用两步均匀化方法评价压电分流纳米复合材料的阻尼特性

IF 3.1 Q2 MATERIALS SCIENCE, COMPOSITES
Sepehr Sedighi, Roohollah Sarfaraz, Pedram Safarpour
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引用次数: 0

摘要

摘要含压电颗粒的复合材料因其独特的机电转换特性而备受关注。这些优异的性能使其应用于各种领域,如结构的减振。动态系统的阻尼参数是至关重要的,特别是当它们发生共振现象时。由压电颗粒组成的多相聚合物基复合材料是最近被引入的创新材料系统,它将机械振动转化为电能,随后通过内部电路消散为热量。本研究旨在分析研究由聚合物基体、导电纳米颗粒和压电颗粒组成的分流三相复合材料的粘弹性特性。通过考虑组成材料的粘弹性特性,采用一步和两步均化方法计算了分流复合材料的有效粘弹性特性。研究了无量纲频率、导电纳米颗粒和压电颗粒的体积分数以及夹杂物形状等关键参数对相位角、存储模量和损耗模量等粘弹性特性的影响。这些参数对粘弹性特性有很大的影响,并且控制方程证明了感知行为是合理的。对结果的评估证实,通过仔细选择组成材料的体积分数和控制智能复合材料的激励频率,可以改善阻尼特性,同时避免额外的成本和制造过程中可能出现的不便。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Evaluation of damping characteristics of a hybrid piezo shunt nanocomposite by using two-steps homogenization approach
Abstract Composite materials containing piezoelectric particles have attracted remarkable attention because of their distinctive electromechanical conversion characteristics. These supreme properties lead to their applications in various fields, such as vibration damping of structures. The damping parameter of dynamic systems is crucial, especially when they undergo resonance phenomena. Multi-phase polymer matrix composites consisting of piezoelectric particles are innovative material systems that have been recently introduced to convert the mechanical vibrations into electrical energy, and subsequently dissipate into heat through an internal electrical circuit. The present study aims to analytically investigate the viscoelastic characteristics of a shunted three-phase composite composed of a polymer matrix, electrically conductive nanoparticles and piezoelectric particles. The effective viscoelastic characteristics of a shunted composite are calculated using one- and two-step homogenization procedures and by considering the viscoelastic characteristics of constituent materials. The influence of several key parameters, namely, the non-dimensional frequency, the volume fraction of electrically conductive nanoparticles and piezoelectric particles, and the shape of the inclusions, on viscoelastic characteristics, such as phase angles, the storage modulus and loss modulus, are examined. The viscoelastic characteristics are considerably affected by these parameters, and the perceived behavior is justified by the governing equations. The assessment of results confirms that the damping characteristics can be improved by careful selection of a volume fraction of constituent materials and control of the excitation frequency of the smart composite, while avoiding additional costs and likely inconveniences in the fabrication process.
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来源期刊
Functional Composites and Structures
Functional Composites and Structures Materials Science-Materials Science (miscellaneous)
CiteScore
4.80
自引率
10.70%
发文量
33
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