Abstract
Transfemoral amputees (TAs) have difficulty in mobility during walking, such as restricted movement of lower extremity and body instability, yet few transfemoral prostheses have explored human-like multiple motion characteristics by simple structures to fit the kinesiology, biomechanics, and stability of human lower extremity. In this work, the configurations of transfemoral prosthetic mechanism are synthesized in terms of human lower-extremity kinesiology. A hybrid transfemoral prosthetic (HTP) mechanism with multigait functions is proposed to recover the gait functions of TAs. The kinematic and mechanical performances of the designed parallel mechanism are analyzed to verify their feasibility in transfemoral prosthetic mechanism. Inspired by motion—energy coupling relationship of the knee, a wearable energy-damper clutched device that can provide energy in knee stance flexion to facilitate the leg off from the ground and can impede the leg’s swing velocity for the next stance phase is proposed. Its co-operation with the springs in the prismatic pairs enables the prosthetic mechanism to have the energy recycling ability under the gait rhythm of the knee joint. Results demonstrate that the designed HTP mechanism can replace the motion functions of the knee and ankle to realize its multimode gait and effectively decrease the peak power of actuators from 94.74 to 137.05 W while maintaining a good mechanical adaptive stability.
Highlights
Nowadays, lower-extremity prostheses are increasingly used worldwide, especially for individuals after aboveknee amputation due to traffic accidents, diabetes mellitus, and dysvascular disease [1]
Transfemoral prosthetic configurations are synthesized based on the human lower-extremity kinesiology, and a series–parallel hybrid transfemoral prosthetic (HTP) mechanism, which is composed of an ankle–foot prosthetic mechanism and a Parallel mechanisms (PMs) of three-DoF rotation, is proposed
Lie group theory is adopted to synthesize the configurations of PM, and 2-UCU/RRR PM is determined for use in the proposed prosthetic mechanism
Summary
Lower-extremity prostheses are increasingly used worldwide, especially for individuals after aboveknee amputation due to traffic accidents, diabetes mellitus, and dysvascular disease [1]. Thanks to the continuous development of robot technology, powered lower limb robotic prostheses, have been extensively studied and manufactured for TAs in recent years. They can effectively resolve the shortcomings of traditional prostheses such as high metabolic consumption of the prosthetic wearers, high gait coordination error, poor wearability, and low degree of freedom. Sup et al [3] proposed a gait controller in a designed powered transfemoral prosthesis, which uses passive impedance to coordinate the prosthetic motion. This controller can improve the stability of TAs when wearing this prosthesis These prostheses can help TAs recover the human-like motion function of the
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