OpenSEA: a 3D printed planetary gear series elastic actuator for a compliant elbow joint exoskeleton.

IF 2.9 Q2 ROBOTICS

Frontiers in Robotics and AI Pub Date : 2025-02-28 eCollection Date: 2025-01-01 DOI:10.3389/frobt.2025.1528266

Benjamin Jenks, Hailey Levan, Filip Stefanovic

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引用次数: 0

Abstract

Introduction: Next-generation assistive robotics rely on series elastic actuators (SEA) that enable compliant human-robot interaction. However, currently there is a deficiency of openly available SEA systems to support this development. To address this, we propose a novel design of a compliant 3D-printed SEA device for elbow movement rehabilitation exoskeletons that we make openly available.

Methods: We designed a 3D-printed SEA to incorporate a planetary gear system and torsional spring, offering compliance, adaptability, and cost-effectiveness. The design provides a high-power density, that can address torque limitations in 3D printed SEA systems. Our design utilizes a 4.12 Nm motor operating at 26 RPM based on assessment of functional performance differences across healthy and post-stroke individuals. Moreover, the design of this SEA allows for easily adjustable parameters to fit different joints, or various torque output configurations, in low-cost exoskeleton applications in rehabilitation.

Results: Testing demonstrated an average compliance contribution of the planetary gear and the average total system compliance of 14.80° and 22.22°, respectively. This range conforms to those expected in human-exoskeleton interaction. Similarly, an FEA analysis of the 3D printed system shows stress ranges of the SEA gears to be between 50 and 60.2 MPa, which causes a displacement of approximately 0.14 mm. This is within the operational flexural range of standard 3D printed materials such as PLA, which is 175 MPa.

Discussion: The study demonstrates an openly available SEA design for 3D printed exoskeletons. This work provides an entry point for accessible exoskeleton design, specifically for rehabilitation. Future work will explore the role of segment vs joint rigidity in developing next-generation compliant exoskeletons, and improving accessibility for personalizable assistive exoskeletons. All designs presented herein are publicly available.

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OpenSEA：用于柔性肘关节外骨骼的3D打印行星齿轮系列弹性驱动器。

下一代辅助机器人依靠串联弹性致动器（SEA）来实现人机交互。然而，目前缺乏公开可用的SEA系统来支持这种开发。为了解决这个问题，我们提出了一种新颖的设计，用于肘部运动康复外骨骼的兼容3d打印SEA设备，我们公开提供。方法：我们设计了一个3d打印的SEA，将行星齿轮系统和扭转弹簧结合在一起，具有顺应性、适应性和成本效益。该设计提供了高功率密度，可以解决3D打印SEA系统的扭矩限制。我们的设计采用4.12 Nm电机，转速为26 RPM，基于健康和中风后个体的功能表现差异评估。此外，SEA的设计允许轻松调整参数，以适应不同的关节或各种扭矩输出配置，在低成本的外骨骼康复应用中。结果：测试表明，行星齿轮的平均柔度贡献和平均总系统柔度分别为14.80°和22.22°。这个范围符合人类外骨骼相互作用的预期。同样，3D打印系统的有限元分析显示，SEA齿轮的应力范围在50到60.2 MPa之间，这导致了大约0.14 mm的位移。这是在标准3D打印材料（如PLA）的操作弯曲范围内，其为175 MPa。讨论：该研究展示了3D打印外骨骼的公开可用的SEA设计。这项工作为无障碍外骨骼设计提供了一个切入点，特别是用于康复。未来的工作将探索节段与关节刚度在开发下一代柔性外骨骼中的作用，并提高个性化辅助外骨骼的可及性。所有的设计都是公开的。

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

Frontiers in Robotics and AI ROBOTICS-

CiteScore

6.50

自引率

5.90%

发文量

355

审稿时长

14 weeks

期刊介绍： Frontiers in Robotics and AI publishes rigorously peer-reviewed research covering all theory and applications of robotics, technology, and artificial intelligence, from biomedical to space robotics.