4.7 Article

Heterogeneous carbon/silicone composite for ultrasensitive anisotropic strain sensor with loading-direction-perception capability

Journal

COMPOSITES SCIENCE AND TECHNOLOGY
Volume 227, Issue -, Pages -

Publisher

ELSEVIER SCI LTD
DOI: 10.1016/j.compscitech.2022.109565

Keywords

P iezo-resistive nanocomposite; Anisotropic strain sensor; Heterogeneous structure; Strain concentration; Sensitivity

Funding

  1. National Natural Science Foundation of China [51803016, U1837204]
  2. Competitive Internal Research Award of Khalifa University [CIRA-2018-16]

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This study demonstrates an ultrasensitive anisotropic strain sensor for loading direction perception. The sensor, composed of orthogonal heterogeneous piezo-resistive composite (HePC) and homogenous piezo-resistive composite (HoPC), shows high sensitivity and directional sensitivity differences, making it effective for distinguishing strain magnitude and direction, as well as monitoring human body gestures.
Anisotropic strain sensors are crucial to accurately detecting the complex strain states in wearable devices and robotics. Large directional sensitivity differences are the key for strain sensors to differentiate loading directions. Here, an ultrasensitive anisotropic strain sensor consisting of orthogonal heterogeneous piezo-resistive composite (HePC) and homogenous piezo-resistive composite (HoPC) is demonstrated for loading direction perception. Benefited by a unique stiff-soft-stiff segment structure design, the HePCs with ultrahigh strain sensitivity were fabricated with carbon black (CB)/silicone nanocomposite with a low Young's modulus as the soft segment (SoS) and carbon-fiber-reinforced CB/silicone nanocomposite with a high Young's modulus as the stiff segment (StS). The HePC with a length ratio (LStS/LSoS) of 14:1 offers an average gauge factor of 70 (epsilon < 1%), which is increased more than 60 times than that of HoPC, due to the strain concentration effect in the SoS of HePC. Moreover, the anisotropic strain sensor fabricated demonstrates significant directional sensitivity differences due to the heterogeneous structure, and their relative resistance changes (RCR) vary considerably from positive to negative upon the change of loading directions. This makes the sensor highly effective to distinguish strain magnitude and direction simultaneously, and succeeding in monitoring complex human body gestures. Meanwhile, the relation between the loading direction and the measured parameter K (RCR in X-direction over that in Y-direction) is proposed to predict the loading angle. Considering its ultrahigh sensitivity and loading-direction-perception capability, the anisotropic strain sensor with the heterogeneous structure of stiff-soft-stiff segments is promising in wearable devices, robotic systems, artificial intelligence, etc.

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