IEEE Trans Biomed Eng. 2018 Jun;65(6):1399-1409. doi: 10.1109/TBME.2017.2754922. Epub 2017 Sep 20.
Show the benefit of kinematically compatible joint structures in exoskeletons for improving their performance in reducing metabolic consumption.
Subjects were fitted with a hip exoskeleton, with misalignment compensation for all degrees of freedom and were instructed to perform recurring sit-to-stand motions for 5 min. This was executed three times: Unequipped (i.e., not wearing the exoskeleton), assisted, and unassisted. During each trial, oxygen consumption and muscle activity were monitored.
An increased oxygen consumption was observed between the unequipped and the unassisted trial. During the assisted trial, oxygen consumption was reduced to levels seen in the unequipped state. Muscle activity increased for rectus femoris and tibialis anterior and decreased for biceps femoris and gluteus maximus.
Oxygen consumption only increases in accordance with the added mass. No added penalty was seen related to increased inertia or hindrance of natural motion patterns. This indicates that the mechanism operates as intended. The increased muscle activity can be explained by the nature of the actuation system, which is not optimized for sit-to-stand tasks. A more targeted actuation system can easily reduce muscle activity, and therefore, induce a reduced oxygen consumption, below unequipped levels.
Because the benefits induced by using these systems are independent of user capabilities or deficiencies, it is applicable in a wide range of exoskeleton applications. The design presented here, allows for the realization of compact and light devices, that have a minimal impact on the metabolic cost of their user. This allows to maximally exploit the metabolically beneficial effects of a well-designed actuation system.
展示运动学兼容的关节结构在减少代谢消耗方面对提高外骨骼性能的益处。
将研究对象配备髋部外骨骼,所有自由度均具有对准补偿,并指导其执行 5 分钟的重复坐立运动。这分为三次执行:未配备(即不穿外骨骼)、辅助和无辅助。在每次试验中,监测氧气消耗和肌肉活动。
在未配备和无辅助试验之间观察到氧气消耗增加。在辅助试验期间,氧气消耗减少到未配备状态下的水平。股直肌和胫骨前肌的肌肉活动增加,而股二头肌和臀大肌的肌肉活动减少。
氧气消耗仅根据增加的质量而增加。没有看到与增加的惯性或自然运动模式的阻碍相关的额外惩罚。这表明该机制按预期运行。肌肉活动的增加可以通过驱动系统的性质来解释,该系统并非针对坐立任务进行优化。更有针对性的驱动系统可以轻松减少肌肉活动,从而降低氧气消耗,使其低于未配备状态的水平。
因为使用这些系统所带来的益处与用户的能力或缺陷无关,所以它适用于广泛的外骨骼应用。这里呈现的设计允许实现紧凑和轻便的设备,对用户的代谢成本影响最小。这使得能够最大限度地利用精心设计的驱动系统在代谢方面的有益效果。
