TECHNICAL MECHANICS
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UDC 629.78

Technical mechanics, 2023, 3, 110 - 123

REVIEW OF METHODS AND MEANS FOR SPACE DEBRIS REMOVAL FROM LOW-EARTH ORBITS

DOI: https://doi.org/10.15407/itm2023.03.110

Svorobin D. S.

Svorobin D. S.
Institute of Technical Mechanics of the National Academy of Sciences of Ukraine and the State Space Agency of Ukraine

      The importance of the space debris problem in the today’s world is generally recognized. The number of space debris objects in near-Earth space is rapidly growing. The goal of this paper is to overview existing methods, systems, and means for space debris removal from low-Earth orbits with the aim to contribute to the solution of a topical problem of outer space utilization: the problem of space debris in near-Earth space. Space debris removal systems are under active development in the leading space countries. The overview showed that in scientific publications a great attention is paid to passive and active methods and means for space debris removal from near-Earth space. Relatively recently, a start was made on studying the feasibility of space debris removal systems using a combined method, which simultaneously uses means developed on the basis of passive and active methods. This paper considers a combined contactless space debris removal system with a service spacecraft equipped with electrojet engines and an aerodynamic compensator in the form of two plates. The combined system implements a directional deorbit of space debris objects by acting thereon with an ion beam. The proposed combined space system may be used to remove space debris from low-Earth orbits to the dense atmosphere followed by its burn-up. The combined line in the development of space debris removal systems is yet to be studied; however, its implementation would offer some advantages over active and passive methods used alone. Because of this, the development of the proposed combined space system with an aerodynamic compensator for contactless space debris removal is a promising line, which poses problems for further studie
     

space debris objects, problem of space debris in near-Earth space, systems and means for space debris removal from near-Earth orbits

1. The Orbital Debris Quarterly News. NASAJSC Houston. 2009. V. 13. No. 2. 10 pp.

2. O'Callaghan J. These are the 50 most dangerous objects orbiting Earth right now. URL: https://www.forbes.com/sites/jonathanocallaghan/2020/09/10/experts-reveal-the-50-most-dangerous-pieces-of-space-junk-orbiting-earth-right-now/?sh=9bc74b97c216 (Last accessed on August 31, 2023).

3. The Orbital Debris Quarterly News. NASAJSC Houston. 2023. V. 27. No. 3. 14 pp.

4. IADC Space debris mitigation guidelines. IADC-2002-01. Revision 1. Issued by Steering Group and Working Group 4. 2007. September. 10 pp.

5. Virgili B.B, Krag H. Active debris removal for LEO missions. Proceedings of 31st IADC meeting, Darmstadt, Germany, 18th of April, 2013. 7 pp.

6. Crowther R, Krag H. The inter-agency space debris coordination committee. URL: https://www.icao.int/Meetings/SPACE2016/Presentations/2%20-%20H.%20Krag%20-%20IADC.pdf (Last accessed on August 31, 2023).

7. State-of-the-Art Small Spacecraft Technology. Small Spacecraft Systems Virtual Institute. Ames Research Center, Moffett Field, California, 2023. 366 pp. URL: https://www.nasa.gov/sites/default/files/atoms/files/2022_soa_full_0.pdf (Last accessed on August 31, 2023).

8. Alby F. SPOT-1 End of life disposal maneuvers. Advances in Space Research. 2004. No. 35. Pp. 1335 - 1342. https://doi.org/10.1016/j.asr.2004.12.013

9. Srikrishnan S., Dash P. K., Nadaraja Pillai S., Arunvinthan S. An approach for space debris cleaning using space based robots. International Journal of Engineering Research and Management (IJERM). 2015. V. 2. Iss. 6. Pp. 51-54.

10. ClearSpace secures a major UK contract to help clean up space. September 26, 2022. URL: https://clearspace.today/clearspace-secures-a-major-uk-contract-to-help-clean-up-space/ (Last accessed on August 31, 2023).

11. Paliy A. S., Skorik A. D. Analysis of use of aerodynamic systems to deorbit modular large-sized space objects from low near-earth orbit. Teh. Meh. 2014. No. 2. Pp. 43-51. (in Russian).

12. Alpatov A. P., Paliy A. S., Skorik A. D. Aerodynamic systems for removing space objects. Teh. Meh. 2015. No. 4. Pp. 126-138. (in Russian).

13. Alpatov A. P., Paliy A. S., Skorik A. D. The development of structural design and the selection of design parameters of aerodynamic systems for deorbiting upper-stage rocket launcher. Science and Innovation. 2017. V. 13. No. 4. Pp. 33-45. (in Ukrainian). https://doi.org/10.15407/scine13.04.029

14. Palii O. S., Alpatov A. P., Skorik O. D., Avdieiev A. M., Baranov Ye. Yu. Aerodynamic system for space object removal from near-Earth orbits: Patent No. 109194 Ukriane, IPC B 64 G 1/62; à201312759; filed on November 1, 2013; published on July 27, 2015, Bul. No. 14. 12 pp. (in Ukrainian).

