Research of the dynamics of condensed product deposition


Cite item

Full Text

Abstract

The paper is devoted to the research of structural nonmetallic materials used in the construction of spacecraft for mass loss and gas release in a vacuum-thermal environment, as well as the research of the dynamics of deposition of gas release condensed products on the optical surfaces of optical equipment. A test bench has been developed for carrying out research of the dynamics of deposition of condensed products based on quartz crystal microbalance. In accordance with the State Standards GOST R 50109-92 mass loss and gas release tests of structural non-metallic materials (fiberglass, fiberglass honeycomb panel, polyurethane foam, tapes, textiles, adhesives, etc.) used in spacecraft construction have been carried out. The effect of the deposition of condensed products of gas release from these materials on the transmission coefficient of the optical element is determined. A conclusion about the possibility of using these materials in constructing spacecraft is made.

About the authors

S. V. Tsaplin

Samara State University

Author for correspondence.
Email: tsaplin@samsu.ru

Candidate of Science (Physics and Mathematics)

Associate Professor, Department of Solid State Physics and Non-Equilibrium Systems

Russian Federation

S. A. Bolychev

Samara State University

Email: tsaplin@samsu.ru

Principal Software Engineer

Russian Federation

References

  1. OST 92-9566-82. Nonmetallic materials of outer surfaces. Method of testing mass loss and content of volatile condensable materials in a vacuum-thermal environment. Moscow: Standartinform Publ., 1982. (In Russ.)
  2. GOST R 50109-92. Nonmetallic materials. Test method for mass loss and content of volatile condensable materials in a vacuum-thermal environment. Moscow: Izdatel'stvo standartov Publ., 1992. (in Russ.)
  3. http://www.aacesearch.at/products/products_AAC_SpaceTesthouse_Outgassing_en. html.
  4. GOST 27124-86. Piezoelectric resonators for industrial and domestic radioelectronic equipment. Basic parameters. Moscow: 1986. (In Russ.)
  5. Akishin A.I., Zazulin V.S. Thickness control of films produced in vacu-um by a quartz crystal resonator // Pribory i tehnika eksperimenta. 1963. No. 1. P. 152-154. (In Russ.)
  6. Scurat V.E., Tansyrev G.D., Beriozkina N.G., Volkov A.V., Jigatch A.N., Leipuksky I.O., Pshenichnikov P.A., Samsonov P.V., Toropov V.P., Demigod S.A., Naumov S.F., Sokolova S.P. Surface Contamination of Some Materials of the Space Station “MIR” // High Performance Polymers. 2001. V.13, no. 4. P. 337-353. doi: 10.1088/0954-0083/13/4/311
  7. Akishin A.I. Space equipment operability under the influence of own atmosphere of spacecraft // Trudy VIII Mezhvuzovskoy nauchnoy shkoly molodykh spetsialistov “Kontsentrirovannye potoki energii v kosmicheskoy tekhnike, elektronike, ekologii i meditsine” Moscow: NIIYAF MGU Publ., 2007. P. 15-19. (In Russ.)
  8. Malov V.V. P'ezorezonansnye datchiki [Piezoresonance sensors]. Moscow: Energoatomizdat Publ., 1989. 272 p. (In Russ.)
  9. Davydenko S.V., Tsaplin S.V. Deposition dynamics research of condensed products of structural materials // Sbornik trudov XXVIII Rossiyskoy shkoly po problemam nauki i tehnology. Miass, 2008. P. 71-77. (In Russ.)
  10. Rosanov L.N. Vakuumnaya tekhnika [Vacuum engineering]. Moscow: Vysshaya shkola Publ., 1990. 320 p.
  11. Maisell L.I., Glang R. Tekhnologiya tonkikh plenok [Handbook of thin film technology]. V. 1. Moscow: Sovetskoe radio Publ., 1977. 664 p.
  12. Maisell L.I., Glang R. Tekhnologiya tonkikh plenok [Handbook of thin film technology]. V. 2. Moscow: Sovetskoe radio Publ., 1977. 768 p.
  13. GOST 26.003-80. Interface system for measuring devices with byte-serial, bit-parallel exchange of information. Moscow: Standartinform Publ., 1980. (In Russ.)

Supplementary files

Supplementary Files
Action
1. JATS XML
Download

Copyright (c) 2015 VESTNIK of the Samara State Aerospace University

This website uses cookies

You consent to our cookies if you continue to use our website.

About Cookies