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利用自传感FRP筋实现结构性能全面监测和自诊断研究 被引量:4

Structural monitoring and health self-diagnosing based on self-sensing FRP bars
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摘要 基于对现有结构健康监测(SHM)的分析,提出了利用应变传感方式开发自传感FRP筋实现结构全面监测和评估的SHM体系。为此,首先针对结构应变传感的需求开发一系列封装技术,将分布式传感光纤埋设进纤维复合材料(FRP),制备自传感FRP筋,大幅提升了光纤的传感性能、施工性和传感耐久性,扩大了其应用范围。随后,针对土木建筑结构具有体量大、杆件多、损伤局部发生等特点,提出了在这些损伤发生概率大的区域分布式布设传感器,进行全面监测,也即区域传感的理念。同时,通过纤维模型理论和动力参数分析理论建立结构健康诊断体系。最后,通过梁、柱的模型验证了所提出的结构监测和健康自诊断体系。研究结果表明,基于应变监测可以建立有效的SHM体系。 A self-sensing FRP bar based SHM system for achieving comprehensive structural monitoring and self-evaluating was presented. At first, the distributed optical fiber sensors were embedded into fiber reinforced polymer (FRP) to manufacture the self-sensing FRP bar with some special packages, making the optical fiber more effective and robust, which expanded the scope of its application the harsh environment of civil engineering. Then, considering the features of civil engineering structures, such as large-scale, a lot of members and damage developing locally, the concept of area sensing was proposed to optimize the sensor installation, namely distributed installation of sensors covering the zones where damages will happen with large possibility. Subsequently, the structural health self-diagnosing system was proposed based on the theories of fiber model and dynamic analysis methods. At last, the proposed structural monitoring and health self-diagnosing was verified with the experiments of beam and column models in the lab. The results have confirmed that the efficient SHM system can be constructed with only strain monitoring.
作者 吴智深 唐永圣 黄璜
机构地区 东南大学城市工程科学研究院 日本茨城大学
出处 《建筑结构》 CSCD 北大核心 2013年第19期5-9,4,共6页 Building Structure
关键词 结构健康监测 分布式光纤传感 自传感FRP筋 structural health monitoring distributed optical fiber sensing self-sensing FRP bar
分类号 TU317 [建筑科学—结构工程]
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参考文献12

  • 1WU ZHISHEN. Structural health monitoring and intelligent infrastructures in Japan [ C ]. Japan: A. A. BALKEMA Publishers, 2003.
  • 2LI SUZHEN, WU ZHISHEN. Development of distributed long-gage fiber optic sensing system for structural health monitoring[ J]. Structural Health Monitoring, 2007, 6 (7) :133-143.
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同被引文献38

引证文献4

二级引证文献23

建筑结构
2013年 第19期

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