可穿戴外骨骼用天然橡胶管弹簧的能量密度和迟滞比较

J. Perry, Abhishek Rathod
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引用次数: 0

摘要

可穿戴外骨骼作为一种补偿丧失功能的手段,以及在日常任务中提供最大治疗效益的最佳辅助,显示出了希望。轻量级弹簧系统的开发,有效的存储和返回被认为是一个关键组成部分,在可穿戴外骨骼成功部署的个人神经缺陷。弹簧钢和天然橡胶都是储能中常用的材料,但在储能密度、储能效率和迟滞等指标上还没有直接的比较。在这项工作中,我们对不同钢丝直径的弹簧钢延伸弹簧和不同壁厚的天然橡胶管进行了循环加载试验。然后,我们使用测量的负载扩展曲线来说明和计算指标,以更好地量化每种材料的能量存储能力,以及它们在可穿戴机器人应用中作为能量存储和返回组件的适用性。结果表明,与钢弹簧相比,天然橡胶具有更高的单位重量储能能力。天然橡胶的迟滞也较高,在使用过程中,通过施加大于预期应变的适当预应变,可以显著减少迟滞。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Energy Density and Hysteresis Comparison in Natural Rubber Tube Springs for Wearable Exoskeleton Applications
Wearable exoskeletons show promise as a means for compensating lost function as well as for providing optimal assistance for maximal therapeutic benefit during everyday tasks. Development of lightweight spring systems for efficient storage and return are proposed as a key component in the successful deployment of wearable exoskeletons for individuals with neurological deficits. Both spring steel and natural rubber are common materials used in energy storage, but have not been directly compared by metrics such as energy storage density, energy storage efficiency, and hysteresis. In this work, we perform cyclic loading tests on spring steel extension springs of varying wire diameter and natural rubber tubing of varying wall thicknesses. We then use measured load-extension profiles to illustrate and compute metrics to better quantify the energy storing capabilities of each material and their appropriateness for use as energy storing and returning components in wearable robotic applications. Results show that natural rubber has a higher capacity for energy storage per unit weight in comparison to steel springs. Hysteresis is also higher in natural rubber and can be dramatically reduced by applying adequate pre-strain at levels greater than the anticipated strain during use.
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