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Aviation materials and technologies №3, 2019

Contents

  • V.V. Antipov, M.V. Grigoryev, A.N. Konovalov, A.A. Meshkov, N.Yu. Serebrennikova

    RESEARCH OF THE INFLUENCE OF RIVETING ON THE LOW-CYCLE FATIGUE OF RIVETED CONNECTION SHEETS OF ALUMINUM-LITHIUM ALLOYS

    3-8
  • K.A. Udod, N.N. Trofimenko, D.N. Romanenko, G.S. Sevalnev

    PROSPECTS FOR THE DEVELOPMENT OF CONSTRUCTIONAL ALUMINIUM-DOPED STEELS

    9-13
  • I. Benarieb, L.B. Ber, K.V. Antipov, S.V. Sbitneva

    TRENDS IN DEVELOPMENT OF WROUGHT ALLOYS OF Al–Mg–Si–(Cu) SYSTEM. Part 1 (review)

    14-22
  • S.N. Semenova, A.M. Chaykun, R.R. Suleymanov

    ETHYLENE-PROPYLENE-DIENE RUBBER AND ITS USE IN RUBBER MATERIALS FOR SPECIAL PURPOSES (review)

    23-30
  • A.I. Tkachuk, I.V. Terekhov, Ya.M. Gurevich, K.N. Grigoreva

    RESEARCH OF THE INFLUENCE OF THE MODIFYING ADDITIVES NATURE ON THE RHEOLOGICAL AND THERMOMECHANICAL PROPERTIES OF A PHOTOPOLYMER COMPOSITION BASED ON EPOXY VINYL ESTER RESIN

    31-40
  • V.M. Gurenkov, V.О. Gorshkov, V.P. Chebotarev, Т.N. Prudskova, Т.I. Andreeva

    COMPARATIVE ANALYSIS OF PROPERTIES OF POLYETHERETHERKETONE OF DOMESTIC AND FOREIGN PRODUCTION

    41-47
  • R.R. Mukhametov, A.P. Petrova

    THERMOSETTING BINDERS FOR POLYMER COMPOSITES (review)

    48-58
  • S.S. Vinogradov, A.A. Nikiforov, L.I. Zakirova

    CADMIUM REPLACEMENT. STAGE 2 – FINAL. GALVANIC THERMAL COATING OF  ZINC–TIN SYSTEM – REAL ALTERNATIVE TO CADMIUM PLATING

    59-66
  • D.P. Farafonov, N.E. Leshchev, A.N. Afanasiev-Khodykin, N.I. Artemenko

    ABRASIVE WEAR-RESISTANT SEAL MATERIALS OF THE GAS TURBINE ENGINE FLOW SECTION

    67-74
  • S.P. Konokotin, R.M. Nazarkin

    THЕ TRAVELLING MAGNETIC FIELD OF BIPOLAR ELECTROMAGNETIC INDUCTOR AND ITS INFLUENCE ON THE PROPERTIES OF Cr- AND Ni-BASED POLYCRYSTALLINE ALLOYS. Part 2

    75-82
  • A.S. Boychuk, I.A. Dikov, A.S. Generalov

    THE INCREASE OF SENSITIVITY AND RESOLUTION OF FRP SOLID SAMPLES NONDESTRUCTIVE ULTRASONIC TESTING USING THE ULTRASONIC PHASED ARRAY 

    83-88
  • A.A. Krivushina, T.V. Bobyreva, T.V. Yakovenko, E.V. Nikolaev

    METHODS OF MICROORGANISMS-DESTRUCTORS STORAGE IN FSUE «VIAM» COLLECTION (review)

    89-94
Содержание номера
1.

DOI: 10.18577/2071-9140-2019-0-3-3-8

UDC: 620.178.35

Pages:: 3-8

V.V. Antipov1, M.V. Grigoryev1, A.N. Konovalov1, A.A. Meshkov2, N.Yu. Serebrennikova1

[1] Federal state unitary enterprise «All-Russian Scientific-Research Institute of Aviation Materials» of National Research Center «Kurchatov Institute»
[2] Open Joint Stock Company «National Institute of Aviation Technologies», info@niat.ru

RESEARCH OF THE INFLUENCE OF RIVETING ON THE LOW-CYCLE FATIGUE OF RIVETED CONNECTION SHEETS OF ALUMINUM-LITHIUM ALLOYS

Riveted joints in the construction of aviation engineering occupy one of the main places among technological processes during the assembly of structural elements. Manufacturing technology of riveted joints is well-proven and a great deal of reference documentation is released. However, in this documentation there are not presented the most advanced materials, with characteristic features during the process of riveted connection with prework taken into account. The distinctive feature of 1441 and B-1481 alloys is additional requirements for manufacturing technology of riveted joints due to the alloys’ high rigidity and sensitivity to impact loads and constant stresses in the riveted seam under tension in the holes.

