MIT Media Lab, Massachusetts Institute of Technology, Cambridge, MA, USA.
J Neuroeng Rehabil. 2014 May 9;11:80. doi: 10.1186/1743-0003-11-80.
Many soldiers are expected to carry heavy loads over extended distances, often resulting in physical and mental fatigue. In this study, the design and testing of an autonomous leg exoskeleton is presented. The aim of the device is to reduce the energetic cost of loaded walking. In addition, we present the Augmentation Factor, a general framework of exoskeletal performance that unifies our results with the varying abilities of previously developed exoskeletons.
We developed an autonomous battery powered exoskeleton that is capable of providing substantial levels of positive mechanical power to the ankle during the push-off region of stance phase. We measured the metabolic energy consumption of seven subjects walking on a level treadmill at 1.5 m/s, while wearing a 23 kg vest.
During the push-off portion of the stance phase, the exoskeleton applied positive mechanical power with an average across the gait cycle equal to 23 ± 2 W (11.5 W per ankle). Use of the autonomous leg exoskeleton significantly reduced the metabolic cost of walking by 36 ± 12 W, which was an improvement of 8 ± 3% (p = 0.025) relative to the control condition of not wearing the exoskeleton.
In the design of leg exoskeletons, the results of this study highlight the importance of minimizing exoskeletal power dissipation and added limb mass, while providing substantial positive power during the walking gait cycle.
许多士兵需要携带重物行进很长的距离,这通常会导致身体和精神上的疲劳。在本研究中,我们设计并测试了一种自主式腿部外骨骼。该设备的目的是降低负重行走的能量消耗。此外,我们还提出了增强因子,这是一个外骨骼性能的通用框架,它将我们的结果与之前开发的不同能力的外骨骼统一起来。
我们开发了一种自主式电池供电的外骨骼,它能够在站立相的蹬离阶段向脚踝提供大量的正机械功率。我们测量了 7 名受试者在 1.5 m/s 的水平跑步机上行走时的代谢能量消耗,同时穿着 23 公斤的背心。
在站立相的蹬离阶段,外骨骼在整个步态周期内施加的平均正机械功率为 23 ± 2 W(每个脚踝 11.5 W)。使用自主式腿部外骨骼可使步行的代谢成本显著降低 36 ± 12 W,与不穿外骨骼的对照条件相比,改善了 8 ± 3%(p = 0.025)。
在腿部外骨骼的设计中,本研究的结果强调了最小化外骨骼功率损耗和附加肢体质量的重要性,同时在行走步态周期中提供大量的正功率。
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