材料科学
弹性体
振动
天然橡胶
复合材料
阻尼比
损耗系数
机械振动
动态力学分析
结构工程
声学
聚合物
工程类
光电子学
物理
电介质
作者
Jia‐Xuan He,Zhao-Dong Xu,Zhong-Wei Hu,Teng Ge,Qiangqiang Li,Yao‐Rong Dong,Gabriele Milani
出处
期刊:Polymer Testing
[Elsevier BV]
日期:2025-05-01
卷期号:148: 108835-108835
被引量:8
标识
DOI:10.1016/j.polymertesting.2025.108835
摘要
Vibration damping elastomers often operate under preload engineering scenarios, which demand enhanced dynamic performance in coupled service environments. This study investigated the mechanical behavior of a high damping rubber-based elastomer under pre-compression, cyclic loading, and thermal conditions. The elastomer is based on carboxylated nitrile-butadiene rubber (XNBR) as the matrix and is modified through nanofiller reinforcement and sacrificial bonds. This modification effectively overcomes the conventional conflict between damping efficient and mechanical strength . The mechanical behaviors of pre-compressed elastomers were comprehensively evaluated using quasi-static compression test, low-to-medium frequency cyclic test, and temperature-controlled cyclic test. These tests were conducted under varying frequencies, pre-compressions, amplitudes, and temperatures, which considered coupled service conditions. Test results demonstrated that pre-compression allowed the operational region of cyclic loading to shift along the hyperelastic stress-strain curve, providing higher stiffness and resistance in service. The high damping rubber-based elastomer significantly improved mechanical properties with increasing frequency from 0.1 Hz to 20.0 Hz. Within general ambient temperatures, low temperatures amplified modulus and energy dissipation . Amplitude-driven softening slightly reduced the equivalent modulus but markedly amplified hysteretic energy dissipation, especially under high pre-compression. The high damping rubber-based elastomer exhibited high damping performance over a wide frequency band (0.1–20.0 Hz) and a wide temperature range (10.0–40.0 °C). Appropriate amplitude and well-designed pre-compression dramatically enhanced energy dissipation with suitable bearing capacity. On a microscopic scale , the synergistic effects of polymer chain mobility, filler-matrix interaction, and hydrogen bond dynamic equilibrium explain the compressive behavior and dynamic energy dissipation mechanisms. These findings established a universal framework for designing the high damping rubber-based elastomer with tailored compressive and damping performance, enabling its application in diverse vibration control scenarios requiring precision and adaptability.
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