Issue 10, 2022

A phonic Braille recognition system based on a self-powered sensor with self-healing ability, temperature resistance, and stretchability

Abstract

Braille recognition is of great significance for the visually impaired and blind people to achieve convenient communication and learning. A self-powered Braille recognition sensing system with long-term survivability and phonic function could provide those people with greatly enhanced access to information and thus improve their living quality. Herein, we develop a skin-like self-powered Braille recognition sensor with self-healing, temperature-resistant and stretchable properties, which is further connected with the designed audio system to realize real-time conversion from mechanical stimulus to electrical signals and then to audio signals. The sensor is fabricated using dynamic interaction-based self-healing materials, which constitute an imine bond-based cross-linked polymer for the triboelectric layer and a hydrogen bond-based organohydrogel for the electrode layer. Moreover, the conductive organohydrogel-based electrode is provided with stretchable, anti-freezing, and non-drying properties. Consequently, minimized impact on the output performance of the sensor is found under mechanical impact, harsh environments and large deformation, enabling a long lifespan, high durability, and good stability. The self-powered sensor can be applied in a Braille recognition system, in which the Braille characters can be further decoded and read out. This work shows a reliable and flexible device with promising prospects in information technology.

Graphical abstract: A phonic Braille recognition system based on a self-powered sensor with self-healing ability, temperature resistance, and stretchability

Supplementary files

Article information

Article type
Communication
Submitted
29 Apr 2022
Accepted
18 Jul 2022
First published
20 Jul 2022

Mater. Horiz., 2022,9, 2603-2612

A phonic Braille recognition system based on a self-powered sensor with self-healing ability, temperature resistance, and stretchability

X. Dai, L. Huang, Z. Sun, Y. Du, B. Xue, M. Wong, J. Han, Q. Liang, Y. Wu, B. Dong, J. Kong and J. Hao, Mater. Horiz., 2022, 9, 2603 DOI: 10.1039/D2MH00534D

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