一种用于通用机械臂的模块化连续体机器人分段设计*

Nicholas P. Castledine, J. Boyle, Jongrae Kim
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引用次数: 6

摘要

本文介绍了一种模块化设计、结构简单、起重能力强的肌腱驱动连续机器人。该节段具有连续的柔性核心,结合沿其长度均匀分布的刚性互锁椎骨。这种设计允许弯曲在两个自由度,同时最大限度地减少扭转运动。该部分由两个拮抗肌腱对驱动,每个肌腱对由单个齿轮直流电机驱动。模块化是通过将这些电机嵌入到段的一端来实现的,避免了对庞大的驱动单元的需求,并允许连接可变数量的段。该设计的特点是一个大的中空中心孔,可以用作吸力辅助夹持的真空通道或允许流体进出。设计过程经历了四次迭代,最后两次进行了定量实验,以评估工作空间、提升能力和扭转刚度。所有的迭代都是使用多材料3D打印制造的,这使得整个结构可以作为一个预组装的单元打印,刚性椎骨融合到柔性核心。装配是一个简单的例子,插入马达和连接肌腱。这种非传统的制造方法被认为是高效、有效和相对便宜的。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Design of a Modular Continuum Robot Segment for use in a General Purpose Manipulator*
This paper presents the development of a tendon-driven continuum robot segment with a modular design, simple construction and significant lifting capabilities. The segment features a continuous flexible core combined with rigid interlocking vertebrae evenly distributed along its length. This design allows bending in two degrees of freedom while minimising torsional movement. The segment is actuated by two antagonistic tendon pairs, each of which is driven by a single geared DC motor. Modularity is achieved by embedding these motors in one end of the segment, avoiding the need for a bulky actuation unit and allowing variable numbers of segments to be connected. The design features a large hollow central bore which could be used as a vacuum channel for suction-assisted gripping or to allow ingress and egress of fluids. The design process goes through four iterations, the final two of which are subjected to quantitative experiments to evaluate workspace, lifting capabilities and torsional rigidity. All iterations are fabricated using multi-material 3D printing, which allows the entire structure to be printed as a pre-assembled unit with the rigid vertebrae fused to the flexible core. Assembly is then a simple case of inserting the motors and connecting the tendons. This unconventional manufacturing approach is found to be efficient, effective and relatively cheap.
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