Influence of varied assistance levels provided by a dual-joint active back-support exoskeleton on spinal musculoskeletal loading and kinematics during lifting.

IF 2 3区工程技术 Q3 ENGINEERING, INDUSTRIAL

Ergonomics Pub Date : 2025-02-18 DOI:10.1080/00140139.2025.2466030

Feng Hu, Niels P Brouwer, Ali Tabasi, Idsart Kingma, Wietse van Dijk, Mohamed Irfan Mohamed Refai, Herman van der Kooij, Jaap H van Dieën

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引用次数: 0

Abstract

An active dual-joint back-support exoskeleton with motors at both lumbar and hip level was designed to reduce spinal musculoskeletal loading and preserve lumbar flexibility during lifting. A subject-specific controller estimated the moment actively generated by back muscles to counteract gravitational forces on the upper body, minimising a counter-productive abdominal muscle contraction. Eight subjects lifted a 15 kg load using free technique with four assistance levels, i.e. 0%, 30%, 50%, and 70% of the active moment. Time-averaged L5S1 compressive force and back muscle active moment estimated by an EMG-driven biomechanical model, decreased by 5.5-9.3% and 14.9-28.6%, respectively, with non-zero assistance. Higher assistance did not yield larger L5S1 compression reduction but did gain further reduction in the time-averaged back muscles active moment. No significant changes in abdominal muscle activity and minor changes in lumbar flexion were observed suggesting the controller and dual-joint design achieved their objectives.

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双关节主动背部支撑外骨骼提供的不同辅助水平对举重过程中脊柱肌肉骨骼负荷和运动学的影响。

一种主动双关节背部支撑外骨骼，在腰椎和髋关节水平都有马达，旨在减少脊柱肌肉骨骼负荷，并在举重时保持腰椎灵活性。一名受试者专用的控制器估计背部肌肉主动产生的力矩，以抵消上半身的重力，最大限度地减少适得其反的腹肌收缩。8名受试者在活动力矩的0%、30%、50%和70%四个辅助水平下，使用自由技术举起15 kg的重物。在非零辅助下，肌电驱动生物力学模型估计的时间平均L5S1压缩力和背部肌肉活动矩分别下降了5.5-9.3%和14.9-28.6%。更高的辅助并没有产生更大的L5S1压缩减少，但确实进一步减少了时间平均背部肌肉活动力矩。腹肌活动无明显变化，腰椎屈曲有轻微变化，表明控制器和双关节设计达到了目的。

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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来源期刊

Ergonomics 工程技术-工程：工业

CiteScore

4.60

自引率

12.50%

发文量

147

审稿时长

6 months

期刊介绍： Ergonomics, also known as human factors, is the scientific discipline that seeks to understand and improve human interactions with products, equipment, environments and systems. Drawing upon human biology, psychology, engineering and design, Ergonomics aims to develop and apply knowledge and techniques to optimise system performance, whilst protecting the health, safety and well-being of individuals involved. The attention of ergonomics extends across work, leisure and other aspects of our daily lives. The journal Ergonomics is an international refereed publication, with a 60 year tradition of disseminating high quality research. Original submissions, both theoretical and applied, are invited from across the subject, including physical, cognitive, organisational and environmental ergonomics. Papers reporting the findings of research from cognate disciplines are also welcome, where these contribute to understanding equipment, tasks, jobs, systems and environments and the corresponding needs, abilities and limitations of people. All published research articles in this journal have undergone rigorous peer review, based on initial editor screening and anonymous refereeing by independent expert referees.