Keywords: Al–Li alloys, rivets of general application, rivets with compensator, press rivet, impact rivet, low-cycle fatigue.

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2.

DOI: 10.18577/2071-9140-2019-0-3-9-13

UDC: 669.018.29

Pages:: 9-13

K.A. Udod1, N.N. Trofimenko2, D.N. Romanenko3, G.S. Sevalnev3

[1] Joint Stock Company «Vyksa Metallurgical Plant»
[2] ALL-RUSSIAN SCIENTIFIC RESEARCH INSTITUTE OF AVIATION MATERIALS, admin@viam.ru
[3] Federal state unitary enterprise «All-Russian Scientific-Research Institute of Aviation Materials» of National Research Center «Kurchatov Institute»

PROSPECTS FOR THE DEVELOPMENT OF CONSTRUCTIONAL ALUMINIUM-DOPED STEELS

The prospects for the development of new structural steels with increased aluminum content are considered. It is shown that research in this area is carried out both in Russia and abroad. It is determined that the main research and development line is to improve the processability of aluminum-containing steels due to their tendency to form brittle intermetallic compounds. The analysis of the development of steels with high aluminum content gives confidence that such materials can be successfully applied in the aircraft industry.

Keywords: aluminum, steel with aluminum, alloying with aluminum, high specific strength, corrosion resistance, strength, damping steel.

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3.

DOI: 10.18577/2071-9140-2019-0-3-14-22

UDC: 669.717

Pages:: 14-22

I. Benarieb1, L.B. Ber2, K.V. Antipov3, S.V. Sbitneva1

[1] Federal state unitary enterprise «All-Russian Scientific-Research Institute of Aviation Materials» of National Research Center «Kurchatov Institute»
[2] Open Joint-Stock Company «All-Russia Institute of Light Alloys», info@oaovils.ru
[3] ALL-RUSSIAN SCIENTIFIC RESEARCH INSTITUTE OF AVIATION MATERIALS, admin@viam.ru

TRENDS IN DEVELOPMENT OF WROUGHT ALLOYS OF Al–Mg–Si–(Cu) SYSTEM. Part 1 (review)

This article presents a national and foreign literature review for application of wrought aluminum alloys of Al–Mg–Si–(Cu) system 6ххх series. The practical significance of these materials in building industry and modern fields of machine building is shown. The classification of these alloys in dependence of content of the main alloying elements is proposed. Perspective domestic and foreign alloys for usage in transport engineering are considered. The main trends in development of these alloys in some branches of industry are formulated.

Keywords: wrought heat-treatable alloys of Al–Mg–Si–(Cu) system, 6ххх series aluminium alloys, perspective materials, weight efficiency.

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    9. Duyunova V.A., Nechaykina T.A., Oglodkov M.S., Yakovlev A.L., Leonov A.A. Perspektivnyye razrabotki v oblasti legkikh materialov dlya sovremennoy aviakosmicheskoy tekhniki [Promising developments in the field of light materials for modern aerospace engineering] // Tekhnologiya legkikh splavov. 2018. №4. S. 28–43.

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4.

DOI: 10.18577/2071-9140-2019-0-3-23-30

UDC: 678.7

Pages:: 23-30

S.N. Semenova1, A.M. Chaykun1, R.R. Suleymanov1

[1] ALL-RUSSIAN SCIENTIFIC RESEARCH INSTITUTE OF AVIATION MATERIALS, admin@viam.ru

ETHYLENE-PROPYLENE-DIENE RUBBER AND ITS USE IN RUBBER MATERIALS FOR SPECIAL PURPOSES (review)

The article contains a literature and patent review of the use of ethylene-propylene-diene rubbers in rubber materials for special purposes. The properties of rubbers and their vulcanizates are shown, the main manufacturers in the world market are listed. Methods and techniques for the preparation of rubber mixtures based on ethylene-propylene-diene rubbers are presented, including their compatibility with other rubbers and optimal vulcanization conditions. It is concluded that there is a great potential for using ethylene-propylene-diene rubbers in the development of materials with desired properties.

