Nature Communications (Oct 2023)

Self-protection soft fluidic robots with rapid large-area self-healing capabilities

  • Wei Tang,
  • Yiding Zhong,
  • Huxiu Xu,
  • Kecheng Qin,
  • Xinyu Guo,
  • Yu Hu,
  • Pingan Zhu,
  • Yang Qu,
  • Dong Yan,
  • Zhaoyang Li,
  • Zhongdong Jiao,
  • Xujun Fan,
  • Huayong Yang,
  • Jun Zou

DOI
https://doi.org/10.1038/s41467-023-42214-5
Journal volume & issue
Vol. 14, no. 1
pp. 1 – 12

Abstract

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Abstract Soft fluidic robots have attracted a lot of attention and have broad application prospects. However, poor fluidic power source and easy to damage have been hindering their development, while the lack of intelligent self-protection also brings inconvenience to their applications. Here, we design diversified self-protection soft fluidic robots that integrate soft electrohydrodynamic pumps, actuators, healing electrofluids, and E-skins. We develop high-performance soft electrohydrodynamic pumps, enabling high-speed actuation and large deformation of untethered soft fluidic robots. A healing electrofluid that can form a self-healed film with excellent stretchability and strong adhesion is synthesized, which can achieve rapid and large-areas-damage self-healing of soft materials. We propose multi-functional E-skins to endow robots intelligence, making robots realize a series of self-protection behaviors. Moreover, our robots allow their functionality to be enhanced by the combination of electrodes or actuators. This design strategy enables soft fluidic robots to achieve their high-speed actuation and intelligent self-protection, opening a door for soft robots with physical intelligence.