壁虎
抓住
机械手
胶粘剂
计算机科学
人机交互
人工智能
材料科学
纳米技术
地质学
图层(电子)
程序设计语言
古生物学
作者
Hao Jiang,Elliot W. Hawkes,Christine Fuller,Matthew A. Estrada,Srinivasan A. Suresh,Neil Abcouwer,Amy Kyungwon Han,Shiquan Wang,Christopher J. Ploch,Aaron Parness,Mark R. Cutkosky
出处
期刊:Science robotics
[American Association for the Advancement of Science]
日期:2017-06-28
卷期号:2 (7)
被引量:316
标识
DOI:10.1126/scirobotics.aan4545
摘要
Grasping and manipulating uncooperative objects in space is an emerging challenge for robotic systems. Many traditional robotic grasping techniques used on Earth are infeasible in space. Vacuum grippers require an atmosphere, sticky attachments fail in the harsh environment of space, and handlike opposed grippers are not suited for large, smooth space debris. We present a robotic gripper that can gently grasp, manipulate, and release both flat and curved uncooperative objects as large as a meter in diameter while in microgravity. This is enabled by (i) space-qualified gecko-inspired dry adhesives that are selectively turned on and off by the application of shear forces, (ii) a load-sharing system that scales small patches of these adhesives to large areas, and (iii) a nonlinear passive wrist that is stiff during manipulation yet compliant when overloaded. We also introduce and experimentally verify a model for determining the force and moment limits of such an adhesive system. Tests in microgravity show that robotic grippers based on dry adhesion are a viable option for eliminating space debris in low Earth orbit and for enhancing missions in space.
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