Analysis of heat transfer of ellipsoidal particles mixed composite with bounded domains

IF 2.3 3区 工程技术 Q2 MECHANICS
Guanyi Zhang, Yifan Zhang, Liangliang Zhang, Yang Gao
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引用次数: 0

Abstract

This paper employs the inclusion-based boundary element method (iBEM) to delve into heat transfer phenomena in composites. Initially, we integrate the heat flow function and ellipsoidal integral into a bounded domain containing multiple ellipsoidal inhomogeneities. The eigen-temperature gradient is utilized to simulate the thermal mismatch between inhomogeneities and the matrix. Subsequently, the temperature field is computed considering boundary heat flux and temperature conditions, eigen-temperature gradient, and virtual heat source acting on inhomogeneities. The eigen-temperature gradient and virtual heat source are then solved using the equivalent heat flow conditions to obtain the steady-state heat conduction results within the bounded domain. Through comprehensive numerical examples, we analyze the temperature distribution within composite and scrutinize the impact of particle shapes, orientations, volume fractions, and thermal conductivity ratios on the effective thermal conductivity of composite. Furthermore, we explore the distinctive properties of functional gradient material. Additionally, a comparison between iBEM and the finite element method is conducted. The findings reveal a progressive enhancement in the thermal conductivity of composite as the particle shape transitions from spherical to fibrous.

Abstract Image

有界域椭球颗粒混合复合材料的传热分析
本文采用基于包容的边界元法(iBEM)来研究复合材料中的传热现象。首先,我们将热流函数和椭圆积分整合到包含多个椭圆非均质体的有界域中。利用特征温度梯度来模拟非均质和基体之间的热失配。随后,考虑边界热通量和温度条件、特征温度梯度和作用于非均质体的虚拟热源,计算温度场。然后利用等效热流条件对特征温度梯度和虚拟热源进行求解,从而得到有界域内的稳态热传导结果。通过综合数值实例,我们分析了复合材料内部的温度分布,并仔细研究了颗粒形状、取向、体积分数和导热比对复合材料有效导热率的影响。此外,我们还探索了功能梯度材料的独特特性。此外,我们还对 iBEM 和有限元法进行了比较。研究结果表明,当颗粒形状从球形过渡到纤维状时,复合材料的热导率会逐渐增强。
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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来源期刊
Acta Mechanica
Acta Mechanica 物理-力学
CiteScore
4.30
自引率
14.80%
发文量
292
审稿时长
6.9 months
期刊介绍: Since 1965, the international journal Acta Mechanica has been among the leading journals in the field of theoretical and applied mechanics. In addition to the classical fields such as elasticity, plasticity, vibrations, rigid body dynamics, hydrodynamics, and gasdynamics, it also gives special attention to recently developed areas such as non-Newtonian fluid dynamics, micro/nano mechanics, smart materials and structures, and issues at the interface of mechanics and materials. The journal further publishes papers in such related fields as rheology, thermodynamics, and electromagnetic interactions with fluids and solids. In addition, articles in applied mathematics dealing with significant mechanics problems are also welcome.
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