Abstract
The series elastic actuators (SEAs) have been popularly applied to various robotic applications. The rigid actuator is vulnerable to applications where back drivability is required despite many automated assembly tasks requiring the function for enhanced robot operation. Since the SEA comprises only one stiffness, there is a limit to the usable application. Therefore, the variable stiffness actuator (VSA) with multiple stiffnesses is to be developed. This study aims to develop a linear multi-degree of freedom VSA. Instead of the conventional rotary-type VSA with one degree of freedom, we propose an actuator that can control stiffness with more than two degrees of freedom. The proposed VSA is advantageous for tasks such as screwing and deburring that require a change in stiffness depending on the circumstances. The mechanism is configured using a linear spring, and the stiffness is controlled by changing the tension spring to a nonlinear form. We also develop the new VSA through this mechanism and perform simulation analysis. In addition, the validity of the proposed VSA is verified through experiments by manufacturing a VSA based on the design.
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References
Braun DJ et al (2019) Variable stiffness spring actuators for low-energy-cost human augmentation. IEEE Trans Rob 35(6):1435–1449
Li X et al (2020a) Structure-controlled variable stiffness robotic joint based on multiple rotary flexure hinges. IEEE Trans Ind Electron 68(12):12452–12461
Li Z et al (2020b) Design, modeling and testing of a compact variable stiffness mechanism for exoskeletons. Mech Mach Theory 151:103905
Liu Y et al (2019) Design and analysis of spring parallel variable stiffness actuator based on antagonistic principle. Mech Mach Theory 140:44–58
Mengacci R et al (2021) Overcoming the torque/stiffness range tradeoff in antagonistic variable stiffness actuators. IEEE/ASME Trans Mechatron 26(6):3186–3197
Morrison T, Hai-Jun S (2020) Stiffness modeling of a variable stiffness compliant link. Mech Mach Theory 153:104021
Ning Y et al (2021) Design and implementation of a novel variable stiffness actuator with cam-based relocation mechanism. J Mech Robot 13(2):1–22
Paine N, Sehoon O, Sentis L (2013) Design and control considerations for high-performance series elastic actuators. IEEE/ASME Trans Mechatron 19(3):1080–1091
Tan DJ et al (2016) A 2-dof joint with coupled variable output stiffness. IEEE Robot Autom Lett 2(1):366–372
Visser LC, Carloni R, Stramigioli S (2011) Energy-efficient variable stiffness actuators. IEEE Trans Rob 27(5):865–875
Wang W, Zhao Y, Li Y (2018) Design and dynamic modeling of variable stiffness joint actuator based on Archimedes spiral. IEEE Access 6:43798–43807
Xiong J et al (2021) Design and experiment of a SMA-based continuous-stiffness-adjustment torsional elastic component for variable stiffness actuators. Smart Mater Struct 30(10):105021
Xu Y et al (2021a) Design, modeling and control of a reconfigurable variable stiffness actuator. Mech Syst Signal Process 160:107883
Xu Y et al (2021b) Design and analysis of a linear digital variable stiffness actuator. IEEE Access 9:13992–14004
Yang SK et al (2022) Design and analysis of a 2-DOF actuator with variable stiffness based on leaf springs. J Bionic Eng 19(5):1392–1404
Zhang T et al (2022) Design and validation of a lightweight hip exoskeleton driven by series elastic actuator with two-motor variable speed transmission. IEEE Trans Neural Syst Rehabil Eng 30:2456–2466
Zhu Y et al (2021) Design and evaluation of a novel torque-controllable variable stiffness actuator with reconfigurability. IEEE/ASME Trans Mechatron 27(1):292–303
Acknowledgements
This work was supported by the National Research Foundation of Korea(NRF) grant funded by the Korea government(MSIT) (No. RS-2023-00209266).
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Baek, J.M., Han, M.G. & Koo, J.C. Linear multi-degree of freedom variable stiffness actuator for robotic assembly tasks. Microsyst Technol 29, 1643–1649 (2023). https://doi.org/10.1007/s00542-023-05531-9
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DOI: https://doi.org/10.1007/s00542-023-05531-9