开发带内角墙自适应磁力粘附机制的轮式爬壁机器人

IF 4.2 2区 计算机科学 Q2 ROBOTICS
Baoyu Wang, Peixing Li, Peibo Li, Lin Zhang, Enguang Guan, Xun Liu, Xudong Hu, Yanzheng Zhao
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引用次数: 0

摘要

爬壁机器人是造船、石化等行业大型复杂部件机器人化智能制造的发展趋势,但仍有几个难题亟待解决,即有效载荷重量比低、表面适应性差、穿越机动性差,尤其是在有内拐角的非连续表面(non-CSIC)上。本文设计了一种高载重重量比的轮式爬壁机器人,它能有效地在非 CSIC 上行走,载重量高达 75 千克,在垂直墙壁上的最大载重量为 141.5 千克。通过引入半封闭磁吸附机构,该机器人在局部机身部件与墙壁表面之间存在明显间隙的情况下,仍能保持冗余的磁吸附能力。此外,通过在机器人中巧妙地设计一个无源自适应模块,在不增加机身与墙壁之间间隙的情况下,增强了表面适应性和穿越性,从而确保了吸附力的优化。考虑到在垂直墙壁、倾斜墙壁、天花板和内部转角处攀爬时的有效载荷容量和多样性,利用有限元分析工具对内部转角处的控制方程和磁吸附力进行了全面模拟。最后,还开发了一个功能原型进行严格的实验测试,结果证实该机器人成功地达到了预期的功能和性能基准。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Development of a wheeled wall‐climbing robot with an internal corner wall adaptive magnetic adhesion mechanism
The wall‐climbing robot is a growing trend for robotized intelligent manufacturing of large and complex components in shipbuilding, petrochemical, and other industries, while several challenges remain to be solved, namely, low payload‐to‐weight ratio, poor surface adaptability, and ineffective traversal maneuverability, especially on noncontinuous surfaces with internal corners (non‐CSIC). This paper designs a high payload‐to‐weight ratio wheeled wall‐climbing robot which can travel non‐CSIC effectively with a payload capacity of up to 75 kg, and it can carry a maximum load of 141.5 kg on a vertical wall. By introducing a semi‐enclosed magnetic adhesion mechanism, the robot preserves a redundant magnetic adsorption ability despite the occurrence of significant gaps between localized body components and the wall surface. In addition, by ingeniously engineering a passive adaptive module into the robot, both the surface adaptability and crossability are enhanced without increasing the gap between the body and the wall, thereby ensuring the optimization of the adsorption force. Considering the payload capacity and diversity when climbing on vertical walls, inclined walls, ceilings, and internal corner transitions, control equations for internal corner transitions and comprehensive simulations of magnetic adsorption forces are performed using FEA tools. Finally, a functional prototype was developed for rigorous experimental testing, with the results confirming that the robot successfully meets the desired functionality and performance benchmarks.
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来源期刊
Journal of Field Robotics
Journal of Field Robotics 工程技术-机器人学
CiteScore
15.00
自引率
3.60%
发文量
80
审稿时长
6 months
期刊介绍: The Journal of Field Robotics seeks to promote scholarly publications dealing with the fundamentals of robotics in unstructured and dynamic environments. The Journal focuses on experimental robotics and encourages publication of work that has both theoretical and practical significance.
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