15. Palii O. S., Alpatov A. P., Skorik O. D. Method and system for space object removal from near-Earth orbits: Patent No. 109318 Ukraine: IPC B 64 G 1/62; à20131326; filed on November 14, 2013; published on August 10, 2015, Bul. No. 15. 11 pp. (in Ukrainian).

16. Palii O. S., Alpatov A. P., Pylypenko O. V., Skorik O. D. Method and spacecraft for shortening the ballistic life of space objects in near-Earth orbits: Patent No. 113747 Ukraine: IPC B 64 G 1/62; à201407652; filed on July 7, 2014; published on March 10, 2017, Bul. No. 5. 11 pp. (in Ukrainian).

17. Rasse B., Damilano P., Dupuy C. Satellite inflatable deorbiting equipment for LEO spacecrafts. Journal of Space Safety Engineering. 2014. V. 1. No. 2. Pp. 75-83. https://doi.org/10.1016/S2468-8967(16)30084-2

18. Bernardi F., Vignali G. Sailing System for Cubesat Deorbiting. University of Rome, Italy. 2016. URL: http://www.unisec-global.org/ddc/pdf/1st/01_FedericoSailing_abst.pdf (Last accessed on August 31, 2023).

19. Mishchenko O. V. On the determination of the tether length for an experimental electrodynamic system. Teh. Meh. 2017. No. 4. Pp. 55-63. (in Russian). https://doi.org/10.15407/itm2017.04.055

20. Pirozhenko A. V., Mishchenko A. V. Small experimental electrodynamic space tether system. Electrical model. Space Sci. & Technol. 2018. No. 3. Pp. 3-10. (in Russian). https://doi.org/10.15407/knit2018.03.003

21. Janhunen P. Electrostatic plasma brake for deorbiting a satellite. J. Propuls. Power. 2010. V. 26. No. 2. Pp. 370-372. https://doi.org/10.2514/1.47537

22. NASA - NanoSail-D Home Page. NASA - Home. URL: http://www.nasa.gov/mission_pages/smallsats/nanosaild.html (Last accessed on August 31, 2023).

23. Koshkin N. I., Korobeynikova E. A., Lopachenko V. V., Melikyants S. M., Strakhova S. L., Shakun L. S. On the motion of a microsatellite with the sail in the atmosphere (NanoSail-D). Kosm. Nauka Tehnol. 2012. V. 18. No. 1. Pp. 31 - 38. (in Russian). https://doi.org/10.15407/knit2012.01.031

24. Yuzhnoye Design Office's Rockets and Spacecraft. S. N. Konyukhov (Ed.). Dnipropetrovsk, 2001. 240 pp. (in Russian).

25. Satellite Missions catalogue: GOCE. URL: https://www.eoportal.org/satellite-missions/goce (Last accessed on August 31, 2023).

26. Bombardelli C, Pelaez J. Ion beam shepherd for contactless space debris removal. Journal of Guidance, Control and Dynamics. 2011. V. 34. No. 3. Pp. 916 - 920. https://doi.org/10.2514/1.51832

27. Bombardelli C., Merino M., Ahedo E., Pelaez J., Urrutxua H., Iturri-Torreay A., Herrera-Montojoy J. Ariadna call for ideas: Active removal of space debris ion beam shepherd for contactless debris removal. ESA Technical Report. 2011. 90 pp.

28. Patent No. WO 2011/110701 A1 Spain, IPC7 B64G 1/24. System for adjusting the position and attitude of orbiting bodies using guide satellites. C. Bombardelli, J. Pelaez. PCT/ES2011/000011; filed on March 11, 2010; published on September 15, 2011. 21 pp.

29. Bombardelli C., Alpatov A. P., Pirozhenko A. V., Baranov E. Yu., Osinovyj G. G., Zakrzhevskii A. E. Project "space shepherd" with ion beam. Ideas and problems. Kosm. Nauka Tehnol. 2014. V. 20. No. 2.Pp. 55 - 60. (in Russian). https://doi.org/10.15407/knit2014.02.055

30. Alpatov A. P., Zakrzhevskii A. Ye., Fokov A. A., Khoroshilov S. V. Determination of optimal position of ion beam space shepherd with respect to space debris object. Teh. Meh. 2015. No. 2. Pp. 37 - 48. (in Russian).

31. Alpatov A. P., Bass V. P., Baulin S. A., Brazinsky V. I., Gusynin V. P., Daniev Yu. F., Zasukha S. A. Technogeneous Clogging of Near-Earth Space. Dnipropetrovsk: Porogi, 2012. 380 pp. (in Russian).

32. Savchuk A.P., Fokov A. A., Khoroshilov S. V. Computations of contactless effects on space debris object using its known contour. Teh. Meh. . 2016. No. 1. Pp. 26 - 37. (in Russian).

