A Novel Underactuated Soft Humanoid Hand For Hand Sign Language

2019 IEEE International Instrumentation and Measurement Technology Conference (I2MTC) Pub Date : 2019-05-01 DOI:10.1109/I2MTC.2019.8827021

Mohamed E. M. Salem, Ruoshi Wen, Maggie Xu, Liu Yan, Ma Xiang, Qiang Wang

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引用次数: 6

Abstract

The human hand is a very complex mechanism which dealing with the external environment with a high range of degree of freedoms to allowing it to do a big variety of movements. Humanoid robotic hands are robotic hands that resemble human hands, especially with respect to their shape and their kinematic abilities. Recently, soft actuators are drawing attention in robotics field due to their high flexibility, lightness, ease of fabrication and its low cost. In this paper, we present a novel soft humanoid pneumatic hand which consists of nine soft bending actuators assembled together in one hand which can be matching the mobility of the human hand as closely as possible and verify this ability by using the hand sign language configurations. Direct 3D printing technique has been presented in the fabrication process of the soft pneumatic hand as a new technique by using a TPU 3D printer filament. Soft actuators characterization such as the bending performance is presented by using the advantage of ABAQUS/CAE software and experimental tests. All control actions were achieved by using Arduino Mega board supported with MATLAB SIMULINK model working with graphical user interface computer application (GUI).

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一种用于手势语的新型欠驱动柔性人形手

人的手是一个非常复杂的机械装置，它处理外部环境具有高度的自由度，使它能够做各种各样的运动。类人机械手是指在形状和运动能力方面与人手相似的机械手。近年来，软致动器以其高柔韧性、轻量化、易于制造和低成本等优点成为机器人领域的研究热点。本文提出了一种新型的柔性人形气动手，它由9个柔性弯曲致动器组合在一起，可以尽可能地匹配人手的移动能力，并通过手势语言配置验证了这种能力。直接3D打印技术作为一种新技术，利用TPU 3D打印长丝在柔性气动手的制造过程中被提出。利用ABAQUS/CAE软件的优势，结合实验测试，对软执行器的弯曲性能等进行了表征。所有的控制动作都是通过Arduino Mega板支持MATLAB SIMULINK模型和图形用户界面计算机应用程序(GUI)来实现的。

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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来源期刊

2019 IEEE International Instrumentation and Measurement Technology Conference (I2MTC)

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