Wearable flexible strain sensor based on three-dimensional wavy laser-induced graphene and silicone rubber
Laser-induced graphene (LIG) has the advantages of one-step fabrication, prominent mechanical performance, as well as high conductivity; it acts as the ideal material to fabricate flexible strain sensors. In this study, a wearable flexible strain sensor consisting of three-dimensional (3D) wavy LIG...
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sg-ntu-dr.10356-1460552023-03-04T17:15:28Z Wearable flexible strain sensor based on three-dimensional wavy laser-induced graphene and silicone rubber Huang, Lixiong Wang, Han Wu, Peixuan Huang, Weimin Gao, Wei Fang, Feiyu Cai, Nian Chen, Rouxi Zhu, Ziming School of Mechanical and Aerospace Engineering Engineering::Mechanical engineering Flexible Strain Sensor Laser-induced Graphene Laser-induced graphene (LIG) has the advantages of one-step fabrication, prominent mechanical performance, as well as high conductivity; it acts as the ideal material to fabricate flexible strain sensors. In this study, a wearable flexible strain sensor consisting of three-dimensional (3D) wavy LIG and silicone rubber was reported. With a laser to scan on a polyimide film, 3D wavy LIG could be synthesized on the wavy surface of a mold. The wavy-LIG strain sensor was developed by transferring LIG to silicone rubber substrate and then packaging. For stress concentration, the ultimate strain primarily took place in the troughs of wavy LIG, resulting in higher sensitivity and less damage to LIG during stretching. As a result, the wavy-LIG strain sensor achieved high sensitivity (gauge factor was 37.8 in a range from 0% to 31.8%, better than the planar-LIG sensor), low hysteresis (1.39%) and wide working range (from 0% to 47.7%). The wavy-LIG strain sensor had a stable and rapid dynamic response; its reversibility and repeatability were demonstrated. After 5000 cycles, the signal peak varied by only 2.32%, demonstrating the long-term durability. Besides, its applications in detecting facial skin expansion, muscle movement, and joint movement, were discussed. It is considered a simple, efficient, and low-cost method to fabricate a flexible strain sensor with high sensitivity and structural robustness. Furthermore, the wavy-LIG strain senor can be developed into wearable sensing devices for virtual/augmented reality or electronic skin. Published version 2021-01-22T03:48:42Z 2021-01-22T03:48:42Z 2020 Journal Article Huang, L., Wang, H., Wu, P., Huang, W., Gao, W., Fang, F., . . . Zhu, Z. (2020). Wearable flexible strain sensor based on three-dimensional wavy laser-induced graphene and silicone rubber. Sensors, 20(15), 4266-. doi:10.3390/s20154266 1424-8220 https://hdl.handle.net/10356/146055 10.3390/s20154266 32751740 2-s2.0-85088901003 15 20 en Sensors © 2020 The Author(s). Licensee MDPI, Basel, Switzerland. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution(CC BY) license (http://creativecommons.org/licenses/by/4.0/). application/pdf |
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Engineering::Mechanical engineering Flexible Strain Sensor Laser-induced Graphene Huang, Lixiong Wang, Han Wu, Peixuan Huang, Weimin Gao, Wei Fang, Feiyu Cai, Nian Chen, Rouxi Zhu, Ziming Wearable flexible strain sensor based on three-dimensional wavy laser-induced graphene and silicone rubber |
| description |
Laser-induced graphene (LIG) has the advantages of one-step fabrication, prominent mechanical performance, as well as high conductivity; it acts as the ideal material to fabricate flexible strain sensors. In this study, a wearable flexible strain sensor consisting of three-dimensional (3D) wavy LIG and silicone rubber was reported. With a laser to scan on a polyimide film, 3D wavy LIG could be synthesized on the wavy surface of a mold. The wavy-LIG strain sensor was developed by transferring LIG to silicone rubber substrate and then packaging. For stress concentration, the ultimate strain primarily took place in the troughs of wavy LIG, resulting in higher sensitivity and less damage to LIG during stretching. As a result, the wavy-LIG strain sensor achieved high sensitivity (gauge factor was 37.8 in a range from 0% to 31.8%, better than the planar-LIG sensor), low hysteresis (1.39%) and wide working range (from 0% to 47.7%). The wavy-LIG strain sensor had a stable and rapid dynamic response; its reversibility and repeatability were demonstrated. After 5000 cycles, the signal peak varied by only 2.32%, demonstrating the long-term durability. Besides, its applications in detecting facial skin expansion, muscle movement, and joint movement, were discussed. It is considered a simple, efficient, and low-cost method to fabricate a flexible strain sensor with high sensitivity and structural robustness. Furthermore, the wavy-LIG strain senor can be developed into wearable sensing devices for virtual/augmented reality or electronic skin. |
| author2 |
School of Mechanical and Aerospace Engineering |
| author_facet |
School of Mechanical and Aerospace Engineering Huang, Lixiong Wang, Han Wu, Peixuan Huang, Weimin Gao, Wei Fang, Feiyu Cai, Nian Chen, Rouxi Zhu, Ziming |
| format |
Article |
| author |
Huang, Lixiong Wang, Han Wu, Peixuan Huang, Weimin Gao, Wei Fang, Feiyu Cai, Nian Chen, Rouxi Zhu, Ziming |
| author_sort |
Huang, Lixiong |
| title |
Wearable flexible strain sensor based on three-dimensional wavy laser-induced graphene and silicone rubber |
| title_short |
Wearable flexible strain sensor based on three-dimensional wavy laser-induced graphene and silicone rubber |
| title_full |
Wearable flexible strain sensor based on three-dimensional wavy laser-induced graphene and silicone rubber |
| title_fullStr |
Wearable flexible strain sensor based on three-dimensional wavy laser-induced graphene and silicone rubber |
| title_full_unstemmed |
Wearable flexible strain sensor based on three-dimensional wavy laser-induced graphene and silicone rubber |
| title_sort |
wearable flexible strain sensor based on three-dimensional wavy laser-induced graphene and silicone rubber |
| publishDate |
2021 |
| url |
https://hdl.handle.net/10356/146055 |
| _version_ |
1759856260606328832 |