Designing radiation protection for the scientific equipment complex of the Earth’s remote sensing spacecraft
Authors: Kombaev T.Sh., Artemov M.E., Zefirov I.V.
Published in issue: #5(89)/2019
DOI: 10.18698/2308-6033-2019-5-1878
Category: Aviation and Rocket-Space Engineering | Chapter: Design, construction and production of aircraft
In the course of operation spacecrafts are exposed to ionizing radiation from outer space. The electronic component base (ECB) used in creating onboard radio-electronic equipment of universal space platforms does not always correspond to the external operating conditions in terms of radiation resistance for some spacecraft orbits due to a number of technical and/or economic reasons. One method to increase the radiation resistance of onboard equipment is to install additional mass protection in the form of screens on the whole equipment or local screens on individual critical radio and electronic components. The article describes the design of additional radiation protection of the geostationary spacecraft scientific equipment complex for adaptation to the radiation conditions of operation in orbits of the “Molniya” type. The solution of the problem involves several preliminary steps, namely: determining the radiation conditions for the spacecraft operation in the target orbit, estimating the local absorbed doses at the locations of the onboard equipment, estimating absorbed doses directly in the electronic component base of the equipment and analyzing the radiation resistance. Designing the radiation complex of scientific equipment was based on the values of the radiation resistance of the equipment and its components, as well as the calculated values of the local absorbed doses in the components
References
[1] Efanov V.V. Mnogofunktsionalnaya kosmicheskaya platforma “Navigator” [Multifunctional space platform “Navigator”]. Lemeshevsky S.A., ed. Khimki, “NPO S.A. Lavochkin” Publ., 2017, 360 p.
[2] Kovtun V.S., Korolev B.V., Sinyavsky V.V., Smirnov I.V. Kosmicheskaya tekhnika i tekhnologii – Space technique and technologies, 2015, no. 2 (9), pp. 3–24.
[3] Vette J. The AE-8 Trapped Electron Model Environment. Report 91–24. Greenbelt, Maryland, National Space Science Data Center, 1991.
[4] Kuznetsov N.V., Popova H., Panasyuk M.I. Empirical Model of Long-Time Variations of Galactic Cosmic Ray Particle Fluxes. J. Geophys. Res. Space Physics, 2017, vol. 122, issue 2, pp. 1463–1472.
[5] Nymmik R.A. Probabilistic Model for Fluences and Peak Fluxes of Solar Particles. Radiation Measurements, 1999, vol. 30, pp. 287–296.
[6] Artemov M.E. FD_ORBIT2. Certificate of state registration of computer programs No. 2012618517, 19.09.2012. Register of computer programs Publ., 20.12.2012, no. 4.
[7] Khamidullina N.M., Zefirov I.V. LocalDose&SEE. Certificate of state registration of computer programs No. 2008613789, 08.08.2008. Register of computer programs Publ., 20.12.2008, no. 4.
[8] Zefirov I.V. Kosmonavtika i raketostroenie — Cosmonautics and Rocket Engineering, 2009, no. 4, pp. 78–87.
[9] Zefirov I.V., Kombaev T.Sh., Chernikov P.S, Vlasenkov E.V., Khamidullina N.M., Artemov M.E. Primenenie tekhnologii SAPR dlya modifikatsii programmnogo kompleksa po raschetu radiatsionnoy stoykosti apparatury kosmicheskikh apparatov [Using CAD technology to modify the software system for calculating the radiation resistance of spacecraft equipment]. XLI Akademicheskie chteniya po kosmonavtike, posvyachshennye pamyati akademika S.P. Koroleva i drugikh vydaushchikhsya otechestvennykh uchenykh – pionerov osvoeniya kosmicheskogo prostranstva: cbornik tezisov [Academic readings in cosmonautics dedicated to the memory of academician S.P. Korolev and other prominent domestic scientists — pioneers of space exploration. Abstracts]. Moscow, BMSTU Publ., 2017, pp. 428–429.
[10] Pichkhadze K.M., Khamidullina N.M., Zefirov I.V. Kosmicheskie issledovaniya — Cosmic Research, 2006, vol. 44, no. 2, pp. 179–182.