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基于微观尺度代表性体积单元法对磁流变弹性体在剪切变形下宏观力学行为的研究

Investigation of Macroscopic Mechanical Behavior of Magnetorheological Elastomers under Shear Deformation Using Microscale Representative Volume Element Approach.

作者信息

Abdollahi Ilda, Sedaghati Ramin

机构信息

Department of Mechanical, Industrial and Aerospace Engineering, Concordia University, Montreal, QC H3G 1M8, Canada.

出版信息

Polymers (Basel). 2024 May 11;16(10):1374. doi: 10.3390/polym16101374.

DOI:10.3390/polym16101374
PMID:38794567
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11124946/
Abstract

Magnetorheological elastomers (MREs) are a class of smart materials with rubber-like qualities, demonstrating revertible magnetic field-dependent viscoelastic properties, which makes them an ideal candidate for development of the next generation of adaptive vibration absorbers. This research study aims at the development of a finite element model using microscale representative volume element (RVE) approach to predict the field-dependent shear behavior of MREs. MREs with different elastomeric matrices, including silicone rubber Ecoflex 30 and Ecoflex 50, and carbonyl iron particles (CIPs) have been considered as magnetic particles. The stress-strain characteristic of the pure silicon rubbers was evaluated experimentally to formulate the nonlinear Ogden strain energy function to describe hyper-elastic behavior of the rubbery matrix. The obtained mechanical and magnetic properties of the matrix and inclusions were integrated into COMSOL Multiphysics to develop the RVE for the MREs, in 2D and 3D configurations, with CIP volume fraction varying from 5% to 40%. Periodic boundary condition (PBC) was imposed on the RVE boundaries, while undergoing shear deformation subjected to magnetic flux densities of 0-0.4 T. Comparing the results from 2D and 3D modeling of isotropic MRE-RVE with the experimental results from the literature suggests that the 3D MRE-RVE can be effectively used to accurately predict the influence of varying factors including matrix type, volume fraction of magnetic particles, and applied magnetic field on the mechanical behavior of MREs.

摘要

磁流变弹性体(MREs)是一类具有橡胶特性的智能材料,表现出与磁场相关的可逆粘弹性,这使其成为开发下一代自适应减震器的理想候选材料。本研究旨在采用微观代表性体积单元(RVE)方法开发有限元模型,以预测MREs与磁场相关的剪切行为。已考虑将具有不同弹性体基体的MREs,包括硅橡胶Ecoflex 30和Ecoflex 50,以及羰基铁颗粒(CIPs)作为磁性颗粒。通过实验评估了纯硅橡胶的应力-应变特性,以建立非线性奥格登应变能函数来描述橡胶基体的超弹性行为。将获得的基体和夹杂的力学及磁性能整合到COMSOL Multiphysics中,以开发二维和三维构型的MREs的RVE,CIP体积分数在5%至40%之间变化。在RVE边界施加周期性边界条件(PBC),同时使其在0 - 0.4 T的磁通密度下承受剪切变形。将各向同性MRE-RVE的二维和三维建模结果与文献中的实验结果进行比较表明,三维MRE-RVE可有效用于准确预测包括基体类型、磁性颗粒体积分数和外加磁场等不同因素对MREs力学行为的影响。

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