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简明历史概述:用于民用结构监测的应变传感器:第一个一百年。

Concise Historic Overview of Strain Sensors Used in the Monitoring of Civil Structures: The First One Hundred Years.

机构信息

Department of Civil and Environmental Engineering, Princeton University, Princeton, NJ 08544, USA.

出版信息

Sensors (Basel). 2022 Mar 20;22(6):2397. doi: 10.3390/s22062397.

DOI:10.3390/s22062397
PMID:35336568
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8951819/
Abstract

Strain is one of the most frequently monitored parameters in civil structural health monitoring (SHM) applications, and strain-based approaches were among the first to be explored and applied in SHM. There are multiple reasons why strain plays such an important role in SHM: strain is directly related to stress and deflection, which reflect structural performance, safety, and serviceability. Strain field anomalies are frequently indicators of unusual structural behaviors (e.g., damage or deterioration). Hence, the earliest concepts of strain sensing were explored in the mid-XIX century, the first effective strain sensor appeared in 1919, and the first onsite applications followed in the 1920's. Today, one hundred years after the first developments, two generations of strain sensors, based on electrical and fiber-optic principles, firmly reached market maturity and established themselves as reliable tools applied in strain-based SHM. Along with sensor developments, the application methods evolved: the first generation of discrete sensors featured a short gauge length and provided a basis for local material monitoring; the second generation greatly extended the applicability and effectiveness of strain-based SHM by providing long gauge and one-dimensional (1D) distributed sensing, thus enabling global structural and integrity monitoring. Current research focuses on a third generation of strain sensors for two-dimensional (2D) distributed and quasi-distributed sensing, based on new advanced technologies. On the occasion of strain sensing centenary, and as an homage to all researchers, practitioners, and educators who contributed to strain-based SHM, this paper presents an overview of the first one hundred years of strain sensing technological progress, with the objective to identify relevant transformative milestones and indicate possible future research directions.

摘要

应变是民用结构健康监测 (SHM) 应用中最常监测的参数之一,基于应变的方法是最早被探索和应用于 SHM 的方法之一。应变在 SHM 中扮演如此重要的角色有多个原因:应变直接与反映结构性能、安全和适用性的应力和挠度相关。应变场异常通常是结构异常行为(例如损坏或劣化)的指标。因此,应变传感的最早概念在 19 世纪中期得到了探索,第一个有效的应变传感器于 1919 年出现,第一个现场应用随后在 20 世纪 20 年代出现。如今,在第一个发展百年之后,基于电和光纤原理的两代应变传感器已经牢固地达到市场成熟,并成为基于应变的 SHM 的可靠工具。随着传感器的发展,应用方法也在不断发展:第一代离散传感器具有短的测量长度,为局部材料监测提供了基础;第二代传感器通过提供长的测量长度和一维 (1D) 分布式传感,大大扩展了基于应变的 SHM 的适用性和有效性,从而实现了全局结构和完整性监测。当前的研究集中在基于新技术的二维 (2D) 分布式和准分布式应变传感器的第三代上。值此应变传感百年之际,作为对所有为基于应变的 SHM 做出贡献的研究人员、从业者和教育工作者的敬意,本文全面回顾了应变传感技术进步的第一个一百年,旨在确定相关的变革性里程碑,并指出可能的未来研究方向。

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