Micromechanical analysis for effective elastic moduli and thermal expansion coefficient of composite materials containing ellipsoidal fillers oriented randomly

IF 5.3 Q2 MATERIALS SCIENCE, COMPOSITES
Hiroyuki Ono
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Abstract

In this study, we examine to derive the solutions of effective elastic moduli and thermal expansion coefficient for composite materials containing ellipsoidal fillers oriented randomly in the material using homogenization theories, which are the self-consistent method and the Mori–Tanaka method. This analysis is carried out by micromechanics combining Eshelby’s equivalent inclusion method for each theory. The solutions for effective elastic moduli and thermal expansion coefficient obtained on each theory are expressed by common coefficients composed of both the physical properties of the constituents of the composite material and geometrical factors depending upon the shape of the fillers. Moreover, these solutions enable us to calculate effective elastic moduli and thermal expansion coefficient for composite materials that contain randomly oriented fillers of various shapes and physical properties. By taking the limit of eliminating the existence of the matrix for these solutions, we can derive effective physical properties of polycrystalline materials. Using the obtained solutions, we investigate the effects of the shape of the fillers on the effective elastic moduli and thermal expansion coefficient. As a result, we confirm that these effective properties fall within the lower and upper bounds, and find that a characteristic result appears when the shape of the fillers is flake or oblate. Through comparisons between the analytical and experimental results, we confirm the practical usability of the solutions obtained in this analysis. Furthermore, we determine originally the shape factor for the filler and can show that this factor has the potential to provide guidelines for the optimal design of filler shape to improve the effective elastic properties of materials.

含有随机定向椭圆形填料的复合材料有效弹性模量和热膨胀系数的微观力学分析
在本研究中,我们利用自洽法和 Mori-Tanaka 法这两种均质化理论,对材料中含有随机取向的椭圆形填料的复合材料的有效弹性模量和热膨胀系数的求解进行了研究。这种分析是通过微观力学结合 Eshelby 的等效包含法对每种理论进行的。根据每种理论得到的有效弹性模量和热膨胀系数的解决方案都由复合材料成分的物理性质和取决于填料形状的几何因素组成的共同系数来表示。此外,这些解决方案使我们能够计算含有各种形状和物理性质的随机取向填料的复合材料的有效弹性模量和热膨胀系数。通过消除这些解法中基体存在的极限,我们可以得出多晶材料的有效物理性质。利用得到的解,我们研究了填料形状对有效弹性模量和热膨胀系数的影响。结果,我们证实这些有效物理性质都在下限和上限范围内,并发现当填料的形状为片状或扁圆形时,会出现一个特征性结果。通过对比分析结果和实验结果,我们确认了本分析中获得的解决方案的实用性。此外,我们还初步确定了填料的形状系数,并证明该系数有可能为填料形状的优化设计提供指导,从而改善材料的有效弹性性能。
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
Composites Part C Open Access
Composites Part C Open Access Engineering-Mechanical Engineering
CiteScore
8.60
自引率
2.40%
发文量
96
审稿时长
55 days
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