基于颗粒体阻塞的可变刚度柔性机械手指研究*

doi:10.16731/j.cnki.1671-3133.2025.05.009

现代制造工程 ›› 2025, Vol. 536 ›› Issue (5): 73-81.doi: 10.16731/j.cnki.1671-3133.2025.05.009

基于颗粒体阻塞的可变刚度柔性机械手指研究^*

魏杨珂, 岳龙旺, 李莎, 刘冲

河南工业大学机电工程学院,郑州 450001

收稿日期:2024-11-04 出版日期:2025-05-18 发布日期:2025-05-30
通讯作者: 岳龙旺,博士,教授,博士生导师。E-mail:2022930788@stu.haut.edu.cn
作者简介:魏杨珂,硕士研究生,主要从事机器人技术方面研究。
基金资助:
*国家自然科学基金项目(51541508);河南省自然科学基金项目(182300410286)

Study of variable stiffness flexible mechanical fingers based on granular body obstruction

WEI Yangke, YUE Longwang, LI Sha, LIU Chong

School of Electromechanical Engineering,Henan University of Technology,Zhengzhou 450001,China

Received:2024-11-04 Online:2025-05-18 Published:2025-05-30

摘要/Abstract

摘要： 柔性夹持器的形状可变特性使其在抓取不规则形状和软性物体时,相较于纯刚性夹持器具有巨大的优势。然而,传统的柔性夹持器由于材料和结构的限制,负载能力较弱,难以满足作业要求。介绍了一种基于颗粒体阻塞原理的可变刚度柔性机械手指设计。与传统的气动柔性夹持器相比,该柔性手指增加了颗粒体阻塞层,通过主动的粒子阻塞,大幅度提高了手指的刚度和负载能力。柔性手指通过调节气压来控制手指的弯曲程度,从而最大限度地贴合不规则物体。同时,通过控制颗粒体阻塞层内的真空压力,可以调节机械手指的刚度。随着颗粒体舱真空压力的增加,舱壁在气体压力作用下对其内部的颗粒进行挤压,导致更加紧密的粒子阻塞,从而获得更大的刚度和负载能力。与被动粒子阻塞相比,这种设计的优势在于手指的刚度可以随意改变,不受柔性手指弯曲角度的影响。同时,手指弯曲角度越大,刚度的可调节范围越大。理论研究和实验表明,基于真空颗粒体阻塞的可变刚度柔性手指能够有效改变手指刚度,实现手指弯曲角度和刚度的独立控制,使得柔性夹持器可以执行更多机器人的抓取操作。

关键词: 柔性手指, 可变刚度, 真空颗粒体阻塞, 纤维增强, 解耦控制

Abstract: Flexible grippers,with their ability to conform to various shapes,offer significant advantages over rigid grippers,particularly when handling irregularly shaped or delicate objects. However,traditional flexible grippers often struggle with limited load capacity due to material and structural constraints,making them less effective for certain applications. A novel design for a variable stiffness flexible mechanical finger was introduced,based on the principle of granular body obstruction. This design incorporates a granular interference layer,which significantly enhances the stiffness and load capacity of the finger through active particle interaction.Unlike conventional pneumatic flexible grippers,this design allows for precise control of the finger′s bending by adjusting air pressure,optimizing its fit around irregular objects. Simultaneously,the stiffness of the finger can be fine-tuned by controlling the vacuum pressure within the granular interference layer. As the vacuum pressure increases,the walls of the compartment compress the particles more tightly,resulting in greater stiffness and enhanced load-bearing capacity.This active particle interference approach offers a key advantage over passive systems, the ability to adjust the finger′s stiffness independently of its bending angle. Moreover,as the bending angle increases,the range of stiffness adjustment also expands. Both theoretical analysis and experimental results demonstrate that this variable stiffness flexible finger,utilizing vacuum-controlled granular obstruction,effectively allows for independent control of bending angle and stiffness,enabling the flexible gripper to perform a wider array of robotic grasping tasks.

Key words: flexible gripper, variable stiffness, vacuum particle jamming, fiber reinforcement, decoupled control

中图分类号:

TP241

魏杨珂, 岳龙旺, 李莎, 刘冲. 基于颗粒体阻塞的可变刚度柔性机械手指研究^*[J]. 现代制造工程, 2025, 536(5): 73-81.

WEI Yangke, YUE Longwang, LI Sha, LIU Chong. Study of variable stiffness flexible mechanical fingers based on granular body obstruction[J]. Modern Manufacturing Engineering, 2025, 536(5): 73-81.

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基于颗粒体阻塞的可变刚度柔性机械手指研究^*

Study of variable stiffness flexible mechanical fingers based on granular body obstruction

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