33. Lappas V. et al. CubeSail: A low cost CubeSail based solar sail demonstration mission. Adv. Sp. Res. 2011. V. 48. No. 11. Pp. 1890 - 1901. https://doi.org/10.1016/j.asr.2011.05.033

34. Merino M., Ahedo E., Bombardelli C., Urrutxua H., Pelaez J. Ion beam shepherd satellite for space debris removal. Progress in Propulsion Physics. 2013. V. 4. Pp. 789 - 802. https://doi.org/10.1051/eucass/201304789

35. Alpatov A. P., Maslova A. I., Khoroshylov S. V. Contactless De-Orbiting of Space Debris by the Ion Beam. Dynamics and Control. Beau Bassin: LAP Lambert Academic Publishing, 2019. 330 pp. https://doi.org/10.15407/akademperiodyka.383.170

36. Khoroshylov S. V. Relative motion control system of spacecraft for contactless space debris removal. Nauka Innov. 2018. No. 4. Pp. 5-17. (in Ukrainian). https://doi.org/10.15407/scin14.04.005

37. Khoroshylov S. V. The algorithm to control the in-plane relative motion of a spacecraft for contactless space debris removal. Space Sci. & Technol. 2019. V. 25. No.1. Pp. 14-26. (in Russian). https://doi.org/10.15407/scine14.04.005

38. Alpatov A., Khoroshylov S., Bombardelli C. Relative control of an ion beam shepherd satellite using the impulse compensation thruster. Acta Astronautica. 2018. V. 151. Ðp. 543-554. https://doi.org/10.1016/j.actaastro.2018.06.056

39. Dron' M., Golubek A., Dubovik L., Dreus A., Heti K. Analysis of ballistic aspects in the combined method for removing space objects from the near-Earth orbits. Eastern-European Journal of Enterprise Technologies. 2019. V. 2. No. 5 (98). Pp. 49-54. https://doi.org/10.15587/1729-4061.2019.161778

40. Alpatov A., Dron' M., Golubek A., Lapkhanov E. Combined method for spacecraft deorbiting with angular stabilization of the sail using magnetorquers. CEAS Space Journal. 2022. No. 15. Pp. 613-625. https://doi.org/10.1007/s12567-022-00469-6

41. Golubek A., Dron' M., Dubovik L., Dreus A., Kulyk O., Khorolskiy P. Development of the combined method to de-orbit space objects using an electric rocket propulsion system. Eastern-European Journal of Enterprise Technologies. 2020. V. 4. No. 5 (106). Pp. 78-87. https://doi.org/10.15587/1729-4061.2020.210378

42. Ukrainian Patent for Invention No. UA121460C2, ÌÏÊ7 B64G 1/24, B64G 1/62. Method for contactless removal of space debris from near-Earth orbits using an aerodynamic compensator. A. P. Alpatov, D. S. Svorobin, O. D. Skoryk. à201607424; filed on July 7, 2016, published on June 10, 2020, Bul. No. 11. 10 pp. (in Ukrainian).

43. Alpatov A. P., Svorobin D. S., Skoryk O. D. System for contactless removal of space debris from near-Earth orbits using an aerodynamic compensator. Teh. Meh. 2016. No. 3. Pp. 51-56. (in Ukrainian).

44. Svorobin D. S., Fokov A. A., Khoroshilov S. V. Analysis of the suitability of an aerodynamic compensator for contactless space debris removal. Aviatsionno-Kosmicheskaya Tekhnika i Tekhnologia. 2018. No. 6. Pp. 4-11. (in Russian).

45. Fokov A. A., Khoroshilov S. V. Svorobin D. S. Out-of-plane relative motion of a spacecraft with an aerodynamic compensator during contactless space debris removal. Space Sci. & Technol. 2021. V. 27. No. 2. Pp. 15-27. (in Ukrainian). https://doi.org/10.15407/knit2021.02.015

46. Fokov A. A., Khoroshylov S. V., Svorobin D. S. Analysis of the advantages of an aerodynamic compensator in contactless space debris removal. Teh. Meh. 2020. No. 4. Pp. 55-64. (in Ukrainian). https://doi.org/10.15407/itm2020.04.055

47. Alpatov A. P., Gorbulin V. P. Orbital space platforms for industrial complex: problems and prospects. Visn. Nac. Akad. Nauk. Ukr. 2013. No. 12. Pp. 26-38. (in Russian). https://doi.org/10.15407/visn2013.12.026

48. Alpatov A. P. Information models and technologies of space debris mitigation in near space. System Technologies. 2018. No. 3. Pp. 3-14. (in Russian).

49. Alpatov A. P. Space debris: the aspects of the problem. Teh. Meh. 2018. No. 1. Pp. 30-47. (in Russian). https://doi.org/10.15407/itm2018.01.030

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