Certificate of Registration Media number Эл #ФС77-53688 of 17 April 2013. ISSN 2308-6033. DOI 10.18698/2308-6033
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Technology of statistical control of the properties of nanomaterials and coatings exposed to ionizing radiation and assessment of the reliability of nanomaterial space products

Published: 11.09.2020

Authors: Ertman L.V., Rudakov V.B., Burtsev A.S., Baklanov V.I., Filonenko P.A.

Published in issue: #9(105)/2020

DOI: 10.18698/2308-6033-2020-9-2018

Category: Metallurgy and Science of Materials | Chapter: Nanotechnologies and Nanomaterials Material Science

Since space engineering started using nanomaterials, there has emerged a contradiction between the need to ensure and confirm high reliability of space products and scarce information to obtain an accurate assessment of reliability due to the lack of sufficient statistics on the reliability of nanomaterial products. To eliminate such a contradiction, we introduce a technology which appears to solve a scientific and technical problem aimed at increasing the accuracy of assessing the reliability of space products. The solution is based on information on the properties, parameters and performance of nanomaterials and coatings and nanomaterial products in the process of statistical control. It is done by combining the information on reliability of the “nanomaterial ― nanomaterial element ― device ― system ― product” sequence and increasing the efficiency of statistical control of this sequence reliability according to the results of simulation, testing and field testing and taking into account rational distribution of costs for testing.

[1] Antonenko S.V., Malinovskaya A.S., Maltsev S.N. Nanotehnika ― Nanotechnics, 2007, no. 11, pp. 8‒14.
[2] Vul Ya., Aleksenskiy A.E., Dideykin A.T. Detonation nanodiamonds: technology, properties and applications. Nanosciences and Nanotechnologies. In: V.N. Kharkin, C. Bai, S.-C. Kim, ed. Encyclopedia of Life Support Systems (EOLSS). Developed under the Auspices of the UNESCO. Oxford, UK, Eolss Publ., 2009, pp. 486–494.
[3] Khannink R., Khill A., ed. Mir materialov i tekhnologii. Nanostrukturnye materialy [The world of materials and technologies. Nanostructured materials]. Moscow, Tekhnosfera Publ., 2009, 488 p. (In Russ.)
[4] Menshikov V.A., Rudakov V.B., Sychev V.N. Kontrol kachestva kosmicheskikh apparatov pri otrabotke i proizvodstve [Quality control of spacecraft during development and production]. Moscow, Mashinostroenie Publ., 2009, 400 p.
[5] Volkov L.I. Upravlenie ekspluatatsiey letatelnykh kompleksov [Aircraft operational control]. Moscow, Vysshaia shkola Publ., 1987, 400 p.
[6] Volkov L.I., Rudakov V.B. Statisticheskiy kontrol ierarkhicheskikh sistem [Statistical control of hierarchical systems]. Moscow, SIP RIA Publ., 2002, 360 p.
[7] Savin G.I. Sistemnoe modelirovanie slozhnykh protsessov [System modeling of complex processes]. Moscow, Fazis Publ., 2000, 275 p.
[8] Makarov M.I., Rudakov V.B., Makarov V.M. Dvoynye tekhnologii (Dual Technologies), 2015, no. 3, pp. 9‒17.
[9] Rudakov V.B., Makarov V.M. Dvoynye tekhnologii (Dual Technologies), 2016, no. 3, pp. 2‒11.
[10] Obzor i analiz napravleniy razvitiya matematicheskikh modeley nanomaterialov i nanotekhnologii. [Review and analysis of directions for the development of mathematical models of nanomaterials and nanotechnologies]. Tr. Mezhdunarodnoy nauchno-tekhnicheskyi konferentsii. Nanotekhnologii funktsionalnykh materialov (NFM’2016), 21‒25 iyunya 2016 goda [Proceedings of the International Scientific and Technical Conference. Nanotechnologies of Functional Materials (NFM’2016), June 21‒25, 2016.]. In 2 vols., vol. 2. St. Petersburg, SPBSTU Publ., 2016, 465 p.