Design and experiment of CLIBOT, a novel UHV insulator climbing robot with discrete optimization

Yunxiang Li, Yunfei Ai, Jinzhou Zou, Liangyu Liu, Chengjian Liu, Siheng Fu, Dehua Zou, Wang Wei
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Abstract

Purpose

By analyzing the shortcomings of existing insulator robots, a novel ultra high voltage (UHV) insulator climbing robot, which could transfer between adjacent insulator strings, is proposed for operation on 800KV multiple-string insulators. An extended inchworm-like configuration was chosen and a stable gripping claw suitable for the insulator string was designed to enable the robot to multiple-string insulators. Then a set of nonheuristic structural parameters that can influence energy consumption was chosen to formulate a nonlinear optimization problem based on the configuration, which improved the energy efficiency of the robot during progressing along a string of insulator.

Design/methodology/approach

The purpose of this paper is to design an insulator climbing robot for operation on UHV multiple-string insulators, which could transfer between adjacent insulator strings and progressed along a string of insulator with high energy efficiency.

Findings

A physical prototype was constructed that can operate at the speed of six pieces per minute (approximately 1.44 meters per minute) on a single string and complete transference between adjacent strings in 45 s. The energy consumption of joints during progressed along a string of insulator had been reduced by 38.8% with the optimized parameters, demonstrating the consistency between the experimental and simulation results.

Originality/value

An insulator climbing robot for operation on UHV multiple-string insulators has been developed with energy consumption optimization design. The robot can transfer between adjacent insulator strings and progressed along a string of insulator with high energy efficiency. The CLIBOT could be expanded to detect or clean the insulators with similar specification.

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新型超高压绝缘子攀爬机器人 CLIBOT 的设计与实验
目的 通过分析现有绝缘子机器人的缺点,提出了一种新型超高压(UHV)绝缘子攀爬机器人,可在相邻绝缘子串之间进行转移,适用于 800KV 多串绝缘子的操作。为了使机器人能够在多串绝缘子上移动,我们选择了一种类似于尺蠖的扩展构型,并设计了适合绝缘子串的稳定抓爪。本文的目的是设计一种在特高压多串绝缘子上运行的绝缘子攀爬机器人,它可以在相邻绝缘子串之间转移,并以较高的能效沿绝缘子串前进。研究结果 制作了一个物理原型,它能以每分钟六块(约每分钟 1.44 米)的速度在单根绝缘子串上运行,并能在 45 秒内完成相邻绝缘子串之间的转移。该机器人可在相邻绝缘子串之间转移,并以较高的能效沿绝缘子串前进。CLIBOT 还可扩展用于检测或清洁类似规格的绝缘子。
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