Zheng Qiwei, Xin Liming, Zhang Qin, Shen Fan, Lu Xiao, Cao Chen, Xin Chuanfu, Zhao Yang, Liu Heming, Peng Yan, Luo Jun, Guo Hengyu, Li Zhongjie
School of Mechatronic Engineering and Automation, Shanghai University, Shanghai, 200444, P. R. China.
School of Computer Engineering and Science, Shanghai University, Shanghai, 200444, P. R. China.
Adv Mater. 2025 Feb;37(8):e2417380. doi: 10.1002/adma.202417380. Epub 2025 Jan 7.
Leech locomotion, characterized by alternating sucker attachment and body contraction provides high adaptability and stability on complex terrains. Herein, a leech-inspired triboelectric soft robot is proposed for the first time, capable of amphibious movement, climbing, and load-carrying crawling. A high-performance triboelectric bionic robot system is developed to drive and control electro-responsive soft robots. Its core components include: i) a leech-inspired soft robot (LSR) made from segmented dielectric elastomer muscles. ii) The triboelectric sucker produces anisotropic frictional forces. iii) The multi-channel high-voltage output triboelectric nanogenerator (HDC-TENG) effectively drives the LSR. iv) The high-voltage triboelectric control unit adapted for the HDC-TENG enables flexible LSR control. Using the scalable structure of the dielectric elastomer muscles enables the LSR to achieve a maximum crawling speed of 0.39 body lengths per minute on land (45 mm min) and 0.22 body lengths per minute in liquid (30.5 mm min). It can also carry a payload of 11.55 grams on acrylic while crawling. This research provides a sustainable and promising new solution for self-powered high-voltage energy sources suitable for electro-responsive soft robots.
水蛭的运动以交替的吸盘附着和身体收缩为特征,在复杂地形上具有很高的适应性和稳定性。在此,首次提出了一种受水蛭启发的摩擦电软机器人,它能够进行两栖运动、攀爬和负重爬行。开发了一种高性能的摩擦电仿生机器人系统来驱动和控制电响应软机器人。其核心组件包括:i)由分段介电弹性体肌肉制成的受水蛭启发的软机器人(LSR)。ii)摩擦电吸盘产生各向异性摩擦力。iii)多通道高压输出摩擦纳米发电机(HDC-TENG)有效驱动LSR。iv)适用于HDC-TENG的高压摩擦电控制单元实现了对LSR的灵活控制。利用介电弹性体肌肉的可扩展结构,LSR在陆地上的最大爬行速度可达每分钟0.39个身体长度(45毫米/分钟),在液体中为每分钟0.22个身体长度(30.5毫米/分钟)。它在爬行时还能在丙烯酸树脂上承载11.55克的负载。这项研究为适用于电响应软机器人的自供电高压能源提供了一种可持续且有前景的新解决方案。
