Wide-range sensitive all-textile piezoresistive sensors assembled with biomimetic core-shell yarn via facile embroidery integration

Wide-range sensitive all-textile piezoresistive sensors assembled with biomimetic core-shell yarn via facile embroidery integration

[Display omitted] •A wide-range sensitive biomimetic piezoresistive pressure sensor was designed.•The BBC structures enhanced the working range, sensitivity and signal consistency.•A sensors array with expected resolution was integrated via facile embroidery.•The sensor shows a working range of ∼25 ...

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Bibliographic Details
Published in:Chemical engineering journal (Lausanne, Switzerland : 1996) Switzerland : 1996), 2022-05, Vol.435, p.135003, Article 135003
Main Authors: Ke, Yiming, Jia, Kangyu, Zhong, Weibing, Ming, Xiaojuan, Jiang, Haiqing, Chen, Jiahui, Ding, Xincheng, Li, Mufang, Lu, Zhentan, Wang, Dong
Format: Article
Language:eng
Subjects:
BBC structure
Biomimetic core–shell yarn
Embroidery technique
Pressure sensors
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Summary:[Display omitted] •A wide-range sensitive biomimetic piezoresistive pressure sensor was designed.•The BBC structures enhanced the working range, sensitivity and signal consistency.•A sensors array with expected resolution was integrated via facile embroidery.•The sensor shows a working range of ∼25 N and a sensitivity of ∼5.15 N−1.•The sensor has a huge potential in various wearable scenarios. Emerging of flexible high-performance pressure sensor has recently led to the development and flourish of wearable intelligent systems. However, a recurring challenge restricting the performances and large-scale applications is the incorporation of high flexibility, wide working pressure range, and facile integration into flexible pressure sensor. In this paper, cytoskeleton-inspired core–shell yarns (CCSY), containing internal silver-plated nylon electrode and external sensing layer with bridge-binder cell (BBC) structures, have been prepared by a modified immersing coating process. Due to the great flexibility and knittability of CCSY, integrated sensors array, as well as pressure sensors, has been inserted into traditional textiles with expected location and resolution via a facile embroidery technique. The obtained pressure sensor shows a wide working pressure range (up to 25 N, ∼148.017 MPa), a high sensitivity (up to 5.15 N−1) and a short response time (∼11.2 ms) with the help of BBC structures. Moreover, the pressure sensor can monitor physiological signals of human body accurately and swiftly, such as pulses, joints movements, and plantar pressure. The scalable and high-performance CCSY-based pressure sensors pave a pass for the next generation wearable intelligent system, fulfilling the sophisticated demands of intelligent life, personalized health care and human–machine interface.
ISSN:1385-8947
1873-3212