Orbital Space Platforms for Industrial Complex: Problems and Prospects
DOI:
https://doi.org/10.15407/visn2013.12.026Keywords:
space platform, orbital industrial complex, design, management, sustainability, materials, process moduleAbstract
The problems of the development of space technology to build technological capacity in the near-Earth and near-Moon space are discussed. The evaluation of the problems and prospects associated with the development of large space-based technological platforms is made. Among the issues discussed the determination of the structure of space-based technological platforms, control systems, connection and communication systems are considered. A set of tasks related to the problem of forming a progressive paradigm of the industrial technological space segment with current accounting of global processes of human civilization evolution is presented in the article.
References
Gorbulin V.P., Mejtarchan B.G. Doklady Akademii Nauk Ukrainy. 1994. (4): 51–56. [in Russian].
Alpatov A.P. Movable control mechanical systems (Kyiv: Naukova Dumka, 1998). [in Russian].
Gorbulin V.P., Pavlovsky M.A. Research Methodology vibrations of large space structures: method. guidances. (Kyiv: Naukova Dumka, 1992). [in Ukrainian].
Demonis I.M., Petrova A.P. Materials VIAM in space technology. (Moscow: VIAM, 2011). [in Russian].
Khorolsky P.P. In: The effectiveness of honeycomb structures in products aerospace engineering: mater. Proc. 5th Sci. Conf. (Dnepropetrovsk , 2013). P. 249–53. [in Russian].
Jenkins H.M. Gossamer Spacecraft: Membrane and Inflatable Structures Technology for Space. (AIAA, 2001). http://doi.org/10.2514/4.866616
Voloshenyuk O.L., Khramov D.A. Tekhnicheskaya mekhanika (Technical mechanics). 2008. (1): 21–30. [in Russian].
Forward R.L., Hoyt R.P. Failsafe multistrand tether SEDS technology. In: Tether in Space. Proc. 4th Int. Conf. (Washington, 1995). P. 1151–59.
Gorbulin V.P., Kushnarev O.P. Kosmicheskaya Nauka i Tekhnologiya (Space Science and Technology). 2012. (5): 66–74. [in Russian].
Khoroshilov S.V. Tekhnicheskaya mekhanika (Technical mechanics). 2011. (3): 117–25. [in Russian].
Bolonkin A.A. Non-Rocket Space Launch and Flight. (Elsevier, 2006). – 488 p.
Beletsky V.V., Levin E.M. The dynamics of space tether systems. (Moscow: Nauka, 1990). [in Russian].
Rupp Ch.C. Flight data from the first and second flights of the Small Expendable Deployer System (SEDS). In: Tether in Space. Proc. 4th Int. Conf. (Washington, 1995). P. 133–148.
Pirozhenko A.V. Kosmicheskiye Issledovaniya (Space Research). 1992. 30(4): 473–82. [in Russian].
Alpatov A.P., Grebenkin F.N., Mishchenko A.V. Visnyk Dnipropetrovskogo Universyteta. 2006. (2): 5–10. [in Russian].
Forward R.L., Hoyt R.P., Uphoff C.W. Terminator tether: a spacecraft deorbit device. J. Spacecraft and Rockets. 2000. 37(2): 187–96. http://doi.org/10.2514/2.3565
Alpatov A.P., Pirozhenko A.V., Khramov D.A. Tekhnicheskaya mekhanika (Technical mechanics). 2005. (2): 90–98. [in Russian].
Voronka N.R. Technology demonstrator of a standardized deorbit module designed for CubeSat and rocketpod applications. In: Small Satellites. Proc. 19th Annual AIAA/USU Conf. (August 2005, Logan, India).
Tortora P., Somenzi L., Iess, L., Licata R. Small mission design for testing in-orbit an electrody-namic tether deorbiting system. J. Spacecraft and Rocket. 2006. 43(4): 883–92. http://doi.org/10.2514/1.15359
http://teacher.msu.ru/upload/school/proforientir/ chem/carbon/carbon-present.pdf
Edwards B.C. Design and deployment of a space elevator. Acta Astronautica. 2000. 4710: 735–44. http://doi.org/10.1016/S0094-5765(00)00111-9
http://en.wikipedia.org/wiki/Tether_propulsion.
Alpatov A.P., Gusynin V.P., Byelonozhko P.P. Shape control of large reflecting structures in space. IAC-11.C2.3.6
Alpatov A.P., Byelonozhko P.A., Byelonozhko P.P. Aktualnye problemy aviatsionnykh i aerokosmicheskikh sistem. 2010. 15(2): 38–57. [in Russian].
