Kinematics and control of a cable-driven snake-like manipulator for underwater application

IF 1 4区工程技术 Q4 ENGINEERING, MECHANICAL Mechanical Sciences Pub Date : 2022-06-07 DOI:10.5194/ms-13-495-2022

F. Xue, Zhimin Fan

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引用次数: 1

Abstract

Abstract. In view of the large volume, complex structure, and poor performance of traditional underwater manipulators in some complicated underwater scenarios, a cable-driven snake-like manipulator (CDSLM) is proposed. In this paper, the kinematics model of the proposed CDSLM is firstly established, which can be decomposed into three parts: motor–cable kinematics, cable–joint kinematics, and joint–end kinematics. A tip-following algorithm is then presented to weave through the confined and hazardous spaces along a defined path with high efficiency. The main merit of the algorithm is that only the terminal section variables need to be calculated and recorded, which solves the problem of expensive computational cost for the inverse kinematics of snake-like manipulators. Finally, evaluation indexes of the path-following performance are proposed to evaluate the effect of the tip-following algorithm. Simulations of the path-tracking performance are carried out using MATLAB. The results demonstrate that the average computation time is about 1.6 ms, with a deviation of less than 0.8 mm from the desired path, and the stability and effectiveness of the tip-following algorithm are verified.

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水下蛇形索驱动机械臂的运动学与控制

摘要针对传统水下机械臂体积大、结构复杂、在一些复杂水下场景下性能不佳的问题，提出了一种索驱动蛇形机械臂(CDSLM)。本文首先建立了CDSLM的运动学模型，将其分解为电机-电缆运动学、电缆-关节运动学和关节端运动学三个部分。在此基础上，提出了一种尖端跟踪算法，可以沿确定的路径高效地穿过受限和危险空间。该算法的主要优点是只需要计算和记录末端截面变量，解决了蛇形机械臂逆运动学计算成本高的问题。最后，提出了路径跟踪性能的评价指标来评价尖端跟踪算法的效果。利用MATLAB对其路径跟踪性能进行了仿真。结果表明，平均计算时间约为1.6 ms，与期望路径的偏差小于0.8 mm，验证了尖端跟踪算法的稳定性和有效性。

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来源期刊

Mechanical Sciences ENGINEERING, MECHANICAL-

CiteScore

2.20

自引率

7.10%

发文量

审稿时长

29 weeks

期刊介绍： The journal Mechanical Sciences (MS) is an international forum for the dissemination of original contributions in the field of theoretical and applied mechanics. Its main ambition is to provide a platform for young researchers to build up a portfolio of high-quality peer-reviewed journal articles. To this end we employ an open-access publication model with moderate page charges, aiming for fast publication and great citation opportunities. A large board of reputable editors makes this possible. The journal will also publish special issues dealing with the current state of the art and future research directions in mechanical sciences. While in-depth research articles are preferred, review articles and short communications will also be considered. We intend and believe to provide a means of publication which complements established journals in the field.