A Wearable Testbed for Studying Variable Transmission in Body-Powered Prosthetic Gripping.

Andrew I W McPherson, Michael E Abbott, Weston White, Yuri Gloumakov, Hannah S Stuart
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Abstract

For those with upper limb absence, body-powered prostheses continue to be popular for many activities despite being an old technology; these devices can provide both inherent haptic feedback and mechanical robustness. Yet, they can also result in strain and fatigue. Body-powered prosthetic graspers typically consist of a simple lever providing a relatively constant transmission ratio between the input forces from the user's shoulder harness and the grip force of their prosthetic prehensor. In the field of robotic hand design, new continuously varying transmissions demonstrate particular promise in generating a wide range of grasping speeds without sacrificing grip strength. These benefits, if applied to shoulder-driven prosthetic grippers, have the potential to both reduce shoulder exertion and fatigue. This work presents the integration of a continuously variable transmission into a body-powered, voluntary close prosthetic testbed. We introduce the design and validate its performance in a benchtop experiment. We compare constant transmission conditions with a force-dependent, continually varying condition. The device is mounted on a prosthetic emulator for a preliminary wearable demonstration.

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一种可穿戴试验台,用于研究人体动力假肢握持中的可变传动。
对于那些上肢缺失的人来说,尽管身体动力假肢是一项古老的技术,但在许多活动中仍然很受欢迎;这些设备可以提供固有的触觉反馈和机械鲁棒性。然而,它们也会导致紧张和疲劳。身体驱动的假肢抓握器通常由一个简单的杠杆组成,该杠杆在来自使用者肩带的输入力和其假肢预传感器的抓握力之间提供相对恒定的传递比。在机械手设计领域,新的连续变化变速器在不牺牲握力的情况下产生宽范围的握力速度方面表现出了特别的前景。如果将这些好处应用于肩部驱动的假肢夹,则有可能减少肩部用力和疲劳。这项工作提出了将无级变速器集成到一个身体驱动的、自愿的闭合假肢试验台中。我们介绍了该设计,并在台式实验中验证了其性能。我们将恒定传输条件与力相关、持续变化的条件进行比较。该设备安装在假肢模拟器上,用于初步的可穿戴演示。
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