拍打
翼
航空航天工程
海洋工程
仿生学
无人机
比例(比率)
机器人
计算机科学
航空学
环境科学
工程类
人工智能
生物
地理
地图学
遗传学
作者
Yufeng Chen,Hongqiang Wang,E. Farrell Helbling,Noah T. Jafferis,Raphael Zufferey,Aaron Ong,Kevin Ma,Nicholas Gravish,Pakpong Chirarattananon,Mirko Kovač,Robert J. Wood
出处
期刊:Science robotics
[American Association for the Advancement of Science]
日期:2017-10-25
卷期号:2 (11)
被引量:283
标识
DOI:10.1126/scirobotics.aao5619
摘要
From millimeter-scale insects to meter-scale vertebrates, several animal species exhibit multimodal locomotive capabilities in aerial and aquatic environments. To develop robots capable of hybrid aerial and aquatic locomotion, we require versatile propulsive strategies that reconcile the different physical constraints of airborne and aquatic environments. Furthermore, transitioning between aerial and aquatic environments poses substantial challenges at the scale of microrobots, where interfacial surface tension can be substantial relative to the weight and forces produced by the animal/robot. We report the design and operation of an insect-scale robot capable of flying, swimming, and transitioning between air and water. This 175-milligram robot uses a multimodal flapping strategy to efficiently locomote in both fluids. Once the robot swims to the water surface, lightweight electrolytic plates produce oxyhydrogen from the surrounding water that is collected by a buoyancy chamber. Increased buoyancy force from this electrochemical reaction gradually pushes the wings out of the water while the robot maintains upright stability by exploiting surface tension. A sparker ignites the oxyhydrogen, and the robot impulsively takes off from the water surface. This work analyzes the dynamics of flapping locomotion in an aquatic environment, identifies the challenges and benefits of surface tension effects on microrobots, and further develops a suite of new mesoscale devices that culminate in a hybrid, aerial-aquatic microrobot.
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