双侧、失调补偿、全自由度髋关节外骨骼：设计与运动学验证

Bilateral, Misalignment-Compensating, Full-DOF Hip Exoskeleton: Design and Kinematic Validation.

作者信息

Junius Karen, Degelaen Marc, Lefeber Nina, Swinnen Eva, Vanderborght Bram, Lefeber Dirk

机构信息

Department of Mechanical Engineering and Flanders Make, Vrije Universiteit Brussel (VUB), Pleinlaan 2, 1050 Brussels, Belgium.

Department of Physical Education and Physiotherapy Rehabilitation Research, Vrije Universiteit Brussel (VUB), Laarbeeklaan 103, 1090 Brussels, Belgium.

出版信息

Appl Bionics Biomech. 2017;2017:5813154. doi: 10.1155/2017/5813154. Epub 2017 Jul 16.

DOI:10.1155/2017/5813154

PMID:28790799

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC5534269/

Abstract

A shared design goal for most robotic lower limb exoskeletons is to reduce the metabolic cost of locomotion for the user. Despite this, only a limited amount of devices was able to actually reduce user metabolic consumption. Preservation of the natural motion kinematics was defined as an important requirement for a device to be metabolically beneficial. This requires the inclusion of all human degrees of freedom (DOF) in a design, as well as perfect alignment of the rotation axes. As perfect alignment is impossible, compensation for misalignment effects should be provided. A misalignment compensation mechanism for a 3-DOF system is presented in this paper. It is validated by the implementation in a bilateral hip exoskeleton, resulting in a compact and lightweight device that can be donned fast and autonomously, with a minimum of required adaptations. Extensive testing of the prototype has shown that hip range of motion of the user is maintained while wearing the device and this for all three hip DOFs. This allowed the users to maintain their natural motion patterns when they are walking with the novel hip exoskeleton.

摘要

大多数机器人下肢外骨骼的一个共同设计目标是降低用户的运动代谢成本。尽管如此，只有有限数量的设备能够实际降低用户的代谢消耗。保持自然运动运动学被定义为设备在代谢方面有益的一项重要要求。这需要在设计中纳入所有人体自由度（DOF），以及旋转轴的完美对齐。由于完美对齐是不可能的，因此应提供对未对准影响的补偿。本文提出了一种用于三自由度系统的未对准补偿机制。通过在双边髋关节外骨骼中的实施对其进行了验证，从而得到了一种紧凑、轻便的设备，该设备可以快速、自主地穿戴，所需调整最少。对该原型的广泛测试表明，用户在佩戴该设备时，其髋关节的运动范围在所有三个髋关节自由度上均得以保持。这使得用户在使用新型髋关节外骨骼行走时能够保持其自然运动模式。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/ad0a/5534269/0b0365024c69/ABB2017-5813154.001.jpg

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双侧、失调补偿、全自由度髋关节外骨骼：设计与运动学验证

Bilateral, Misalignment-Compensating, Full-DOF Hip Exoskeleton: Design and Kinematic Validation.

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