用于减少肌肉活动和感知工作量的气动驱动柔性可穿戴机器人肘部外骨骼的设计、开发和评估。

IF 2 Q3 ENGINEERING, BIOMEDICAL

Journal of Rehabilitation and Assistive Technologies Engineering Pub Date : 2025-06-02 eCollection Date: 2025-01-01 DOI:10.1177/20556683251347517

Eshwara Prasad Sridhar, Veysel Erel, Aida Nasirian, Muthu B J Wijesundara, Mahmudur Rahman

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引用次数: 0

摘要

为了减少肌肉劳损，提高使用者的舒适度，开发了一种气动驱动的柔性可穿戴机器人肘部外骨骼。该设计将人体关节力学与单件气动结构相结合，以获得最佳辅助并降低复杂性。方法：19名被试分别在“支持开启”和“支持关闭”条件下完成任务，评估任务的有效性和可行性。肌肉活动通过表面肌电图测量，而扭矩输出和膨胀时间评估机械性能。结果：在18 PSI（磅/平方英寸）下，柔性可穿戴机器人肘部外骨骼使肱二头肌的肌肉活动减少22.36%，肱三头肌的肌肉活动减少18.19%。扭矩测试显示，在21 PSI时最大输出为4.39 Nm。膨胀时间测试表明，在25 PSI的高模式下，外骨骼可以在0.22秒内达到总膨胀，证明了实现快速驱动的能力。结论：这些结果表明，柔性可穿戴机器人肘部外骨骼可显著降低肌肉激活，这可能有助于降低与工作相关的肌肉骨骼疾病的风险。通过在重复性任务中提供有效的帮助，外骨骼增强了机械性能和用户舒适度。

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Design, development, and evaluation of a pneumatically actuated soft wearable robotic elbow exoskeleton for reducing muscle activity and perceived workload.

Introduction: To reduce muscle strain and enhance user comfort, a Pneumatically Actuated Soft Wearable Robotic Elbow Exoskeleton was developed. The design integrates human joint mechanics with a single-piece pneumatic structure for optimal assistance and reduced complexity.

Methods: Nineteen participants performed tasks under "Support On" and "Support Off" conditions to evaluate their effectiveness and feasibility. Muscle activity was measured using Surface Electromyography, while torque output and inflation times were assessed to gauge mechanical performance.

Results: The Soft Wearable Robotic Elbow Exoskeleton reduced muscle activity in the biceps by 22.36% and in the triceps by 18.19% at 18 PSI (Pounds per Square Inch). Torque tests revealed a maximum output of 4.39 Nm at 21 PSI. Inflation time tests showed that the exoskeleton could reach total inflation in as little as 0.22 seconds in high mode at 25 PSI, demonstrating the ability to achieve rapid actuation speed and efficiency.

Conclusions: These results indicate that the Soft Wearable Robotic Elbow Exoskeleton significantly reduces muscle activation, which may help mitigate the risk of work-related musculoskeletal disorders. By providing effective assistance during repetitive tasks, the exoskeleton enhances both mechanical performance and user comfort.

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来源期刊

Journal of Rehabilitation and Assistive Technologies Engineering ENGINEERING, BIOMEDICAL-

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5.00%

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