用于定向压力检测的磁性毛发触觉传感器

IF 6.8 Q1 AUTOMATION & CONTROL SYSTEMS
Yuki A. Meier, Pierre Duhr, Marcel Mordarski, Céline Vergne, Erik Poloni, André R. Studart, Joris Pascal, Ahmet F. Demirörs
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引用次数: 0

摘要

人体的触觉感应是通过皮肤实现的。这启发了人们制造带有压力传感器的合成皮肤,并将其潜在应用于机器人、生物医学和人机界面。基于磁性元件的触觉传感器具有高灵敏度和宽动态范围的特点,因此前景广阔。然而,目前的磁性触觉传感器主要检测固体物体的压力,并在 100 mN 左右的相对较高压力下工作。本文通过制造柔软、可拉伸、永久磁化的毛发状结构来解决这些局限性,从而实现高分辨率、高性价比的压力传感。将这些毛发状结构与三维磁场测量技术的进步相结合,我们就能在没有固体接触的情况下监测定向触觉压力。为了证明这项技术的概念,我们制作了一个生物启发的软装置,它具有毛发结构,能感应和报告环境机械压力,类似于人体皮肤。软磁毛发结构的简单自组装使我们的方法易于大面积应用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Magnetic Hair Tactile Sensor for Directional Pressure Detection

Magnetic Hair Tactile Sensor for Directional Pressure Detection

Tactile sensing in the human body is achieved via the skin. This has inspired the fabrication of synthetic skins with pressure sensors for potential applications in robotics, bio-medicine, and human–machine interfaces. Tactile sensors based on magnetic elements are promising as they provide high sensitivity and a wide dynamic range. However, current magnetic tactile sensors mostly detect pressures of solid objects and operate at relatively high forces about 100 mN. Herein, these limitations are addressed by manufacturing soft, stretchable, and hair-like structures that are permanently magnetized to achieve high-resolution, cost-effective, and high-resolution pressure sensing. Combining these hair-like structures with advances in 3D magnetic-field measurements allows us to monitor directional tactile pressures without solid contact. To prove the concept of this technology, a bio-inspired soft device is built with a hairy structure that senses and reports environmental mechanical stresses, similar to that of human skin. Simple self-assembly of the soft magnetic hair structure makes our approach easy to scale for large-area applications.

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CiteScore
1.30
自引率
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