A 2D lightweight instrumented wheel for assessing wheelchair functionality/activity.

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS ACS Applied Bio Materials Pub Date : 2023-01-01 DOI:10.1177/20556683231155198

Reto Togni, Manuel Müller, Stefan Plüss, William R Taylor, Roland Zemp

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引用次数: 1

Abstract

Introduction: Force measurement wheels are essential instruments for analysing manual wheelchair propulsion. Existing solutions are heavy and bulky, influence propulsion biomechanics, and are limited to confined laboratory environments. In this paper, a novel design for a compact and lightweight measurement wheel is presented and statically validated.

Methods: Four connectors between the push-rim and wheel-rim doubled as force sensors to allow the calculation of tangential and radial forces as well as the point of force application. For validation, increasing weights were hung on the push-rim at known positions. Resulting values were compared against pre-determined force components.

Results: The implemented prototype weighed 2.1 kg and was able to transmit signals to a mobile recording device at 140 Hz. Errors in forces at locations of propulsive pushes were in the range up to ±3.1 N but higher at the frontal extreme. Tangential force components were most accurate.

Conclusion: The principle of instrumenting the joints between push-rim and wheel-rim shows promise for assessing wheelchair propulsion in daily life.

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用于评估轮椅功能/活动的2D轻量级仪器轮。

力测轮是分析手动轮椅推进力的重要仪器。现有的解决方案既笨重又笨重，影响推进生物力学，而且仅限于受限的实验室环境。本文提出了一种新型的紧凑轻量化测量轮的设计方案，并进行了静态验证。方法:推轮辋和轮轮辋之间的四个连接件作为力传感器，可以计算切向和径向力以及施力点。为了验证，在已知位置将增加的重量挂在推环上。将结果值与预先确定的力分量进行比较。结果:实现的原型重2.1 kg，能够以140 Hz的频率向移动记录设备传输信号。推进力位置的力误差在±3.1牛的范围内，但在正面极端处更高。切向力分量最准确。结论:对轮椅推轮与轮轮之间关节进行检测的原理为日常生活中评估轮椅推进力提供了依据。

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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