Design of a Live-Line Inspection Robot System for Insulators in UHVDC Transmission Lines

Authors

  • Yunfeng Yan Inner Mongolia Power Group Wuhai Extra High Voltage Power Supply Company
  • Hao Sun Inner Mongolia Power Group Wuhai Extra High Voltage Power Supply Company
  • Fei Hao Inner Mongolia Power Group Wuhai Extra High Voltage Power Supply Company
  • Peng Chen Inner Mongolia Power Group Wuhai Extra High Voltage Power Supply Company
  • Tianlong Zhang Inner Mongolia Power Group Wuhai Extra High Voltage Power Supply Company
  • Zehua Yang Inner Mongolia Power Group Wuhai Extra High Voltage Power Supply Company

DOI:

https://doi.org/10.4108/ew.11877

Keywords:

UHVDC transmission, low zero-value insulators, detection robot, PSO-SVR algorithm, electromagnetic shielding, data optimization, live-line detection

Abstract

To address the pain points of low-zero insulators in UHVDC transmission lines, which are prone to insulation flashover, and the low accuracy, reliance on manual labor, and weak anti-interference capabilities of traditional inspection methods, this study developed an integrated live-line inspection robot that combines mechanical climbing, precise inspection, intelligent control, and electromagnetic shielding. The robot system comprises a mechanical system (tracked movement mechanism, guiding and clamping mechanism), detection system (2500V high-voltage detection circuit, MEGA128 microcontroller control), control system (L298N motor drive, frequency-hopping spread spectrum wireless data transmission), and electromagnetic shielding system (multi-layer shielding shell, opto-isolation, multi-point common ground). An innovative "equipotential bypass" detection principle is proposed to eliminate leakage current interference, and an improved PSO-SVR fusion algorithm is introduced to optimize the detection data. Experimental verification showed that in laboratory tests, the robot exhibited excellent electromagnetic interference resistance (shielding effectiveness SE≥ 60 dB) and a resistance measurement error ≤±2.5%. In actual live-line testing of 500 kV/1000 kV lines, the detection error was ≤±3%, the detection cycle for a single string (28/32 pieces) was only 92~108s, the detection rate of degraded insulators was 100%, and it eliminated the need for power outages and manual tower climbing. This robot meets the "live-line, accurate, efficient, and interference-resistant" detection requirements of UHV lines, providing reliable technical support for the intelligent operation and maintenance of power grids and has broad engineering application prospects.

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Published

09-02-2026

Issue

Vol. 12 (2025): EAI Endorsed Transactions on Energy Web

Section

Research articles

License

Copyright (c) 2026 Yunfeng Yan, Hao Sun, Fei Hao, Peng Chen, Tianlong Zhang, Zehua Yang

Creative Commons License

This work is licensed under a Creative Commons Attribution-NonCommercial-ShareAlike 4.0 International License.

This is an open-access article distributed under the terms of the Creative Commons Attribution CC BY 4.0 license, which permits unlimited use, distribution, and reproduction in any medium so long as the original work is properly cited.

How to Cite

1.
Yan Y, Sun H, Hao F, Chen P, Zhang T, Yang Z. Design of a Live-Line Inspection Robot System for Insulators in UHVDC Transmission Lines. EAI Endorsed Trans Energy Web [Internet]. 2026 Feb. 9 [cited 2026 Feb. 15];12. Available from: https://publications.eai.eu/index.php/ew/article/view/11877

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