Assessing the efficiency of exoskeletons in physical strain reduction by biomechanical simulation with AnyBody Modeling System.

IF 3.4 Q2 ENGINEERING, BIOMEDICAL Wearable technologies Pub Date : 2021-06-07 eCollection Date: 2021-01-01 DOI:10.1017/wtc.2021.5
Lars Fritzsche, Pavel E Galibarov, Christian Gärtner, Jonas Bornmann, Michael Damsgaard, Rudolf Wall, Benjamin Schirrmeister, Jose Gonzalez-Vargas, Daniele Pucci, Pauline Maurice, Serena Ivaldi, Jan Babič
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Abstract

Introduction: Recently, many industrial exoskeletons for supporting workers in heavy physical tasks have been developed. However, the efficiency of exoskeletons with regard to physical strain reduction has not been fully proved, yet. Several laboratory and field studies have been conducted, but still more data, that cannot be obtained solely by behavioral experiments, are needed to investigate effects on the human body.

Methods: This paper presents an approach to extend laboratory and field research with biomechanical simulations using the AnyBody Modeling System. Based on a dataset recorded in a laboratory experiment with 12 participants using the exoskeleton Paexo Shoulder in an overhead task, the same situation was reproduced in a virtual environment and analyzed with biomechanical simulation.

Results: Simulation results indicate that the exoskeleton substantially reduces muscle activity and joint reaction forces in relevant body areas. Deltoid muscle activity and glenohumeral joint forces in the shoulder were decreased between 54 and 87%. Simultanously, no increases of muscle activity and forces in other body areas were observed.

Discussion: This study demonstrates how a simulation framework could be used to evaluate changes in internal body loads as a result of wearing exoskeletons. Biomechanical simulation results widely agree with experimental measurements in the previous laboratory experiment and supplement such by providing an insight into effects on the human musculoskeletal system. They confirm that Paexo Shoulder is an effective device to reduce physical strain in overhead tasks. The framework can be extended with further parameters, allowing investigations for product design and evaluation.

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基于任何人建模系统的生物力学模拟评估外骨骼的物理应变降低效率
摘要简介最近,许多用于支持工人完成繁重体力任务的工业外骨骼已经被开发出来。然而,外骨骼在减少物理应变方面的效率尚未得到充分证明。已经进行了几项实验室和实地研究,但还需要更多的数据来研究对人体的影响,这些数据不能仅仅通过行为实验获得。方法本文提出了一种使用AnyBody建模系统扩展生物力学模拟的实验室和现场研究的方法。基于一项实验室实验中记录的数据集,12名参与者在头顶任务中使用外骨骼Paexo肩部,在虚拟环境中再现了相同的情况,并通过生物力学模拟进行了分析。结果仿真结果表明,外骨骼显著降低了相关身体区域的肌肉活动和关节反作用力。肩部的三角肌活动和肩关节力降低了54%至87%。同时,没有观察到其他身体区域的肌肉活动和力量增加。讨论本研究展示了如何使用模拟框架来评估佩戴外骨骼后体内负荷的变化。生物力学模拟结果与先前实验室实验中的实验测量结果广泛一致,并通过深入了解对人类肌肉骨骼系统的影响来补充这一点。他们证实,Paexo肩扛是一种有效的设备,可以减少头顶任务中的身体压力。该框架可以通过进一步的参数进行扩展,允许对产品设计和评估进行调查。
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CiteScore
5.80
自引率
0.00%
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0
审稿时长
11 weeks
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