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Journal article
A Novel Variable Stiffness Compliant Robotic Link Based on Discrete Variable Stiffness Units for Safe Human-Robot Interaction
Journal of mechanisms and robotics, Vol.16(1), 014501
01/01/2024
Web of Science ID: WOS:001116555700011
Abstract
Variable stiffness manipulators balance the trade-off between manipulation performance needing high stiffness and safe human-robot interaction desiring low stiffness. Variable stiffness links enable this flexible manipulation function during human-robot interaction. In this paper, we propose a novel variable stiffness link based on discrete variable stiffness units (DSUs). A DSU is a parallel guided beam that can adjust stiffness discretely by changing the cross-sectional area properties of the hollow beam segments. The variable stiffness link (Tri-DSU) consists of three tandem DSUs to achieve eight stiffness modes and a stiffness ratio of 31. To optimize the design, stiffness analysis of the DSU and Tri-DSU under various configurations and forces was performed by a derived linear analytical model which applies to small/intermediate deflections. The model is derived using the approach of serially connected beams and superposition combinations. 3D-Printed prototypes were built to verify the feature and performance of the Tri-DSU in comparison with the finite element analysis and analytical model results. It's demonstrated that our model can accurately predict the stiffnesses of the DSU and Tri-DSU within a certain range of parameters. Impact tests were also conducted to validate the performance of the Tri-DSU. The developed method and analytical model are extendable to multiple DSUs with parameter configurations to achieve modularization and customization, and also provide a tool for the design of reconfigurable collaborative robot (cobot) manipulators.
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Details
- Title
- A Novel Variable Stiffness Compliant Robotic Link Based on Discrete Variable Stiffness Units for Safe Human-Robot Interaction
- Publication Details
- Journal of mechanisms and robotics, Vol.16(1), 014501
- Resource Type
- Journal article
- Publisher
- ASME
- Number of pages
- 8
- Grant note
- National Science Foundation (NSF) grant; National Science Foundation (NSF) FRR-2131711; CIRA-2020-024 / Khalifa University of Science, Technology and Research
- Copyright
- © ASME
- Identifiers
- WOS:001116555700011; 99380579793706600
- Academic Unit
- Mechanical Engineering; Hal Marcus College of Science and Engineering
- Language
- English