A Novel Physical Model for Describing Thermal Conductivity of Composite Materials: Application to the Measured Values in a Two-Phase WC-Co System

Shiyi Wen, Yong Du, Jing Tan, Yuling Liu, P. Zhou, Jianzhan Long, G. Kaptay
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Abstract

The method for describing the thermal conductivity of composite materials as a function of the grain size, temperature and composition remains undeveloped until now. Cemented carbide is one typical composite material. In order to remedy the current situation of understanding and facilitate designing cemented carbides with a desirable thermal conductivity, experiment and a newly developed physical model for assessing the thermal conductivity for WC-Co system were carried out in this work. The present physical model can produce results in good agreements with the 109 values of thermal conductivities for WC-Co system measured in the present work as well as from the literature. The good performance of the presently developed physical model indicates that it provides a reasonable way to evaluate the thermal conductivity for composite materials, which is also promising to be extended to multi-phase composite materials. By using this model, the thermal conductivity for pure WC was extrapolated for the first time, which lays a good foundation for studying the thermal conductivity of WC-based materials. Meanwhile, the thermal resistivities dependent on the temperature for the interfaces of WC/Co and WC/WC were also obtained by the present model for the first time. Moreover, several industrial WC-Co alloys as function of grain size and temperature were predicted by the physical model, which considerably contributes to designing cemented carbides with desirable thermal conductivities.
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一种描述复合材料导热系数的新物理模型:在两相WC-Co体系测量值中的应用
描述复合材料导热系数随晶粒尺寸、温度和成分变化的方法至今尚未发展起来。硬质合金是典型的复合材料。为了改善人们对WC-Co体系导热系数的认识现状,并为设计具有理想导热系数的硬质合金提供了方便,本文进行了实验研究,并建立了一种新的评估WC-Co体系导热系数的物理模型。目前的物理模型可以产生的结果与本工作和文献中测量的WC-Co体系的109个导热系数值很好地吻合。目前所建立的物理模型的良好性能表明,它为评价复合材料的导热性提供了一种合理的方法,并有望推广到多相复合材料中。利用该模型首次外推了纯WC的导热系数,为研究WC基材料的导热系数奠定了良好的基础。同时,本文还首次得到了WC/Co和WC/WC界面随温度变化的热阻系数。此外,通过物理模型预测了几种工业WC-Co合金的晶粒尺寸和温度的函数,这对设计具有理想导热性的硬质合金有很大的帮助。
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