基于电致发光效应的输电线路零值绝缘子自诊断关键技术

doi:10.19595/j.cnki.1000-6753.tces.250843

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摘要针对目前输电线路零值绝缘子带电检测准确性差的问题,该文首先通过理论分析和试验测试,研究外部因素及内在填料配比对ZnS:Cu电致发光涂料的发光亮度、临界发光阈值电场强度等发光特性的影响规律,并制备出可满足输电线路零值瓷绝缘子自诊断需求的电致发光涂料;然后建立了110 kV瓷绝缘子串表面电场分布仿真模型,确定了电致发光涂料在绝缘子表面的最佳喷涂位置及喷涂面积;最后搭建带电试验平台,分析了绝缘子串在不同工况下的发光效果,验证了仿真结果的准确性,并提出了输电线路零值绝缘子自诊断方案。研究结果表明：电致发光涂料的发光亮度随涂层厚度、填料浓度和高介电常数颗粒质量分数的增加先上升后下降,调控后的电致发光涂料的临界发光阈值电场强度可控制在约200 kV/m;绝缘子钢脚部分水泥与瓷件交界处较为适宜作为喷涂电致发光涂料的特征区域,最佳涂层宽度约为10 mm;正常工况下,绝缘子串每片绝缘子的电致发光涂层均可以发光,当存在零值绝缘子时,零值绝缘子表面的电致发光涂层灰度值低于30,其余正常阻值绝缘子表面的电致发光涂层灰度值出现不同程度增加,可根据发光灰度值对零值绝缘子进行自诊断。该文为输电线路零值绝缘子检测提供了新的思路,可有效地提升输电线路瓷质绝缘子零值检测的准确性。

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关键词 ：电致发光, 零值绝缘子, 发光特性, 临界发光阈值电场强度, 输电线路

Abstract：To address the challenges of inadequate detection accuracy in the live-line identification of zero-value insulators on transmission lines, this study investigates the luminescence mechanisms of electroluminescent materials. This is achieved through experimental analysis of various factors that influence the photoluminescent characteristics of ZnS:Cu. An electroluminescent coating spray was developed for application on porcelain insulator surfaces, and its critical luminescence threshold electric field was determined. Finite element simulations were conducted to calculate the electric field distribution across the surfaces of porcelain insulators, and in conjunction with the coating's critical threshold, optimal application locations and coating area dimensions were identified. Finally, a self-diagnosis scheme for transmission line zero-value insulators was proposed based on electric field simulations and live-line test results under various operational conditions. Research results indicate：
Firstly, the effects of external factors and the internal filler ratio on the luminescence characteristics of ZnS:Cu electroluminescent coatings were examined through both theoretical analysis and experimental methods. Electroluminescent coatings suitable for application on the surfaces of insulators were developed. The luminous brightness of the electroluminescent coating initially increases and then decreases with the rise in coating thickness, filler concentration, and the mass fraction of high dielectric constant particles. Furthermore, the critical luminescence threshold electric field of the controlled electroluminescent coating can be maintained at approximately 200 kV/m. Compared to the electroluminescent coating before modification, the critical luminescence threshold electric field of the modified coating was reduced by approximately 83.33%, effectively lowering the threshold required to initiate electroluminescence.
Secondly, the results of the electric field simulation indicate that when the zero-value insulator is positioned on the high-voltage side, the electric field’s influence on the surface of the insulator string is greater than when it is located in the middle. This influence is also greater than when it is situated on the low-voltage side. Furthermore, the impact of the continuous double-piece zero value on the surface electric field of the insulator string is more significant than that of the non-continuous double-piece zero value, and it surpasses the effect of the single-piece zero value. The interface region between the porcelain and cement at the insulator’s steel feet exhibits electric field intensities that exceed the critical threshold of 200 kV/m, making it the optimal area for coating application. A coating width of 10 mm is recommended at this interface.
Finally, under normal operating conditions, faint luminescence is observed at the interface of the steel foot coating. When zero-value insulators are present, the grayscale value of the affected coatings decreases to below 30. The severity of the influence follows this order: high-voltage side positioning>central positioning>low-voltage side positioning for single defective insulators, with continuous dual defects>discontinuous dual defects>single defects. Live-line test results show consistent agreement with surface electric field simulations. In addition, a solution utilizing narrowband optical filtering technology is proposed to effectively mitigate the impact of outdoor ambient light on observational quality. These research outcomes significantly enhance the detection accuracy of zero-value porcelain insulators in transmission lines.

Key words： Electroluminescence zero-value insulator luminescence properties critical luminescence threshold electric field transmission lines

收稿日期: 2025-05-20

PACS:

TM216

基金资助:中国电力科学研究院双创孵化基金资助项目（GYB51202402227）

通讯作者: 陈铭宏天男,2001年生,硕士研究生,研究方向为电气设备在线监测与故障诊断。E-mail：cmht20230630@163.com

作者简介: 耿江海男,1980年生,正高级工程师,研究方向为电气设备绝缘机理和状态检修、电气设备在线监测与故障诊断等。E-mail：gengjianghai@163.com

引用本文:

耿江海, 陈铭宏天, 张育铭, 周松松, 王平. 基于电致发光效应的输电线路零值绝缘子自诊断关键技术[J]. 电工技术学报, 2026, 41(9): 3141-3156. Geng Jianghai, Chen Minghongtian, Zhang Yuming, Zhou Songsong, Wang Ping. Key Technologies for Self-Diagnosis of Zero-Value Insulators of Transmission Lines Based on Electroluminescence Effect. Transactions of China Electrotechnical Society, 2026, 41(9): 3141-3156.

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