Research of Adhesion Mechanism in Space Climbing Robot On-Orbit Servicing for Spacecraft

doi:10.15982/j.issn.2095-7777.2017.03.015

PDF(20948 KB)

Journal of Deep Space Exploration ›› 2017, Vol. 4 ›› Issue (3) : 293-298. DOI: 10.15982/j.issn.2095-7777.2017.03.015

SU Yilin¹, HOU Xuyan¹, CAO Pan¹, XUE Pingping¹, TANG Tianfeng¹, LI Long², CHEN Tao³, JIANG Shengyuan¹

Author information +

History +

Abstract

According to the on-orbit servicing requirements of space cooperative target spacecraft，in order to expand the existing manipulator work space and its task function and provide support for the on-orbit control of the spacecraft，a new type of space climbing robot is proposed. The space climbing robot system consists of legs driven by piezoelectric，micro adhesive feet and other parts. The space climbing robot is composed of eight legs driven by piezoelectric which has three joints and five degrees of freedom. It can extend crossing obstacle ability by somersault based on the traditional way of climbing. The robot feet are designed in micro array structure that based on the bionics principle and reference the micro structure on feet of gecko，insects or other creatures. Based on the theory of interface micro mechanics and tribology，the contact mechanics model between micro structure of the adhesive feet and the surface of spacecraft is established. Then it analyzes its adhesive properties based on discrete element method. The simulation results demonstrate that using different ways of movement can achieve different adhesive ability of single seta，which provides theoretical support for achieving the robot foot adhesive and rapid stripping ability.

Keywords

bionic / microarray / discrete element method / adhesive force

Cite this article

EndNote

Ris (Procite)

Bibtex

Download citation ▾

SU Yilin, HOU Xuyan, CAO Pan, XUE Pingping, TANG Tianfeng, LI Long, CHEN Tao, JIANG Shengyuan. Research of Adhesion Mechanism in Space Climbing Robot On-Orbit Servicing for Spacecraft. Journal of Deep Space Exploration, 2017, 4(3): 293‒298 https://doi.org/10.15982/j.issn.2095-7777.2017.03.015

References

[1] Letschnik J,Walter U,Artigas J. On-orbit servicing[J]. Robotics & Automation Magazine IEEE,2009,16(4):29-33
[2] Flores-Abad A,Ma O,Pham K,et al. A review of space robotics technologies for on-orbit servicing[J]. Progress in Aerospace Sciences,2014,68(8):1-26
[3] 姜生元,沈毅,吴湘,等. 月面广义资源探测及其原位利用技术构想[J]. 深空探测学报,2015,2(4):291-301
Jiang S Y,Shen Y,Wu X,et al. Technical schemes of investigation and in-situ utilization for Lunar surface generalized resource[J]. Journal of Deep Space Exploration,2015,2(4):291-301
[4] Hirose S,Nagakubo A. Legged wall-climbing robot[J]. Journal of the Robotics Society of Japan,1992,10(5):575-580
[5] Longo D,Muscato G. A modular approach for the design of the Alicia climbing robot for industrial inspection[J]. Industrial Robot An International Journal,2004,31(2):148-158
[6] Grieco J C，Prieto M，Armada M，et al. A six-legged climbing robot for high payloads[C]//6th IEEE Conference on Control Applications. Trieste：IEEE，1998.
[7] Armada M，Gonzalez P，Nieto J，et al. On the design and control of a self-propelling robot for hazardous environments[C]//Proc. 21st Int. Symposium on Industrial Robots. Copenhagen：IFS Pub Ltd，1990.
[8] Armada M. Telepresence and intelligent control for a legged locomotion robot：in expert systems and robotics[M]. Berlin：Springer Verlag，2011.
[9] Autumn K,Gravish N. Gecko adhesion:evolutionary nanotechnology[J]. Philosophical Transactions of the Royal Society,2008,366(11):1575-1590
[10] Autumn K,Chang W P,Hsieh T,et al. Adhesion force of a single gecko foot-hair[J]. Nature,2000,405(8):681-684
[11] Autumn K,Sitti M,Liang Y A,et al. Evidence for van der waals adhesion in gecko setae[J]. PNAS,2002,991(19):12252-12256
[12] Gao H J,Wang X,Yao H M,et al. Mechanics of hierarchical adhesion structures of geckos[J]. Mechanics of Materials,2005,37(2):275-285