含富勒烯纳米流体粘度模拟研究

K. Khanchych, V. Zhelezny, O. Khliyeva, Ivan Diachenko, Y. Semenyuk, Yana Hlek
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摘要

本文介绍了含富勒烯纳米流体(NFs)在宽温度范围内粘度的模拟结果。提出了两种不同的预测NFs粘度的模型。第一个是基于所研究的NFs与其基流体的热力学相似性。结果表明,富勒烯${\ mathm C}_{60}$在邻二甲苯中的溶液和富勒烯${\ mathm C}_{60}$在四氢萘(1,2,3,4 -四氢萘)中的溶液分别与邻二甲苯和四氢萘的热力学相似。为了计算含富勒烯纳米颗粒的粘度,采用了基于粘性流动活化理论的方程。分析了基液活化能和相应的NFs的温度依赖性。结果表明,基液活化能的温度依赖性和相应的nf几乎是等距线。这使得利用得到的基础流体活化能的温度依赖性和NF粘度的有限信息(某一浓度的一个实验值)来预测NF的粘度成为可能。用于预测NFs粘度的第二个模型是基于可以从NFs密度数据中获得的自由体积信息。在该模型中,建议使用作者的扩展标度模型计算的临界振幅的反量作为所研究解的自由体积。
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On Modelling the Viscosity of Fullerene-Containing Nanofluids
The results of modeling the viscosity of fullerene-containing nanofluids (NFs) in a wide temperature range are presented. Two different models for predicting the viscosity of NFs are proposed. The first one is based on the thermodynamic similarity of the studied NFs with their base fluids. It was established that solutions of fullerene ${\mathrm C}_{60}$ in o-xylene as well as solutions of fullerene ${\mathrm C}_{60}$ in tetralin (1,2,3,4 - tetrahydronaphthalene) are thermodynamically similar with o-xylene and tetralin, respectively. To calculate the viscosity of fullerene-containing NFs, the equations based on the activation theory of viscous flow were used. An analysis of the temperature dependence of the activation energy of the base fluids and corresponding NFs was performed. It was found that the temperature dependences of the activation energy of the base fluids and corresponding NFs are practically equidistant lines. That makes possible to predict the viscosity of the NFs using the obtained temperature dependences of the activation energy of the base fluids and limited information on the NF’s viscosity (one experimental value for a certain concentration). The second model for predicting the viscosity of the NFs is based on the information on a free volume that can be obtained from data on the density of the NFs. In this model, it is proposed to use as the free volume of the studied solutions the inverse quantities to their critical amplitudes calculated by the author’s model of the extended scaling.
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