Suzanne J Filius, Bas J van der Burgh, Jaap Harlaar
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引用次数: 0
摘要
为手臂肌肉严重无力的人提供电动手臂支撑需要精确补偿手臂重量和被动关节阻抗的升高(如肌肉萎缩和纤维化导致的关节僵硬)。在体内估算这些参数以及手臂的质心具有挑战性,而且人类对辅助功能的评估可能是主观的。为了解决这个问题,我们设计了一个假臂来复制人类手臂的人体测量学、自由度、可调节段质量和被动肘关节阻抗(eJimp)。本研究介绍了假臂的设计、人体测量和验证。它成功地模拟了人类手臂的运动范围、质量和质心。假臂还展示了复制各种 eJimp 扭矩-角度曲线的能力。此外,它还可以调整分段质量、质量中心和 eJimp,以匹配具有代表性的预期目标人群。事实证明,这种简单、经济高效的工具对于开发和验证电动手臂支撑或 "外骨骼"--Duchenne ARm ORthosis (DAROR)--非常有价值。这项研究包括对实际应用的建议,并提供了根据最终设计优化设计规格的见解。它是对 CAD 设计的补充,增强了假臂在未来手臂辅助设备中的应用。
The Design of the Dummy Arm: A Verification Tool for Arm Exoskeleton Development.
Motorised arm supports for individuals with severe arm muscle weakness require precise compensation for arm weight and elevated passive joint impedance (e.g., joint stiffness as a result of muscle atrophy and fibrosis). Estimating these parameters in vivo, along with the arm's centre of mass, is challenging, and human evaluations of assistance can be subjective. To address this, a dummy arm was designed to replicate the human arm's anthropometrics, degrees of freedom, adjustable segment masses, and passive elbow joint impedance (eJimp). This study presents the design, anthropometrics, and verification of the dummy arm. It successfully mimics the human arm's range of motion, mass, and centre of mass. The dummy arm also demonstrates the ability to replicate various eJimp torque-angle profiles. Additionally, it allows for the tuning of the segment masses, centres of mass, and eJimp to match a representative desired target population. This simple, cost-effective tool has proven valuable for the development and verification of the Duchenne ARm ORthosis (DAROR), a motorised arm support, or 'exoskeleton'. This study includes recommendations for practical applications and provides insights into optimising design specifications based on the final design. It supplements the CAD design, enhancing the dummy arm's application for future arm-assistive devices.