Kinematic analysis of the shoulder mechanism in able-bodied non-experienced manual wheelchair users

2016 International Conference for Students on Applied Engineering (ICSAE) Pub Date : 2016-10-01 DOI:10.1109/ICSAE.2016.7810204

Hassanain Ali Lafta, R. Guppy, G. Whatling, C. Holt

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Abstract

About 10% of the global population, i.e. about 650 million people, have disabilities [1]. Studies indicate that, of these, some 10% require a wheelchair. Manual wheelchair propulsion is an important form of mobility for those people to become productive members of their communities. The shoulder is a complex mechanism that plays an important role in manual wheelchair propulsion. Better knowledge of upper limb biomechanics during manual wheelchair propulsion can improve understanding of the resulted injuries and lead to improvements in propulsion efficiency. The primary purpose of this study is to investigate the simultaneous shoulder complex kinematics during functional manual wheelchair mobility. A protocol for three-dimensional kinematic measurements of the shoulder complex is presented using six degrees of freedom analysis. Each upper limb is treated as a four segments linked system that consists of trunk, upper arm, forearm and hand. Each segment is considered as a single rigid body. Selected temporal and kinematic parameters over the wheelchair stroke cycle are characterised in all three planes of motion.

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肢体健全的非经验轮椅使用者肩部机构的运动学分析

全球约有10%的人口，即约6.5亿人患有残疾[1]。研究表明，其中约10%的人需要轮椅。手动轮椅推进是这些人成为社区生产成员的重要移动形式。肩是一个复杂的机构，在手动轮椅的推进中起着重要的作用。在手动轮椅推进过程中，更好地了解上肢生物力学可以提高对所造成损伤的理解，从而提高推进效率。本研究的主要目的是探讨功能性手动轮椅移动时肩同时复杂运动学。采用六自由度分析提出了一种肩部复合体三维运动学测量方案。每个上肢被视为由躯干、上臂、前臂和手组成的四节相连系统。每个节段被认为是一个单一的刚体。选定的时间和运动学参数在轮椅行程周期的特点，在所有三个平面的运动。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2016 International Conference for Students on Applied Engineering (ICSAE)

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