Keywords: rubbers, ethylene-propylene-diene rubber, heat resistance, ozone resistance, compatibility, compatibilizer, vulcanization.

Reference List

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DOI: 10.18577/2071-9140-2019-0-3-31-40

UDC: 678.6

Pages:: 31-40

A.I. Tkachuk1, I.V. Terekhov1, Ya.M. Gurevich1, K.N. Grigoreva2

[1] Federal state unitary enterprise «All-Russian Scientific-Research Institute of Aviation Materials» of National Research Center «Kurchatov Institute»
[2] ALL-RUSSIAN SCIENTIFIC RESEARCH INSTITUTE OF AVIATION MATERIALS, admin@viam.ru

RESEARCH OF THE INFLUENCE OF THE MODIFYING ADDITIVES NATURE ON THE RHEOLOGICAL AND THERMOMECHANICAL PROPERTIES OF A PHOTOPOLYMER COMPOSITION BASED ON EPOXY VINYL ESTER RESIN

The article has investigated the physical-chemical, thermomechanical, and elastic-strength characteristics of samples of a modified epoxy vinyl ester resin, cured under the influence of incoherent UV radiation, with and without subsequent curing in a drying oven. Hexamethylene diisocyanate and diallyl phthalate were used as modifying additives. Using the DSC method, it has been determined that incoherent UV radiation does not allow reaching 99% of the conversion degree in the curable composition, therefore, in order to increase the heat-resistant and mechanical properties, it is necessary to additionally postcure polymer photocompositions. It has been also determined that modification of the epoxy vinyl ester resin leads to an increase in the glass transition temperature and the elastic strength properties of the cured samples.

Keywords: photopolymerization, epoxy vinyl ester resins, UV curing, isocyanates, infrared spectra, thermomechanical and elastic-strength characteristics.

Reference List

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DOI: 10.18577/2071-9140-2019-0-3-41-47

UDC: 678.8

Pages:: 41-47

V.M. Gurenkov1, V.О. Gorshkov1, V.P. Chebotarev1, Т.N. Prudskova1, Т.I. Andreeva1

[1] Joint Stock Company «Institute of plastics named after G.S. Petrov», dir@instplast.ru

COMPARATIVE ANALYSIS OF PROPERTIES OF POLYETHERETHERKETONE OF DOMESTIC AND FOREIGN PRODUCTION

The article is devoted to the problem of import substitution of high-temperature constructional thermoplastics. The results of the study of the properties of polyetheretherketone domestic (Institute of plastics) and foreign (Victrex) production. The current state of Russian production of polyether ether ketone is discussed.
Developed a basic branded assortment of products that meet the assortment of foreign manufacturers.

Keywords: thermoplastics, polyetheretherketone, additive technologies, import substitution.

Reference List

    1. Polyether ketone and method of producing the same: pat. US7217780B2; filed 10.12.02; publ. 21.04.05.

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    4. Moon G.Y., Rhim J.W. Sulfonated peek ion exchange membranes for direct methanol fuel cell applications // Macromolecular research. 2007. Vol. 15. No. 4. R. 379–384.

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    6. Ha S.-W., Hauert R., Ernst K.-H., Wintermantel E. Surface analysis of chemically-etched and plasma-treated polyetheretherketone (PEEK) for biomedical applications // Surface and coatings technology. 1997. Vol. 96. No. 2–3. P. 293–299.

    7. Davim J.P., Reis P., Lapa V., Antonio C.C. Machinability study on polyetheretherketone (PEEK) unreinforced and reinforced (GF30) for applications in structural components // Composite Structures. 2003. Vol. 62. No. 1. P. 67–73.

    8. Normand B., Takenouti H., Keddam M. et al. Electrochemical impedance spectroscopy and dielectric properties of polymer: application to PEEK thermally sprayed coating // Electrochimica Acta. 2004. Vol. 49. No. 17–18. P. 2981–2986.

    9. Sposob polucheniya poliefirketona: pat. 2673242 Ros. Federatsiya [The method of producing polyetherketone: pat. 2673242 Rus. Federation]; zayavl. 27.06.18; opubl. 23.11.18.

