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Yin Zhang, Qiang Zhan The Capturing of Space Debris with a Spaceborne Multi-fingered Gripper

Аннотация: With the massive launching of spacecraft, more and more space debris are making the low Earth orbit (LEO) much more crowded which seriously affects the normal fl ight of other spacecrafts. Space debris removal has become a very urgent issue concerned by numerous countries. In this paper, using SwissCube as a target, the capturing of space debris with a spaceborne four-fi ngered gripper was studied in order to obtain the key factors that affect the capturing effect. The contact state between the gripper fi ngers and SwissCube was described using a defi ned contact matrix. The law of momentum conservation was used to model the motion variations of the gripper and SwissCube before and after the capturing process. A zero-gravity simulation environment was built using ADAMS software. Two typical kinds of capturing processes were simulated considering different stiffness of fi ngers and different friction conditions between fi ngers and SwissCube. Comparisons between results obtained with the law of momentum conservation and those from ADAMS simulation show that the theoretical calculations and simulation results are consistent. In addition, through analyzing the capturing process, a valuable fi nding was obtained that the contact friction and fi nger fl exibility are two very important factors that affect the capturing result.


Ключевые слова:

Robotics, Design and Development, Contact Friction, Flexibility, Capturing process, Multi-fi ngered Gripper, Space Debris, Virtual Prototype Development, Low Earth orbit, SwissCube.

Abstract: With the massive launching of spacecraft, more and more space debris are making the low Earth orbit (LEO) much more crowded which seriously affects the normal flight of other spacecrafts. Space debris removal has become a very urgent issue concerned by numerous countries. In this paper, using SwissCube as a target, the capturing of space debris with a spaceborne four-fingered gripper was studied in order to obtain the key factors that affect the capturing effect. The contact state between the gripper fingers and SwissCube was described using a defined contact matrix. The law of momentum conservation was used to model the motion variations of the gripper and SwissCube before and after the capturing process. A zero-gravity simulation environment was built using ADAMS software. Two typical kinds of capturing processes were simulated considering different stiffness of fingers and different friction conditions between fingers and SwissCube. Comparisons between results obtained with the law of momentum conservation and those from ADAMS simulation show that the theoretical calculations and simulation results are consistent. In addition, through analyzing the capturing process, a valuable finding was obtained that the contact friction and finger flexibility are two very important factors that affect the capturing result.


Keywords:

Robotics, Design and Development, Contact Friction, Flexibility, Capturing process, Multi-fingered Gripper, Space Debris, Virtual Prototype Development, Low Earth orbit, SwissCube


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Библиография
1. M.H. Shan, J. Guo and E. Gill, Review and comparison of active space debris capturing and removal methods, Prog Aerosp Sci. 80 (2016) 18-32.
2. J.-C. Liou, N.L. Johnson and N.M. Hill, Controlling the growth of future LEO debris populations with active debris removal, Acta Astronaut. 66 (2010) 648-653.
3. C. Bonnal, J.M. Ruault and M.C. Desjean, Active debris removal: recent progress and current trends, Acta Astronaut. 85 (2013) 51-60.
4. G. Creamer, The SUMO/FREND project: technology development for autonomous grapple of geosynchronous satellites, Adv Astronaut Sci. 128 (2007) 895-909.
5. T. Boge, T. Wimmer, O. Ma and M. Zebenay, EPOS-A robotics-based hardware-in-the-loop simulator for simulating satellite RvD operations. In: 10th International symposium on artificial intelligence, robotics and automation in space, Sapporo, Japan, 2010.
6. J.A.F. Deloo, Analysis of the rendezvous phase of e.Deorbit: guidance, communication and illumination. PhD Thesis, Delft University of Technology, NL, 2015.
7. S. Kawamoto, T. Makida, F. Sasaki, et al, Precise numerical simulations of electrodynamic tethers for an active debris removal system, Acta Astronaut. 59 (2006) 139-148.
8. C.R. Phipps, K.L. Baker, S.B. Libby, et al, Removing orbital debris with lasers, Adv Space Res. 49 (2012) 1283-1300.
9. M. Richard, L. Kronig, F. Belloni, et al, Uncooperative rendezvous and docking for MicroSats, In: 6th International conference on recent advances in space technologies, Istanbul, Türkiye, 12-14 June 2013.
10. O.A. Araromi, I. Gavrilovich, J. Shintake, et al, Rollable multisegment dielectric elastomer minimum energy structures for a deployable microsatellite gripper, IEEE/ASME Transactions on Mechatronics. 20 (2015) 438-446.
References
1. M.H. Shan, J. Guo and E. Gill, Review and comparison of active space debris capturing and removal methods, Prog Aerosp Sci. 80 (2016) 18-32.
2. J.-C. Liou, N.L. Johnson and N.M. Hill, Controlling the growth of future LEO debris populations with active debris removal, Acta Astronaut. 66 (2010) 648-653.
3. C. Bonnal, J.M. Ruault and M.C. Desjean, Active debris removal: recent progress and current trends, Acta Astronaut. 85 (2013) 51-60.
4. G. Creamer, The SUMO/FREND project: technology development for autonomous grapple of geosynchronous satellites, Adv Astronaut Sci. 128 (2007) 895-909.
5. T. Boge, T. Wimmer, O. Ma and M. Zebenay, EPOS-A robotics-based hardware-in-the-loop simulator for simulating satellite RvD operations. In: 10th International symposium on artificial intelligence, robotics and automation in space, Sapporo, Japan, 2010.
6. J.A.F. Deloo, Analysis of the rendezvous phase of e.Deorbit: guidance, communication and illumination. PhD Thesis, Delft University of Technology, NL, 2015.
7. S. Kawamoto, T. Makida, F. Sasaki, et al, Precise numerical simulations of electrodynamic tethers for an active debris removal system, Acta Astronaut. 59 (2006) 139-148.
8. C.R. Phipps, K.L. Baker, S.B. Libby, et al, Removing orbital debris with lasers, Adv Space Res. 49 (2012) 1283-1300.
9. M. Richard, L. Kronig, F. Belloni, et al, Uncooperative rendezvous and docking for MicroSats, In: 6th International conference on recent advances in space technologies, Istanbul, Türkiye, 12-14 June 2013.
10. O.A. Araromi, I. Gavrilovich, J. Shintake, et al, Rollable multisegment dielectric elastomer minimum energy structures for a deployable microsatellite gripper, IEEE/ASME Transactions on Mechatronics. 20 (2015) 438-446.