用于风载荷下斜拉攀爬机器人的新型 MR 阻尼器的设计、动态建模和测试。

ISA transactions Pub Date : 2024-11-09 DOI:10.1016/j.isatra.2024.10.022

Kaiwei Ma, Fengyu Xu, Yangru Zhou, Laixi Zhang, Guo-Ping Jiang

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摘要

为了提高桥梁施工设备在高海拔环境下的适应性，本研究探讨了一种专为斜拉索攀爬机器人设计的磁流变（MR）阻尼器。首先，研究人员开发了一种新型阻尼器，其中包含一个弹簧-磁流变流体组合和三个磁路单元。随后，在受力分析的基础上，通过汉密尔顿原理建立了机器人-缆索-风耦合动态模型。仿真结果表明，阻尼器的最大输出力为 204.60 N，最佳工作电流为 0.2 A（力 4）和 0.4 A（力 7）。为了验证分析结果，使用 MR 阻尼器进行了测试。结果显示，实际输出阻尼力的平均相对误差为 4.60%。安装到机器人上后，爬坡速度范围、平均相对误差和最大相对误差分别控制在 0.66 mm/s、0.78% 和 2.5%以内。这种方法可以快速选择合适的工作电流，并显著提高机器人的爬行稳定性。

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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Design, dynamic modeling and testing of a novel MR damper for cable-stayed climbing robots under wind loads.

To increase the adaptability of bridge construction equipment in high-altitude settings, this study examines a magnetorheological (MR) damper designed for cable-stayed climbing robots. Initially, a novel damper incorporating a spring-MR fluid combination and three magnetic circuit units is developed. A robot-cable-wind coupling dynamic model is subsequently formulated via Hamilton's principle, based on force analysis. The simulation results indicate that the damper's maximum output force is 204.60 N, with optimal working currents of 0.2 A (Force 4) and 0.4 A (Force 7). To verify the analysis, testing is conducted using an MR damper. The results reveal an average relative error of 4.60% for the actual output damping force. When mounted on the robot, the climbing speed range, average relative error, and maximum relative error are controlled within 0.66 mm/s, 0.78% and 2.5%, respectively. This approach allows for the rapid selection of suitable working currents and markedly enhances the climbing stability of the robot.

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ISA transactions

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