Controllable structure design for highly efficient and low cost fabrication of graphite based stretchable strain sensors

Translational Materials Research Pub Date : 2018-10-24 DOI:10.1088/2053-1613/AAE715

Chaoyong Zhou, Zhikang Zeng, Wen Li, Q. Yu, Desmond C Klerk, Baoyang Lu, Yan Yu

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引用次数: 1

Abstract

Detecting dynamic multi-scale human motion requires the stretchable strain sensor to possess outstanding properties in every aspect. Unlike conventional strain sensors which focus on changing conductive materials and preparing methods, we introduce a novel mechanical structure design to control the performance of the strain sensor. The performance of the device can be simply controlled by the structural design rather than complex materials adjustments. So the complexity of the material preparation will be greatly reduced, thus promotes the materials translation and production. By designing an asymmetric structure of elastomer substrate and protect layer with different adjustable parameters, the strain distribution in elastomer can be controlled, which finally change the performance of strain sensors. The experiment results illustrated our works on changing the stretchablity and sensitivity of the strain sensors. Application tests on human body including subtle-scale strain like pulse and large-scale strain like elbow bending are conducted to prove our capability for multi-scale motion detecting.

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高效低成本石墨基可拉伸应变传感器的可控结构设计

检测动态多尺度人体运动要求可拉伸应变传感器在各个方面都具有优异的性能。与传统应变传感器关注于改变导电材料和制备方法不同，我们引入了一种新的机械结构设计来控制应变传感器的性能。该装置的性能可以简单地通过结构设计来控制，而不需要复杂的材料调整。因此，材料制备的复杂性将大大降低，从而促进了材料的翻译和生产。通过设计具有不同可调参数的弹性体衬底和保护层的非对称结构，可以控制弹性体内部的应变分布，从而改变应变传感器的性能。实验结果说明了我们在改变应变传感器的拉伸性和灵敏度方面所做的工作。在人体上进行了脉动等小尺度应变和弯头弯曲等大尺度应变的应用试验，验证了我们的多尺度运动检测能力。

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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Translational Materials Research

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