基于激光的非接触振动结构索健康监测技术:背景、成功及新进展

Q2 Physics and Astronomy Advances in Acoustics and Vibration Pub Date : 2018-06-13 DOI:10.1155/2018/8640674
A. Mehrabi, Saman Farhangdoust
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引用次数: 30

摘要

结构电缆容易受到高应力集中、腐蚀、风致振动和其他振动的影响。电缆通常是电缆支撑结构中最关键的元件,其健康状况对结构的健康非常重要。本文所讨论的基于激光的振动技术是一种对电缆以及整个电缆支撑结构进行健康监测的手段。该技术使用非接触式遥感激光测振仪来收集数百英尺距离内的电缆振动数据,并确定其动态特性,包括振动频率和阻尼比。然后,使用专门为能够考虑重要缆索参数的结构缆索开发的公式来计算缆索力。将电缆中估计的力与先前测量的力或设计者的预测进行比较,以检测与电缆本身的损坏和/或其他地方的结构变化相关的模式。还将估计的阻尼比与预定义的标准进行比较,以推断对风致振动和其他振动的易感性。该技术为缆索支撑结构的健康监测提供了快速、有效和准确的手段。它确定了潜在损坏的位置和元件,以及详细检查和现场检查的必要性。迄今为止,该技术已成功用于美国和国外25座主要桥梁的评估。虽然最初是为斜拉索的状态评估而设计的,但它已被进一步发展,包括各种系统和条件,其中包括悬挂、特拉斯和拱形桥梁中的结构吊索、不接地斜拉索、带交叉带的拉索和节段桥梁施工中的外部后张钢筋束。它还在施工阶段的活动中找到了一个宝贵的位置,用最少的努力来核查张力元件中的力。这项技术正在考虑未来的自动化和空中交付工作。
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A Laser-Based Noncontact Vibration Technique for Health Monitoring of Structural Cables: Background, Success, and New Developments
Structural cables are susceptible to the effects of high stress concentrations, corrosion, and wind-induced and other vibrations. Cables are normally the most critical elements in a cable-supported structure and their well-being is very important in the health of the structure. The laser-based vibration technique discussed in this paper is a means for health monitoring of cables and therefore the entire cable-supported structure. This technique uses a noncontact remote sensing laser vibrometer for collecting cable vibration data from distances of up to several hundreds of feet and determines its dynamic characteristics including vibration frequencies and damping ratios. A formulation specifically developed for structural cables capable of accounting for important cable parameters is then used to calculate the cable force. Estimated forces in the cables are compared to previously measured forces or designer’s prediction to detect patterns associated with damage to the cable itself and/or changes to the structure elsewhere. The estimated damping ratios are also compared against predefined criteria to infer about susceptibility against wind-induced vibrations and other vibrations. The technique provides rapid, effective, and accurate means for health monitoring of cable-supported structures. It determines the locations and elements with potential damage and the need for detailed and hands on inspection. To date, the technique has been used successfully for evaluation of twenty-five major bridges in the US and abroad. Though originally devised for condition assessment of stay cables, it has been developed further to include a variety of systems and conditions among them structural hanger ropes in suspension, truss, and arch supported bridges, ungrouted stay cables, cables with cross-ties, and external posttensioning tendons in segmental bridge construction. It has also found a valuable place in construction-phase activities for verification of forces in tension elements with minimal efforts. Future endeavors for automation and aerial delivery are being considered for this technique.
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期刊介绍: The aim of Advances in Acoustics and Vibration is to act as a platform for dissemination of innovative and original research and development work in the area of acoustics and vibration. The target audience of the journal comprises both researchers and practitioners. Articles with innovative works of theoretical and/or experimental nature with research and/or application focus can be considered for publication in the journal. Articles submitted for publication in Advances in Acoustics and Vibration must neither have been published previously nor be under consideration elsewhere. Subject areas include (but are not limited to): Active, semi-active, passive and combined active-passive noise and vibration control Acoustic signal processing Aero-acoustics and aviation noise Architectural acoustics Audio acoustics, mechanisms of human hearing, musical acoustics Community and environmental acoustics and vibration Computational acoustics, numerical techniques Condition monitoring, health diagnostics, vibration testing, non-destructive testing Human response to sound and vibration, Occupational noise exposure and control Industrial, machinery, transportation noise and vibration Low, mid, and high frequency noise and vibration Materials for noise and vibration control Measurement and actuation techniques, sensors, actuators Modal analysis, statistical energy analysis, wavelet analysis, inverse methods Non-linear acoustics and vibration Sound and vibration sources, source localisation, sound propagation Underwater and ship acoustics Vibro-acoustics and shock.
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