Highly sensitive and stable conductive elastomer composites for strain monitoring of seismic isolation bearings: Experiment and molecular simulation

IF 6.8 3区材料科学 Q1 MATERIALS SCIENCE, MULTIDISCIPLINARY

Journal of Science: Advanced Materials and Devices Pub Date : 2025-06-13 DOI:10.1016/j.jsamd.2025.100924

Bangwei Wan , Yong Yuan , Yang Yang , Xiaotao Yu , Rongxin Guo , Yong Yan

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引用次数: 0

Abstract

Seismic isolation bearings are critical components for energy dissipation and seismic resistance in building structures. Real-time deformation monitoring during service can provide timely performance assessments, accurately evaluate damage, reduce maintenance costs, and enhance construction efficiency. Conductive elastomers, which exhibit a resistance/strain response, are effective sensing materials for such monitoring. However, they often suffer from a shoulder peak effect in their output monitoring signals, compromising monitoring stability and reliability. In this study, we endowed elastomer (VMQ) with conductive properties using multi-walled carbon nanotubes (MWCNT) and modified its cross-linking structure with Hydrogen silicone oil (TMS) and Hydrosilane (HSO) to eliminate the shoulder peak effect. Results showed that introducing dihydrogen structures reduced the resistive hysteresis area by 94.22 % and eliminated the shoulder peak effect. The underlying mechanism was explored through a combination of experiments and molecular dynamics (MD) simulations. Additionally, the tensile strength and elongation at the break of the conductive elastomer improved by 21.89 % and 45.11 %, respectively. The optimized conductive elastomer exhibited excellent strain-sensing properties, including high sensitivity (GF = 2918.524) and a fast response time (217 ms). Its resistance/strain response remained stable and free of shoulder peak effects across different strain levels and strain rates after 5000 loading-unloading cycles. When applied to seismic isolation bearings, the material maintained a stable monitoring signal under large deformations. These findings highlight the potential of this innovative sensing composite for structural health monitoring in large-scale components.

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用于地震隔离轴承应变监测的高灵敏度和稳定的导电弹性体复合材料：实验和分子模拟

隔震支座是建筑结构耗能和抗震的关键部件。使用过程中的实时变形监测，可提供及时的性能评估，准确评估损坏情况，降低维护成本，提高施工效率。导电弹性体表现出电阻/应变响应，是这种监测的有效传感材料。然而，它们的输出监测信号往往存在肩峰效应，影响监测的稳定性和可靠性。在这项研究中，我们利用多壁碳纳米管（MWCNT）赋予弹性体（VMQ）导电性能，并用氢硅油（TMS）和氢硅烷（HSO）修饰其交联结构，以消除肩峰效应。结果表明，双氢结构的引入使电阻滞后面积减小了94.22%，消除了肩峰效应。通过实验和分子动力学（MD）模拟相结合的方法探讨了其潜在的机制。此外，导电弹性体的抗拉强度和断裂伸长率分别提高了21.89%和45.11%。优化后的导电弹性体具有优异的应变传感性能，灵敏度高（GF = 2918.524），响应时间快（217 ms）。在5000次加载-卸载循环后，其电阻/应变响应在不同应变水平和应变速率下保持稳定，不存在肩峰效应。当应用于隔震支座时，该材料在大变形下保持稳定的监测信号。这些发现突出了这种创新传感复合材料在大型部件结构健康监测方面的潜力。

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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来源期刊

Journal of Science: Advanced Materials and Devices Materials Science-Electronic, Optical and Magnetic Materials

CiteScore

11.90

自引率

2.50%

发文量

审稿时长

47 days

期刊介绍： In 1985, the Journal of Science was founded as a platform for publishing national and international research papers across various disciplines, including natural sciences, technology, social sciences, and humanities. Over the years, the journal has experienced remarkable growth in terms of quality, size, and scope. Today, it encompasses a diverse range of publications dedicated to academic research. Considering the rapid expansion of materials science, we are pleased to introduce the Journal of Science: Advanced Materials and Devices. This new addition to our journal series offers researchers an exciting opportunity to publish their work on all aspects of materials science and technology within the esteemed Journal of Science. With this development, we aim to revolutionize the way research in materials science is expressed and organized, further strengthening our commitment to promoting outstanding research across various scientific and technological fields.