes are almost non-Newtonian in nature while nanofluids not involving carbon nanotubes are mostly Newtonian. Finally, the research challenges and needs in this important area of nanofluids are also highlighted.
纳米流体的粘度——综述
在本研究中,对纳米流体的流变特性及其先进的传热应用进行了全面的综述。本文对不同纳米流体粘度的理论和实验研究的最新进展进行了批判性总结。此外,还探索并充分讨论了不同的合理吸引人的理论模型和实验相关性。此外,目前的研究分析了强烈影响纳米流体粘度的几个因素,包括固体体积分数、温度、粒度、颗粒形状、不同的基础流体、表面活性剂的添加、超声处理、纳米团簇和pH值。对许多研究人员的重要理论和实验结果以及许多粘度模型的预测进行了比较和讨论,并提出了适当的理由。大多数结果表明,纳米流体的粘度由于颗粒浓度的增加而上升,而随着温度的降低而下降。纳米添加剂尺寸的增大导致纳米流体粘度的降低/增加。对于大多数纳米流体,在低体积分数、剪切率、浓度和粘度下观察到牛顿行为,而在高体积分数、剪速率、浓度和粘性下观察到非牛顿行为。使用碳纳米管的纳米流体在性质上几乎是非牛顿的,而不涉及碳纳米管的纳米流体大多是牛顿的。最后,还强调了纳米流体这一重要领域的研究挑战和需求。
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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