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    12. Bikas H., Stavropoulos P., Chryssolouris G. Additive manufacturing methods and modeling approaches: a critical review // International Journal of Advanced Manufacturing Technology. 2016. Vol. 83. P. 389–405.

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    15. Goodridge R.D., Tuck C.J., Hague R.J.M. Laser sintering of polyamides and other polymers // Progress in Materials Science. 2012. Vol. 57. P. 229–267.

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DOI: 10.18577/2071-9140-2019-0-3-48-58

UDC: 667.621

Pages:: 48-58

R.R. Mukhametov1, A.P. Petrova2

[1] ALL-RUSSIAN SCIENTIFIC RESEARCH INSTITUTE OF AVIATION MATERIALS, admin@viam.ru
[2] Federal state unitary enterprise «All-Russian Scientific-Research Institute of Aviation Materials» of National Research Center «Kurchatov Institute»

THERMOSETTING BINDERS FOR POLYMER COMPOSITES (review)

The properties and fields of application of polymeric binders of various classes: polyester, cyan, epoxy vinyl ester, epoxy, phenol formaldehyde, organosilicon, polyimide are considered. The relationship between the rheological properties of the binders and the technological characteristics of their processing is shown. A wide range of developed binders provides  the use of all technologies for the production of composite materials: autoclave molding using the prepreg technology, resin transfer molding (RTM), vacuum assisted resin transfer molding (VARTM), resin film infusion (RFI).

Keywords: binder, melt binder, binder solution, polyester binder, epoxy binder, phenol formaldehyde binder, binder processing technologies.

Reference List

    1. Kablov E.N. Innovacionnye razrabotki FGUP «VIAM» GNC RF po realizacii «Strategicheskih napravlenij razvitiya materialov i tehnologij ih pererabotki na period do 2030 goda» [Innovative developments of FSUE «VIAM» SSC of RF on realization of «Strategic directions of the development of materials and technologies of their processing for the period until 2030»] // Aviacionnye materialy i tehnologii. 2015. №1 (34). S. 3–33. DOI: 10.18577/2071-9140-2015-0-1-3-33.

    2. Kablov E.N. Materialy novogo pokoleniya [New generation materials] // Zashchita i bezopasnost. 2014. №4. S. 28–29.

    3. Chursova L.V., Grebeneva T.A., Panina N.N., Tsybin A.I. Svyazuyushchiye dlya polimernykh kompozitsionnykh materialov stroitelnogo naznacheniya [Binders for polymeric composite materials for construction] // Vse materialy. Entsiklopedicheskiy spravochnik. 2015. №8. S. 13–17.

    4. Alentyev A.Yu., Yablokova M.Yu. Svyazuyushchiye dlya polimernykh kompozitsionnykh materialov [Binders for polymer composites]. M.: MGU im M.V. Lomonosova, 2010. 69 s.

    5. Mishkin S.I., Raskutin A.E., Evdokimov A.A., Gulyaev I.N. Tehnologii i osnovnye etapy stroitelstva pervogo v Rossii arochnogo mosta iz kompozicionnyh materialov [Technologies and the main stages of construction of the arch bridge first in Russia from composite materials] // Trudy VIAM: elektron. nauch.-tehnich. zhurn. 2017. №6 (54). St. 05. Available at: http://www.viam-works.ru (accessed: March 06, 2019). DOI: 10.18577/2307-6046-2017-0-6-5-5.

    6. Mukhametov R.R., Petrova A.P. Svoystva epoksidnykh polimernykh svyazuyushchikh i ikh pererabotka v polimernyye kompozitsionnyye materialy [Properties of epoxy binders and their processing in polymers composition materials] // Novosti materialovedeniya. Nauka i tekhnika: elektron. nauch.-tekhnich. zhurn. 2018. №3–4 (30). St. 06. Available at: http://www.materialsnews.ru (accessed: March 06, 2019).

    7. Muhametov R.R., Petrova A.P., Ponomarenko S.A., Ahmadieva K.R., Pavlyuk B.F. Vliyanie tkanyh voloknistyh napolnitelej razlichnyh tipov na svojstva otverzhdennogo svyazuyushchego VS-2526K [Influence of woven fibrous fillers of various types on properties of cured binder VS-2526K] // Trudy VIAM: elektron. nauch.-tekhnich. zhurn. 2018. №3 (63). St. 04. Available at: http//www.viam-works.ru (accessed: March 06, 2019). DOI: 10.18577/2307-6046-2018-0-3-28-36.

