A Pneumatically-Actuated Variable-Stiffness Robot Arm Using Parallel Flexures

2018 IEEE International Conference on Robotics and Biomimetics (ROBIO) Pub Date : 2018-12-01 DOI:10.1109/ROBIO.2018.8665208

V. Venkiteswaran, Ruiqin Hu, H. Su

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引用次数: 2

Abstract

A novel design is presented for a variable-stiffness robotic arm from conceptual design to experimental validation, utilizing a fast-acting pneumatic rodless cylinder with minimal footprint. Unlike other systems previously developed that rely on variation of compliance in kinematic joints, the proposed design enables the manipulator arm itself to undergo stiffness change by controlling the effective length of two parallel sheet flexures. The behavior is modeled using traditional beam bending equations. The concept is validated using finite element analysis and experiments. Quick and accurate stiffness change is demonstrated using static and dynamic calibration of the system. The overall change in stiffness for static applications is about lO-fold, and it can be achieved in about 0.6 seconds. The ability of the controller to track stiffness profiles over time is also demonstrated through experiments. We envision that the presented variable-stiffness robotic arm can be cascaded for accommodating three axes of impacts, for building multi-linked collaborative manipulators.

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一种并联柔性气动变刚度机械臂

提出了一种从概念设计到实验验证的变刚度机械臂的新设计，该设计利用了占地面积最小的快速作用气动无杆气缸。与以前开发的依赖于运动关节顺应性变化的其他系统不同，所提出的设计使机械臂本身能够通过控制两个平行板挠曲的有效长度来进行刚度变化。使用传统的梁弯曲方程对其性能进行了建模。通过有限元分析和实验验证了这一概念。通过对系统的静态和动态标定，证明了系统刚度变化快速准确。静态应用程序的总体刚度变化约为lO-fold，可以在大约0.6秒内实现。通过实验也证明了控制器跟踪刚度曲线随时间变化的能力。我们设想所提出的变刚度机械臂可以级联以适应三个冲击轴，用于构建多链接协作机械手。

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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2018 IEEE International Conference on Robotics and Biomimetics (ROBIO)

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