S. A. Kostrov, V. S. Razakov, G. V. Stepanov, E. A. Olenich, V. V. Gorodov, E. Yu. Kramarenko
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引用次数: 0
摘要
摘要 研究了带有球形和板形填料的磁活性弹性体的粘弹性能。研究人员制备了基于硅树脂弹性体和羰基铁微颗粒的四个系列样品。一系列样品的磁性填料浓度为 30% 至 60%,填料颗粒的形状(球形和板状)以及在聚合物基体中的分布(各向同性和各向异性)各不相同。获得的磁活性弹性体的磁流变特性已通过动态机械分析进行了检验。不同成分样品的存储模量值在 10-100 千帕之间。结果表明,各向异性材料比各向同性材料更坚硬,磁流变效应更高:在 1 T 的磁场中,各向异性样品的弹性模量随最大填料含量的增加而增加,超过一个数量级。在磁性填料浓度较低的情况下,使用板状铁可以使材料获得较高的磁响应;在填料浓度较高的情况下,基于球形颗粒的样品的弹性模量增幅更大。各向异性材料表现出更明显的佩恩效应。
Influence of Distribution Anisotropy and Particle Shape on Magnetorheological Properties of Magnetoactive Elastomers
Viscoelastic properties of magnetoactive elastomers with spherical and plate-shaped filler have been studied. Four series of samples based on silicone elastomer and carbonyl iron microparticles have been prepared. A series of samples with a concentration of magnetic filler from 30 to 60 wt % which differed in the shape of filler particles (spherical and platelike) and in their distribution in the polymer matrix (isotropic and anisotropic). The magnetorheological properties of the obtained magnetoactive elastomers have been examined by dynamic mechanical analysis. Storage modulus values for samples of different compositions are in the range of 10–100 kPa. It has been shown that anisotropic materials are stiffer than the isotropic counterparts and demonstrate a higher magnetorheological effect: the increase in the elastic modulus of an anisotropic sample with the maximum filler content exceeds an order of magnitude in a magnetic field of 1 T. At the same filler concentrations, materials based on platelike iron are stiffer than those based on spherical iron. At low magnetic filler concentrations, the use of platelike iron makes it possible to achieve a higher magnetic response of the material; at high filler concentrations, the increase in the elastic modulus is greater for samples based on spherical particles. The anisotropic materials exhibit a more pronounced Payne effect.
期刊介绍:
Polymer Science, Series A is a journal published in collaboration with the Russian Academy of Sciences. Series A includes experimental and theoretical papers and reviews devoted to physicochemical studies of the structure and properties of polymers (6 issues a year). All journal series present original papers and reviews covering all fundamental aspects of macromolecular science. Contributions should be of marked novelty and interest for a broad readership. Articles may be written in English or Russian regardless of country and nationality of authors. All manuscripts are peer reviewed. Online submission via Internet to the Series A, B, and C is available at http://polymsci.ru.
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