用于多关节下肢辅助的软硬混合气动机电外骨骼

IF 3.4 Q2 ENGINEERING, BIOMEDICAL IEEE transactions on medical robotics and bionics Pub Date : 2024-07-01 DOI:10.1109/TMRB.2024.3421547
Luka Mišković;Enrica Tricomi;Xiaohui Zhang;Francesco Missiroli;Kristina Krstanović;Tadej Petrič;Lorenzo Masia
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引用次数: 0

摘要

人体增强通常采用硬质外骨骼或软质外衣。刚性外骨骼通过承重框架和直接的关节扭矩来增强稳定性和重量支撑。相反,没有刚性框架的软质外骨骼则利用近端定位的致动器和肌腱将力传递给固定在肢体上的纺织部件,从而提高适应性并简化机械结构。为了利用两者的优点,本研究介绍了一种多关节混合辅助装置,该装置结合了软质肌腱驱动的髋关节外骨骼和硬质气动膝关节外骨骼。髋关节有三个主动自由度,在摆动过程中由外骨骼辅助,以尽量减少运动限制、机械复杂性和重量。膝关节只有一个主动自由度,在站立期间由刚性膝关节外骨骼提供气动辅助,确保膝关节在负载响应期间的固有顺应性。该研究调查了混合系统在四种条件下(无辅助、髋关节辅助、膝关节辅助和混合辅助)对代谢成本、肌肉活动和运动学的影响,研究对象是在倾斜跑步机上(15°,3 公里/小时)的七名健康受试者。研究结果表明,混合助力能显著降低代谢成本,其次是髋关节助力和膝关节助力,助力肌肉的活动明显减少,对运动学的影响最小。
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Hybrid Rigid-Soft and Pneumatic-Electromechanical Exoskeleton for Multi-Joint Lower Limb Assistance
Human augmentation typically employs either rigid exoskeletons or soft exosuits. Rigid exoskeletons enhance stability and weight support through load-bearing frames and direct joint torque. Conversely, soft exosuits, devoid of rigid frames, utilize proximally positioned actuators and tendons to transmit forces to textile parts affixed to limbs, thereby enhancing adaptability and simplifying mechanics. To exploit the benefits of both, this study introduces a multi-joint hybrid-assisted device that combines a soft tendon-driven hip exosuit with a rigid pneumatic knee exoskeleton. The hip joint, featuring three active degrees of freedom, is assisted during the swing by the exosuit to minimize kinematic restrictions, mechanical complexity, and weight. The knee joint, with its single active degree of freedom, receives assistance during the stance from the rigid knee exoskeleton, pneumatically actuated, ensuring inherent knee compliance during load response. The study investigates the hybrid system’s impact on metabolic cost, muscle activity, and kinematics in four conditions (unassisted, hip-assisted, knee-assisted, and hybrid-assisted) with seven healthy subjects on an inclined treadmill (15° at 3 km/h). Findings indicate that hybrid assistance yields the greatest significant metabolic reductions, followed by hip assistance and knee-only assistance, with assisted muscles exhibiting significantly reduced activity and minimal impact on kinematics.
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2024 Index IEEE Transactions on Medical Robotics and Bionics Vol. 6 Table of Contents IEEE Transactions on Medical Robotics and Bionics Society Information Guest Editorial Special section on the Hamlyn Symposium 2023—Immersive Tech: The Future of Medicine IEEE Transactions on Medical Robotics and Bionics Publication Information
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