Bistable soft jumper capable of fast response and high takeoff velocity

跳跃的 跳跃者 双稳态 起飞 工程类 模拟 机器人 控制理论(社会学) 计算机科学 材料科学 电子工程 航空航天工程 人工智能 光电子学 生理学 控制(管理) 生物
作者
Daofan Tang,Chengqian Zhang,Chengfeng Pan,Hao Hu,Haonan Sun,Huangzhe Dai,Jianzhong Fu,Carmel Majidi,Peng Zhao
出处
期刊:Science robotics [American Association for the Advancement of Science]
卷期号:9 (93): eadm8484-eadm8484 被引量:72
标识
DOI:10.1126/scirobotics.adm8484
摘要

In contrast with jumping robots made from rigid materials, soft jumpers composed of compliant and elastically deformable materials exhibit superior impact resistance and mechanically robust functionality. However, recent efforts to create stimuli-responsive jumpers from soft materials were limited in their response speed, takeoff velocity, and travel distance. Here, we report a magnetic-driven, ultrafast bistable soft jumper that exhibits good jumping capability (jumping more than 108 body heights with a takeoff velocity of more than 2 meters per second) and fast response time (less than 15 milliseconds) compared with previous soft jumping robots. The snap-through transitions between bistable states form a repeatable loop that harnesses the ultrafast release of stored elastic energy. On the basis of the dynamic analysis, the multimodal locomotion of the bistable soft jumper can be realized: the interwell mode of jumping and the intrawell mode of hopping. These modes are controlled by adjusting the duration and strength of the magnetic field, which endows the bistable soft jumper with robust locomotion capabilities. In addition, it is capable of jumping omnidirectionally with tunable heights and distances. To demonstrate its capability in complex environments, a realistic pipeline with amphibious terrain was established. The jumper successfully finished a simulative task of cleansing water through a pipeline. The design principle and actuating mechanism of the bistable soft jumper can be further extended for other flexible systems.
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