Simultaneous Structural Monitoring over Optical Ground Wire and Optical Phase Conductor via Chirped-Pulse Phase-Sensitive Optical Time-Domain Reflectometry.

IF 3.4 3区 综合性期刊 Q2 CHEMISTRY, ANALYTICAL Sensors Pub Date : 2024-11-20 DOI:10.3390/s24227388
Jorge Canudo, Pascual Sevillano, Andrea Iranzo, Sacha Kwik, Javier Preciado-Garbayo, Jesús Subías
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Abstract

Optimizing the use of existing high-voltage transmission lines demands real-time condition monitoring to ensure structural integrity and continuous service. Operating these lines at the current capacity is limited by safety margins based on worst-case weather scenarios, as exceeding these margins risks bringing conductors dangerously close to the ground. The integration of optical fibers within modern transmission lines enables the use of Distributed Fiber Optic Sensing (DFOS) technology, with Chirped-Pulse Phase-Sensitive Optical Time-Domain Reflectometry (CP-ΦOTDR) proving especially effective for this purpose. CP-ΦOTDR measures wind-induced vibrations along the conductor, allowing for an analysis of frequency-domain vibration modes that correlate with conductor length and sag across spans. This monitoring system, capable of covering distances up to 40 km from a single endpoint, enables dynamic capacity adjustments for optimized line efficiency. Beyond sag monitoring, CP-ΦOTDR provides robust detection of external threats, including environmental interference and mechanical intrusions, which could compromise cable stability. By simultaneously monitoring the Optical Phase Conductor (OPPC) and Optical Ground Wire (OPGW), this study offers the first comprehensive, real-time evaluation of both structural integrity and potential external aggressions on overhead transmission lines. The findings demonstrate that high-frequency data offer valuable insights for classifying mechanical intrusions and environmental interferences based on spectral content, while low-frequency data reveal the diurnal temperature-induced sag evolution, with distinct amplitude responses for each cable. These results affirm CP-ΦOTDR's unique capacity to enhance line safety, operational efficiency, and proactive maintenance by delivering precise, real-time assessments of both structural integrity and external threats.

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通过啁啾脉冲相位敏感光学时域反射仪同时监测光学接地线和光学相位导体的结构。
要优化现有高压输电线路的使用,就必须进行实时状态监测,以确保结构的完整性和持续服务。这些线路在当前容量下的运行受到基于最坏天气情况的安全裕度的限制,因为超过这些裕度有可能使导线危险地接近地面。现代输电线路中集成了光纤,因此可以使用分布式光纤传感(DFOS)技术,其中啁啾脉冲相位敏感光时域反射仪(CP-Φ-OTDR)在这方面尤为有效。CP-ΦOTDR 可测量导体沿线由风引起的振动,从而分析与导体长度和跨距下垂相关的频域振动模式。该监测系统能够覆盖单个端点长达 40 千米的距离,可进行动态容量调整,优化线路效率。除了下垂监测外,CP-ΦOTDR 还能有力地检测外部威胁,包括环境干扰和机械入侵,这些都可能影响光缆的稳定性。通过同时监测光学相导体 (OPPC) 和光学接地线 (OPGW),本研究首次对架空输电线路的结构完整性和潜在外部侵扰进行了全面、实时的评估。研究结果表明,高频数据为根据频谱内容对机械侵入和环境干扰进行分类提供了有价值的见解,而低频数据则揭示了昼夜温度引起的下垂演变,每条电缆都有不同的振幅响应。这些结果肯定了 CP-ΦOTDR 的独特能力,即通过对结构完整性和外部威胁进行精确、实时的评估,提高线路安全性、运行效率和主动维护能力。
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来源期刊
Sensors
Sensors 工程技术-电化学
CiteScore
7.30
自引率
12.80%
发文量
8430
审稿时长
1.7 months
期刊介绍: Sensors (ISSN 1424-8220) provides an advanced forum for the science and technology of sensors and biosensors. It publishes reviews (including comprehensive reviews on the complete sensors products), regular research papers and short notes. Our aim is to encourage scientists to publish their experimental and theoretical results in as much detail as possible. There is no restriction on the length of the papers. The full experimental details must be provided so that the results can be reproduced.
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