Optimized Design and Performance Comparison of Wheeled Type In-Pipe Inspection Robot

2022 6th International Conference on Electronics, Communication and Aerospace Technology Pub Date : 2022-12-01 DOI:10.1109/ICECA55336.2022.10009509

R. Elankavi, D. Dinakaran, R. Chetty, M. M. Ramya, J. Jose

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引用次数: 1

Abstract

Pipelines are crucial in transportation, requiring regular maintenance to function correctly. Robots perform maintenance works, and each robot moves through the pipes using a different mechanism. The In-Pipe Inspection robots are categorized based on their locomotion types. The mechanisms utilized by wheeled wall-pressed type In-Pipe Inspection Robots are divided into dependent and independent mechanisms. The present wheeled IPIR using the dependent mechanism finds difficulty in passing through vertical pipe with obstacles. In this study, one robot from each mechanism is chosen, and the mobility of that robot inside a vertical pipe with an obstacle is examined through simulation using the MSC ADAMS software and observed experimentally. The results show that the robot wheels used in the independent mechanism always make contact with the pipeline's inner surface compared to the dependent mechanism. This result indicates that the robot with the independent mechanism is more suitable for In-Pipe inspection.

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轮式管道检测机器人的优化设计与性能比较

管道在运输中至关重要，需要定期维护才能正常运行。机器人执行维护工作，每个机器人使用不同的机制在管道中移动。管道内检测机器人根据其运动类型进行分类。轮式压壁式管道检测机器人采用的机构分为依赖机构和独立机构。目前采用依赖机构的轮式IPIR在通过有障碍物的垂直管道时存在困难。在本研究中，从每个机构中选择一个机器人，并使用MSC ADAMS软件通过模拟和实验观察该机器人在有障碍物的垂直管道中的移动性。结果表明:与依赖机构相比，独立机构的机器人轮毂始终与管道内表面接触;结果表明，采用独立机构的机器人更适合于管道内检测。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2022 6th International Conference on Electronics, Communication and Aerospace Technology

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