Research on Mechanical Leg Structure Design and Control System of Lower Limb Exoskeleton Rehabilitation Robot Based on Magnetorheological Variable Stiffness and Damping Actuator

Chenglong Zhao; Zhen Liu; Chongsong Zheng; Liucun Zhu; Yuefei Wang

doi:10.3390/act13040132

Actuators (Apr 2024)

Research on Mechanical Leg Structure Design and Control System of Lower Limb Exoskeleton Rehabilitation Robot Based on Magnetorheological Variable Stiffness and Damping Actuator

Chenglong Zhao,
Zhen Liu,
Chongsong Zheng,
Liucun Zhu,
Yuefei Wang

Affiliations

Chenglong Zhao: School of Mechanical and Marine Engineering, Beibu Gulf University, Qinzhou 535011, China
Zhen Liu: Department of Integrated Systems Engineering, Nagasaki Institute of Applied Science, Nagasaki 851-0193, Japan
Chongsong Zheng: CATARC (Tianjin) Automotive Engineering Research Institute Co., Ltd., Tianjin 300300, China
Liucun Zhu: Advanced Science and Technology Research Institute, Beibu Gulf University, Qinzhou 535001, China
Yuefei Wang: School of Mechanical and Marine Engineering, Beibu Gulf University, Qinzhou 535011, China

DOI: https://doi.org/10.3390/act13040132
Journal volume & issue: Vol. 13, no. 4
p. 132

Abstract

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During the walking process of lower limb exoskeleton rehabilitation robots, inevitable collision impacts will occur when the swinging leg lands on the ground. The impact reaction force from the ground will induce vibrations in the entire robot’s body from bottom to top. To address this phenomenon, considering the limitations of traditional active compliance and passive compliance methods, a variable stiffness and damping actuator (VSDA) leg structure using a magnetorheological damper (MRD) is proposed. Firstly, experimental methods are used to obtain the ground reaction force (GRF) exerted on a normal person during walking. Then, a mathematical model of the VSDA leg structure is constructed, and its working principle is analyzed. Based on human mass and dimensions, a 3D model is designed and selected. Finally, a simulation model is built in the MATLAB/Simulink environment using the fuzzy switch damping control strategy to simulate the acceleration and displacement of the human body under sinusoidal and random excitations. The results indicate that under sinusoidal excitation, employing fuzzy switch damping control optimizes human displacement by 72.47% compared to the high stiffness and high damping system, and by 16.95% compared to the switch damping system. Human acceleration is optimized by 52.09% compared to the high stiffness and high damping system, and by 25.2% compared to the switch damping system. Under random excitation, adopting fuzzy switch damping control optimizes human displacement by 59.09% compared to the high stiffness and high damping system, and by 21.74% compared to the switch damping system. Human acceleration is optimized by 78.74% compared to the high stiffness and high damping system, and by 31.66% compared to the switch damping system. This validates the VSDA design structure and control method, demonstrating certain advantages in improving the compliance and stability of lower limb exoskeleton rehabilitation robots.

Published in Actuators

ISSN: 2076-0825 (Online)
Publisher: MDPI AG
Country of publisher: Switzerland
LCC subjects: Technology: Electrical engineering. Electronics. Nuclear engineering: Materials of engineering and construction. Mechanics of materials; Technology: Electrical engineering. Electronics. Nuclear engineering: Production of electric energy or power. Powerplants. Central stations
Website: http://www.mdpi.com/journal/actuators

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