三支柱绝缘子微缺陷超声临界纵波探测方法与应用

doi:10.19595/j.cnki.1000-6753.tces.241860

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摘要三支柱绝缘子作为超/特高压气体绝缘输电管道（GIL）的关键组部件,会因浇注装配工艺而产生潜伏性缺陷,受电-热-机械等复合应力的作用,易发生劣化放电、炸裂击穿等风险,故实现早期微缺陷探测识别成为当务之急。该文聚焦三支柱绝缘子微缺陷检测技术,提出由中心导杆内壁向支腿嵌件外侧发射的探测方法。采用横/纵波互联方式分别沿体内/表面传播形成通路检测缺陷,进一步根据三支柱绝缘子复杂曲面结构临界纵波透射模式下环氧衍生微裂纹的折反射原理,建立更准确的统一正则化三维声波传导计算模型,获得了不同位置、类型、尺度缺陷下波传导规律与回波信号关联特征,并基于临界体-纵波联合检测方法设计探测系统,进行三支柱绝缘子缺陷信号接收识别实验验证。研究发现,含裂纹缺陷三支柱绝缘子应变能密度呈双峰分布,纵波缺陷波增大且回波能量衰减27.5%,越接近支腿处信号衰减越高,裂纹偏移角度、宽度增加均会导致波形的衰减与时延,探测不同长度裂纹时存在极性效应;气隙缺陷体波的反射回波呈双尖峰分布,幅值升高50%以上。由此优化设计了探测装置,发射频率为柱腿500 kHz/腹部2 MHz,临界入射角为9°,曲率半径为15 mm,可探测缺陷尺寸范围达0.41 mm以上,灵敏度为5.8 dB/mm。该研究为实现GIL三支柱绝缘子微缺陷探测提供了理论依据和有效方法。

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	李玄
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	李庆民

关键词 ：气体绝缘输电管道（GIL）, 三支柱绝缘子, 超声临界纵波, 波动方程正则化, 微缺陷探测

Abstract：Tri-post insulators as key components of ultra/extra-high voltage gas-insulated transmission lines (GIL), are susceptible to defects degradation, discharge brittle cracking breakdown and other potential risks due to latent defects generated by installation processes such as casting and assembly, and by the composite stresses such as electric-thermal-mechanical in the pipeline, so it is imperative to realize the early detection and identification of microdefects to ensure the safe and stable operation of GIL.
This paper focuses on the method of microdefect detection under the complex surface profile of tri-post insulator, calculating the geometrical formation conditions based on the critical longitudinal wave refraction principle between the epoxy-wedge coupling layers, then obtaining the fluctuating displacement quantity by bringing in the insulator characteristic surface profile equation, establishing the regularized correlation matrix between the vibration wave strain and the defective structural parameters under the stress field excitation, and finally generalizing to the amount of longitudinal stress under the defective boundary condition constraints. Corresponding relationship with the electrical signal, a more accurate three-dimensional acoustic wave conduction calculation model is formed. The critical longitudinal wave and body wave are used to detect cracks and air-gap microdefects by dividing the superposition state of tri-post insulator fluctuations into ultrasonic artefacts, propagation and absorption zones in a multi-area measurement method.
An optimized design model for critical longitudinal wave detection of microdefects in tri-post insulator is further established to obtain the correlation characteristics of longitudinal wave conduction law and echo signals under different locations, types and scales of defects. The results show the strain energy density of the tri-post insulator with crack defects is bimodal, and the strain energy increases with the increase of crack length, which leads to the decrease of echo energy, and the signal of critical longitudinal wave detection grows by 22.9%, and the echo energy decays by 27.5%. The closer the crack defects are to the legs, the greater the signal decays, and the better the detection effect; there is a polar effect when detecting cracks of different lengths, short crack echo attenuation is weaker, but longer cracks will lead to compensation of energy loss after superposition interference, and the echo amplitude attenuation is the largest when the crack length is 17.6% of the cross-sectional radius of the leg. In addition, the offset angle of the tri-post insulator surface cracks, thickness increase will hinder the incident propagation, resulting in further wave attenuation and time delay, linear fitting of the characteristic peak equation can be entered into the signal energy attenuation and echo time delay to determine the specific parameters of the microdefects; body wave reflection detection of defects in the air gap when the echo was a double-spike distribution, the amplitude of the amplitude of all the more than 50%, with the increase in the frequency of defects in the waveform is significant. Thus, the optimized design of this detection device has a transmitting frequency of 500 kHz in the abdomen and 2 MHz in the legs, a critical angle of incidence of 9°, a radius curvature of 15 mm, can detect microdefects in the size range of 0.41 mm or more, which defect size sensitivity up to 5.8 dB/mm, with a combined sensitivity assessment of 46.8 dB.
Finally, accordingly, a detection system was designed based on the combined detection method of critical longitudinal and body wave, and preliminary experimental verification of microdefect detection in tri-post insulator was carried out, in which potential microdefects in insulator standard specimens were measured and found to have average error of less than 5%, which realized the quantitative detection and effective analysis of microdefects in tri-post insulator.

Key words： Gas-insulated transmission lines (GIL) tri-post insulator ultrasound critical longitudinal wave regularization of fluctuation equations microdefect detection

收稿日期: 2024-10-21

PACS:

TM216

基金资助:国家自然科学基金（52127812, 51929701）和国网山东电科院科技项目（2023A-139）资助

通讯作者: 李庆民男,1968年生,教授,博士生导师,研究方向为高电压与绝缘技术、放电物理。E-mail: lqmeee@ncepu.edu.cn

作者简介: 李玄男,2001年生,博士研究生,研究方向为GIS/GIL绝缘缺陷检测与内部失效机理。E-mail: lx18801239458@163.com

引用本文:

李玄, 尹奕淳, 师伟, 王健, 任瀚文, 李庆民. 三支柱绝缘子微缺陷超声临界纵波探测方法与应用[J]. 电工技术学报, 2025, 40(21): 6905-6921. Li Xuan, Yin Yichun, Shi Wei, Wang Jian, Ren Hanwen, Li Qingmin. Ultrasonic Critical Longitudinal Wave Detection Method and Application for Microdefects in Tri-Post Insulators. Transactions of China Electrotechnical Society, 2025, 40(21): 6905-6921.

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