Research on motion planning system for wall-climbing mobile manipulator for large steel structures welding operation

Yan Xu, Yaqiu Liu, Xun Liu, Baoyu Wang, Lin Zhang, Zhengwen Nie
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Abstract

Purpose

The purpose of this study is to address the welding demands within large steel structures by presenting a global spatial motion planning algorithm for a mobile manipulator. This algorithm is based on an independently developed wall-climbing robot, which comprises a four-wheeled climbing mobile platform and a six-degree-of-freedom robotic manipulator, ensuring high mobility and operational flexibility.

Design/methodology/approach

A convex hull feasible domain constraint is developed for motion planning in the mobile manipulator. For extensive spatial movements, connected sequences of convex polyhedra are established between the composite robot’s initial and target states. The composite robot’s path and obstacle avoidance optimization problem are solved by constraining the control points on B-spline curves. A dynamic spatial constraint rapidlye-xploring random trees-connect (RRTC) motion planning algorithm is proposed for the manipulator, which quickly generates reference paths using spherical spatial constraints at the manipulator’s end, eliminating the need for complex nonconvex constraint modeling.

Findings

Experimental results show that the proposed motion planning algorithm achieves optimal paths that meet task constraints, significantly reducing computation times in task conditions and shortening operation times in non-task conditions.

Originality/value

The algorithm proposed in this paper holds certain application value for the realization of automated welding operations within large steel structures using mobile manipulator.

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用于大型钢结构焊接作业的爬墙移动机械手运动规划系统研究
目的 本研究的目的是通过提出一种移动机械手的全局空间运动规划算法来满足大型钢结构的焊接需求。该算法基于自主研发的爬墙机器人,它由一个四轮攀爬移动平台和一个六自由度机器人机械手组成,确保了高机动性和操作灵活性。设计/方法/途径为移动机械手的运动规划开发了一个凸壳可行域约束。对于大范围的空间运动,在复合机器人的初始状态和目标状态之间建立连接的凸多面体序列。通过在 B-样条曲线上对控制点进行约束,解决了复合机器人的路径和避障优化问题。为机械手提出了一种动态空间约束快速探索随机树连接(RRTC)运动规划算法,该算法利用机械手端的球形空间约束快速生成参考路径,无需复杂的非凸约束建模。实验结果实验结果表明,所提出的运动规划算法实现了满足任务约束条件的最优路径,显著减少了任务条件下的计算时间,缩短了非任务条件下的操作时间。 原创性/价值本文提出的算法对于利用移动机械手实现大型钢结构内的自动化焊接操作具有一定的应用价值。
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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