Advanced Science (Jul 2020)

4D Printing Strain Self‐Sensing and Temperature Self‐Sensing Integrated Sensor–Actuator with Bioinspired Gradient Gaps

  • Daobing Chen,
  • Qingping Liu,
  • Zhiwu Han,
  • Junqiu Zhang,
  • HongLie Song,
  • Kejun Wang,
  • Zhengyi Song,
  • Shifeng Wen,
  • Yan Zhou,
  • Chunze Yan,
  • Yusheng Shi

DOI
https://doi.org/10.1002/advs.202000584
Journal volume & issue
Vol. 7, no. 13
pp. n/a – n/a

Abstract

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Abstract Integrated sensor–actuators with exciting functionalities, such as action self‐sensing, position self‐sensing, posture self‐sensing, or active sensing, are promising for applications in biomedical device, human–machine interaction, intelligent self‐protection devices, and humanoid robots. Despite recent progress, it remains challenging to achieve a macroscopical integrated sensor–actuator in a material system with microstructures. To address this critical challenge, a 4D printing bioinspired microstructure strategy is reported to design a high‐performance integrated sensor–actuator capable of simultaneous actuation and sensation. Decoupled thermal stimulation and strain sensation is achieved by combining nanocarbon black/polylactic acid composites with bioinspired gradient microgap structures. As a result, printed integrated sensor–actuators can actively touch objects triggered by thermal stimulation and self‐sense the touching state through the resistance change. It is anticipated that the basic design principle underlying this behavior can be used to develop integrated sensor–actuators of various shapes and functionalities to meet desirable applications.

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