Piston-like particle jamming for enhanced stiffness adjustment of soft robotic arm

Tianlei Wang, Fei Ding, Zhenxing Sun
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Abstract

Purpose

Stiffness adjusting ability is essential for soft robotic arms to perform complex tasks. A soft state enables dexterous operation and safe interaction, while a rigid state enables large force output or heavy weight carrying. However, making a compact integration of soft actuators with powerful stiffness adjusting mechanisms is challenging. This study aims to develop a piston-like particle jamming mechanism for enhanced stiffness adjustment of a soft robotic arm.

Design/methodology/approach

The arm has two pairs of differential tendons for spatial bending, and a jamming core consists of four jamming units with particles sealed inside braided tubes for stiffness adjustment. The jamming core is pushed and pulled smoothly along the tendons by a piston, which is then driven by a motor and a ball screw mechanism.

Findings

The tip displacement of the arm under 150 N jamming force and no more than 0.3 kg load is minimal. The maximum stiffening ratio measured in the experiment under 150 N jamming force is up to 6–25 depends on the bending direction and added load of the arm, which is superior to most of the vacuum powered jamming method.

Originality/value

The proposed robotic arm makes an innovative compact integration of tendon-driven robotic arm and motor-driven piston-like particle jamming mechanism. The jamming force is much larger compared to conventional vacuum-powered systems and results in a superior stiffening ability.

用于增强软机械臂刚度调节的活塞式粒子干扰器
目的刚度调节能力对于软机械臂执行复杂任务至关重要。柔软状态可实现灵巧的操作和安全的交互,而刚性状态则可实现大的力输出或重物承载。然而,如何将软致动器与强大的刚度调节机制紧凑地集成在一起是一项挑战。本研究旨在开发一种类似活塞的粒子干扰机制,以增强软机械臂的刚度调节能力。该机械臂有两对用于空间弯曲的差分腱,以及一个由四个干扰单元组成的干扰核心,其中的粒子密封在用于刚度调节的编织管内。在 150 牛顿的干扰力和不超过 0.3 公斤的负载下,机械臂的顶端位移极小。原创性/价值所提出的机械臂创新性地将肌腱驱动机械臂和电机驱动的活塞式粒子干扰机构紧凑地结合在一起。与传统的真空供电系统相比,该系统的干扰力更大,因此具有更强的加固能力。
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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