Review and Evaluation of Effective Thermal Conductivity Model for Solid-solid Binary Composite

被引：0

作者：

Qian L. ^{[1
]}

Yu H. ^{[1
]}

Sun Y. ^{[1
]}

Deng J. ^{[1
]}

Wu D. ^{[1
]}

Li Z. ^{[1
]}

Huang T. ^{[1
]}

机构：

[1] Science and Technology on Reactor System Design Technology Laboratory, Nuclear Power Institute of China, Chengdu

来源：

Yuanzineng Kexue Jishu/Atomic Energy Science and Technology | 2020年 / 54卷 / 03期

关键词：

Effective thermal conductivity; Model evaluation; Solid-solid binary composite;

D O I：

10.7538/yzk.2019.youxian.0310

中图分类号：

学科分类号：

摘要：

Effective thermal conductivity (ETC) is an important characteristic parameter which represents the heat transfer ability of the composite and is a function of the thermal conductivity of the continuous phase kc, the conductivity of the dispersed phase kd, the volume fraction of dispersed phaseφ, the shape and arrangement of dispersed phase, etc. Therefore, the prediction of ETC is a very complicated process. Even with the great number of models available, the uncertainty in predicting the ETC of the composite system can still be very high. Hence the screen of ETC models with better predicting results should be done according to different applications. First, the review of widely applicable ETC prediction methods for solid-solid binary composite system with granular dispersed phase was presented, including existing empirical or theoretical models, the minimum thermal resistance theory, the thermal resistance network method, the numerical method, the asymptotic homogenization method and the percolation method. Then, based on the experimental and numerical ETC results of solid-solid binary composite system, the comprehensive evaluation of ETC empirical or theoretical models was shown. Finally, the ETC models with better predicting results in different application realms were proposed. © 2020, Editorial Board of Atomic Energy Science and Technology. All right reserved.

引用

页码：409 / 420

页数：11

共 45 条

[21]

Tsao G.T.N., Thermal conductivity of two-phase materials, Industrial and Engineering Chemistry, 53, 5, pp. 395-397, (1961)

[22]

Singh K.J., Ramvir S., Chaudhary D.R., Heat conduction and a porosity correction term for spherical and cubic particles in a simple cubic packing, Journal of Physics D: Applied Physics, 31, 14, pp. 1681-1687, (1998)

[23]

Bhattacharya A., Calmidi V.V., Mahajan R.L., Thermophysical properties of high porosity metal foams, International Journal of Heat and Mass Transfer, 45, 5, pp. 1017-1031, (2002)

[24]

Chen Z., Qian J., Ye Y., Predicting theory of effective thermal conductivity of complex material, Journal of China University of Science and Technology, 22, 4, pp. 417-423, (1992)

[25]

Liang J., Zhu B., Prediction of thermal conductivity of silicon rubber/Al<sub>2</sub>O<sub>3</sub> compsite, Special Purpos Rubber Products, 35, 1, pp. 75-77, (2014)

[26]

Song S., Liao Q., Shen W., Effective thermal conductivity of composites filled with different shape particles, Journal of Chongqing University, 34, 6, pp. 87-91, (2011)

[27]

Li M., Zhu J., Yin Z., Analysis of effective thermal conductivity of particle dispersive composites, Journal of Functional Materials, 32, 4, pp. 397-398, (2001)

[28]

Russell H.W., Principles of heat flow in porous insulators, Journal of the American Ceramic Society, 18, 1-12, pp. 1-5, (1935)

[29]

Topper L., Industrial design data-Analysis of porous thermal insulating materials, Industrial and Engineering Chemistry, 47, 7, pp. 1377-1379, (1955)

[30]

Zhang H., Ge X., Ye H., Resistance network for predicting the thermal conductivity of composite materials, Journal of Functional Materials, 36, 5, pp. 757-759, (2005)

← 1 2 3 4 5 →