TY - JOUR
T1 - Design, Analysis and Evaluation of the Hip-Driven Clutch-Type Elastic Actuator for Assisted Gait
AU - Yang, Yilin
AU - Chen, Hanyu
AU - Jia, Tianyu
AU - Ren, Weiyan
AU - Liu, Yali
AU - Ji, Linhong
AU - Guan, Xinyu
PY - 2025/7/1
Y1 - 2025/7/1
N2 - The reduction in muscle strength in the lower limbs of elderly individuals can affect their mobility and disrupt their daily routines. Exoskeletons could provide supportive torque and facilitate the elderly in resuming normal social activities. The ideal exoskeleton should provide sufficient walking torque and maintain good human-exoskeleton coupling. We proposed a clutch-type elastic actuator (CEA) based on a ratchet pawl mechanism as the hip joint actuator, which couples the elastic energy storage element with the motor and takes advantage of the long stance phase in the assisted gait. The actuator kinetic model was established for the swing and stance phase, and simulation and bench experiments were conducted to evaluate the performance of CEA. Compared with the rigid actuator(RA), the simulation results show that the CEA reduces the peak power by 56.56% and the average power by 64.22%, the bench test shows that the CEA reduces the peak power by 47.97% and the average power by 56.33%, providing a reference for the miniaturization and lightweight design of exoskeletons.
AB - The reduction in muscle strength in the lower limbs of elderly individuals can affect their mobility and disrupt their daily routines. Exoskeletons could provide supportive torque and facilitate the elderly in resuming normal social activities. The ideal exoskeleton should provide sufficient walking torque and maintain good human-exoskeleton coupling. We proposed a clutch-type elastic actuator (CEA) based on a ratchet pawl mechanism as the hip joint actuator, which couples the elastic energy storage element with the motor and takes advantage of the long stance phase in the assisted gait. The actuator kinetic model was established for the swing and stance phase, and simulation and bench experiments were conducted to evaluate the performance of CEA. Compared with the rigid actuator(RA), the simulation results show that the CEA reduces the peak power by 56.56% and the average power by 64.22%, the bench test shows that the CEA reduces the peak power by 47.97% and the average power by 56.33%, providing a reference for the miniaturization and lightweight design of exoskeletons.
UR - https://www.scopus.com/pages/publications/105023715753
U2 - 10.1109/EMBC58623.2025.11253007
DO - 10.1109/EMBC58623.2025.11253007
M3 - Article
C2 - 41336350
AN - SCOPUS:105023715753
SN - 2694-0604
VL - 2025
SP - 1
EP - 6
JO - Annual International Conference of the IEEE Engineering in Medicine and Biology Society. IEEE Engineering in Medicine and Biology Society. Annual International Conference
JF - Annual International Conference of the IEEE Engineering in Medicine and Biology Society. IEEE Engineering in Medicine and Biology Society. Annual International Conference
ER -