Space system reflectors’ metallization selection for orbital Earth surface lighting

Innovation technologies in aerospace activities


Аuthors

Starovoitov E. I.

Radio Engineering Corporation “VEGA”, 34, Kutuzovskiy prospekt, Moscow, 121170, Russia

e-mail: vega.su

Abstract

Energy consumption growth continues worldwide and human activities negative consequences are manifested in ever-increasing degree. Electric power generation for the nighttime lighting leads to heavy consumption of hydrocarbon fuel. The negative consequences for the ecology can be reduced by dint of space technologies, using reflected sunlight for the nighttime lighting. The article analyzes spectrum of reflected Sun radiation from metallic coatings of various types of reflectors’, used in the space system for orbital Earth surface lighting. It is known by now that artificial lighting can disrupt at night photo-biological reactions of various living bodies, including humans. The short-wavelength spectrum region should be pointed out specially, featuring pronounced photo-biological effect. Thus, the author suggests to reduce the reflected Sun radiation flux in short-wavelength region (ultraviolet radiation and blue color), exerting the strongest biological effect. To ease the load on operator’s visual organs and reduce the undesirable effect on ecology, various metallic coatings are recommended for use in the orbital lighting system. Five types of metallic coatings for space reflector, namely aluminum, silver, titanium, copper and golden, were considered in the article. Reflectors with silver coating are suitable for ultraviolet radiation reduction (0.28–0.38 mcm) in reflected radiation, and for ultraviolet radiation reduction (0.28–0.38 mcm) and lighting by blue color(0.44—0.48 mcm) reflectors with copper and golden coatings can be used. At the same time, taking into account the entire set of requirements, titanium coating is optimal choice of reflector coating.

Keywords:

orbital lighting, reflector, metal coating, spectrum, ecology

References

  1. Aizenberg Yu.B. Spravochnaya kniga po svetotekhnike (Lighting engineering Reference Book), Moskow, Znak, 2006, 972 p.

  2. Kraft A. Erike. Budushchee kosmicheskoi industrii (The future of space industy), Moscow, Mashinostroenie, 1979, 200 p.

  3. Semenov Yu.P., Lopota V.A. Raketno-kosmicheskaya korporatsiya “Energiya” imeni S.P. Koroleva. 1946-1996. (S.P. Korolev Rocket and Space Corporation “Energia”. 1946-1996), Moscow, RSC “Energia”, 1996, 675 p.

  4. Semenov V.F., Sizentsev G.A., Sotnikov B.I., Sytin O.G. Izvestiya RAN. Energetika, 2006, no. 1, pp. 21–30.

  5. Barmasov A.V., Barmasova A.M., Yakovleva T.Yu. Uchenye zapiski Rossiiskogo gosudarstvennogo gidrometeorologicheskogo universiteta, 2014, no. 33, pp. 84–101.

  6. International Dark-Sky Light Pollution and Wildlife, available at: http://sea2shore.org/wp-content/uploads/2015/01/LightPollutionAndWildlife.pdf«

  7. Richard H. ffrench-Constant R.H., Somers-Yeates R., Bennie J., Economou T., Hodgson D., Spalding A., McGregor P.K. Light pollution is associated with earlier tree budburst across the United Kingdom, 2016, available at: http://rspb.royalsocietypublishing.org/content/royprsb/283/1833/20160813.full.pdf

  8. Aladov A.V., Zakgeim A.L., Mizerov M.N., Chernyakov A.E. Svetotekhnika, 2012, no. 3, pp. 7–10.

  9. Kaptsov V.A., Sosunov N.N., Shishchenko I.I., et al. Gigiena i sanitariya, 2014, no. 4, pp. 120–123.

  10. Jin H., Jin S., Chen L., Cen S., Yuan K. Research on the Lighting Performance of LED Street Lights With Different Color Temperatures, IEEE Photonics Journal, 2015, vol. 7, pp. 1–9.

  11. Moroz L.S., Chechulin B.B., Polin I.V. et al. Titan i ego splavy (Titanium and its alloys), Leningrad, Sudpromgiz, vol. 1, 1960, 516 p.

  12. Allen C.W. Astrophysical quantities. 3rd. ed. London, The Athlone Press, 1973, available at: https://archive.org/details/AstrophysicalQuantities

  13. Luchinskii G.P. Khimiya titana (Titanium chemistry), Mosсow, Khimik, 1971, 472 p.

  14. Semenov Yu.P., Branets V.N., Grigor’ev Yu.I., Zelenshchikov N.I., Koshelev V.A., Mel’nikov V.M., Platonov V.N., Sevast’yanov N.N., Syromyatnikov V.S.. Kosmicheskie issledovaniya, 1994, vol. 32, no. 4–5, pp. 186–193.

  15. Kovtyukh A.S.. Kosmicheskii praktikum (Space practicum), Moscow, UNC DO, 2005, 181 p.

  16. Panyushin S.K. Elektronnyi nauchno-obrazovatel’nyi vestnik “Zdorov’e i obrazovanie v XXI veke”, 2012, vol. 14, no, 10. pp. 289-291.

  17. Romanov V.N. Sistemnyi analiz dlya inzhenerov (System analysis for engineers), St. Petersburg, SZGZTU, 2006, 186 p.

  18. Mel’nikov V.M., Matyushenko I.N., Chernova N.A., Kharlov B.N. Trudy MAI, 2014, no. 78, available at: http://www.mai.ru/science/trudy/eng/published.php?ID=53742

  19. Cheremnyh E.A., Zykov A.V. Trudy MAI, 2011, no. 45, available at: http://www.mai.ru/science/trudy/eng/published.php?ID=25397

  20. Makarenkova N.A. Trudy MAI, 2016, no. 85, available at: http://www.mai.ru/science/trudy/eng/published.php?ID=65711


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