Wearable Strain Sensors with Aligned Macro Carbon Cracks Using a Two-Dimensional Triaxial-Braided Fabric Structure for Monitoring Human Health

ACS Appl Mater Interfaces. 2021 May 19;13(19):22926-22934. doi: 10.1021/acsami.1c01961. Epub 2021 May 7.

Abstract

Recently, wearable sensors, due to their ability to exhibit characteristics, have been appealing for health monitoring through detection of human motions and vital signals. The development of strain sensors with high sensing performance and wearability has been a great challenge to date. In this study, a textile-based strain sensor with good skin affinity was fabricated through a simple fabrication process of dip-coating 2D triaxial-braided fabrics using carbon ink and then drying. The macro crack aligned on the 2D triaxial-braided fabric with a high-density structure and good recovery force. The sensitivity of textile-based strain sensor can be enhanced due to aligned macro crack formed by prestrained fabricating process and characteristic of the 2D triaxial braided fabric with high dense structure. The optimized sensor exhibits high sensitivity (gauge factor: 128) in a strain range of 0-30%, durability (5000 cycles), washability, low hysteresis, and fast response time (90 ms). Therefore, it can be applied as a wearable sensor that can monitor human motions (large strain) and biosignals (subtle strain).

Keywords: dip-coating; macro crack; prestrain process; textile-based sensor; triaxial-braided fabric; wearable sensor.

MeSH terms

  • Carbon / chemistry*
  • Humans
  • Monitoring, Physiologic / instrumentation*
  • Textiles
  • Wearable Electronic Devices*

Substances

  • Carbon