Automated Fabrication of Tactile Sensors Using a Custom Additive Manufacturing Platform

2022 International Conference on Manipulation, Automation and Robotics at Small Scales (MARSS) Pub Date : 2022-07-25 DOI:10.1109/MARSS55884.2022.9870485

Danming Wei, Ruoshi Zhang, Ji-Tzuoh Lin, Dilan Ratnayake, Olalekan O. Olowo, Andrew S. Nimon, Moath H. A. Alqatamin, A. Sherehiy, D. Popa

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引用次数: 2

Abstract

This paper presents the NeXus, a precision robotic platform with additive manufacturing capabilities that can be used to prototype strain gauge-based tactile sensors – SkinCells - on flexible substrates. An Aerosol Inkjet printer was employed to print the strain gauge structure of the SkinCell sensor. The design of this sensor combines curvilinear geometries representing both a radial shape structure and an arc shape structure, which have opposite gauge responses when the force is applied to the center of the sensor. The fabrication process of the SkinCell sensor is predicated on a parametric kinematic calibration of the NeXus to identify features on the sensor substrate and align them to the printing and metrology tools. Several strain gauge SkinCell sensor samples were printed on pre-fabricated flexible substrates using the NeXus. Results indicate a calibration precision of approximately 170 microns with 60 microns line-width features. This precision is sufficient to ensure that all printed gauges are electrically connected to the pre-fabricated contacts.

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使用自定义增材制造平台的触觉传感器自动制造

本文介绍了NeXus，一种具有增材制造能力的精密机器人平台，可用于在柔性基板上制作基于应变计的触觉传感器- SkinCells的原型。采用气溶胶喷墨打印机打印SkinCell传感器的应变片结构。该传感器的设计结合了代表径向形状结构和弧形结构的曲线几何形状，当力施加到传感器的中心时，它们具有相反的测量响应。SkinCell传感器的制造过程基于NeXus的参数化运动学校准，以识别传感器基板上的特征，并将其与打印和计量工具对齐。使用NeXus将几个应变计SkinCell传感器样品打印在预制的柔性基板上。结果表明，校准精度约为170微米，线宽特征为60微米。这种精度足以确保所有印刷压力表都电连接到预制触点。

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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2022 International Conference on Manipulation, Automation and Robotics at Small Scales (MARSS)

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