Dynamic mechanical behaviors of epoxy resin/hollow polymeric microsphere composite foams under forced non-resonance and forced resonance

Rui Li, Guisen Fan, Ouyang Xiao, Guojun Wang, Hao Wei
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引用次数: 1

Abstract

Composite foams with 10–50 vol% hollow polymeric microspheres were prepared using bisphenol A epoxy resin and polyetheramine curing agent as the matrix. The results demonstrated that the density, hardness, and static mechanical properties of the epoxy resin/hollow polymer microsphere composite foams, as well as their dynamic mechanical properties under forced non-resonance, were similar to those of polymer/hollow glass microsphere composite foams. At 25°C and under 1–100 Hz forced resonance, the first-order and second-order resonance frequencies of the composite foams shifted to the low-frequency region as the volume fraction of hollow polymer microspheres increased. Meanwhile, the first-order and second-order loss factors of the as-prepared composite foams were improved by 41.7% and 103.3%, respectively, compared with the pure epoxy resin. Additionally, the first-order and second-order loss factors of the as-prepared composite foams reached a maximum at 40 vol% and 30 vol% hollow polymer microspheres, respectively. This research helps us to expand the application range of composite foam materials in damping research.
环氧树脂/中空聚合物微球复合泡沫在强制非共振和强制共振下的动态力学行为
以双酚A型环氧树脂和聚醚胺固化剂为基体,制备了体积分数为10 ~ 50%的中空聚合物微球复合泡沫材料。结果表明:环氧树脂/中空聚合物微球复合泡沫的密度、硬度、静态力学性能以及在强制非共振条件下的动态力学性能与聚合物/中空玻璃微球复合泡沫相似;在25℃和1 ~ 100 Hz强制共振条件下,随着空心聚合物微球体积分数的增加,复合泡沫的一阶和二阶共振频率向低频区偏移。与纯环氧树脂相比,复合泡沫材料的一阶和二阶损失系数分别提高了41.7%和103.3%。此外,在所制备的复合泡沫材料的一阶和二阶损失因子分别达到40 vol%和30 vol%的中空聚合物微球的最大值。本研究有助于拓展复合泡沫材料在阻尼研究中的应用范围。
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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