    8. Muhametov R.R., Petrova A.P., Ponomarenko S.A., Dolgova E.V., Pavlyuk B.F. Svojstva svyazuyushchego EDT-69N i PKM na ego osnove [Properties of binder EDT-69N and polymer composites on its basis] // Trudy VIAM: elektron. nauch.-tehnich. zhurn. 2018. №4 (64). St. 04. Available at: http//www.viam-works.ru (accessed: March 06, 2019). DOI: 10.18577/2307-6046-2018-0-4-4-4.

    9. Babin A. N. Svyazujushhie dlya polimernyh kompozicionnyh materialov novogo pokoleniya [Binding for polymeric composite materials of new generation] // Trudy VIAM: elektron. nauch.-tehnich. zhurn. 2013. №4. St. 11. Available at: http://www.viam-works.ru (accessed: March 06, 2019).

    10. Postnova M.V., Postnov V.I. Opyt razvitiya bezavtoklavnyh metodov formovaniya PKM [Development experience out-of-autoclave methods of formation PCM]// Trudy VIAM: ehlektron. nauch.-tekhnich. zhurn. 2014. №4. St. 06. Available at: http://www.viam-works.ru (accessed: March 06, 2019). DOI 10.18577/2307-6046-2014-0-4-6-6.

    11. Panina N.N., Kim M.A., Gurevich Ya.M. i dr. Svyazuyushchiye dlya bezavtoklavnogo formovaniya izdeliy iz polimernykh kompozitsionnykh materialov [Binders for non-autoclaving molding products from polymer composite materials] // Klei. Germetiki. Tekhnologii. 2013. №10. S. 18–27.

    12. Kablov E.N., Chursova L.V., Babin A.N., Mukhametov R.R., Panina N.N. Razrabotki FGUP «VIAM» v oblasti rasplavnykh svyazuyushchikh dlya polimernykh kompozitsionnykh materialov [Developments of FSUE «VIAM» in the field of melt binders for polymer composite materials] // Polimernyye materialy i tekhnologii. 2016. T. 2. №2. S. 37–42.

    13. Muhametov R.R., Ahmadieva K.R., Kim M.A., Babin A.N. Rasplavnye svyazujushhie dlya perspektivnyh metodov izgotovleniya PKM novogo pokoleniya [Melt binding for perspective methods of production of PCM of new generation] // Aviacionnye materialy i tehnologii. 2012. №S. S. 260–265.

    14. Chursova L.V., Panina N.N., Grebeneva T.A., Terekhov I.V., Donetskiy K.I. Termoreaktivnyye svyazuyushchiye i polimernyye bindery dlya polimernykh kompozitsionnykh materialov, poluchayemykh metodom vakuumnoy infuzii [Thermosetting binders and polymer binders for polymer composites obtained by vacuum infusion] // Plasticheskiye massy. 2018. №1–2. S. 57–63.

    15. Chursova L.V., Dushin M.I., Kogan D.I. i dr. Plenochnyye svyazuyushchiye dlya RFI-tekhnologii [Film Binders for RFI Technology] // Rossiyskiy khimicheskiy zhurnal. 2010. T. LIV. №1. S. 63–66.

    16. Kogan D.I., Chursova L.V., Petrova A.P. Tekhnologiya izgotovleniya PKM sposobom propitki plenochnym svyazuyushchim [Manufacturing technology PCM method of impregnation film binder] // Klei. Germetiki. Tekhnologii. 2011. №6. S. 25–29.

    17. Kogan D.I., Chursova L.V., Petrova A.P. Polimernyye kompozitsionnyye materialy, poluchennyye putem propitki plenochnym svyazuyushchim [Polymer composite materials obtained by impregnation with film binder] // Vse materialy. Entsiklopedicheskiy spravochnik. 2011. №11. S. 2–6.

    18. Petrovа A.P., Dementyevа L.A., Lukina N.F., Chursova L.V. Kleevye svjazujushhie dlja polimernyh kompozicionnyh materialov na ugle- i steklonapolniteljah [Adhesive binders for polymer composite materials based on carbon- and glass fillers] // Trudy VIAM: elektron. nauch.-tehnich. zhurn. 2015. №9. St. 11. Available at: http://www.viam-works.ru (accessed: March 06, 2019). DOI: 10.18577/2307-6046-2015-0-9-11-11.

    19. Zastrogina O.B., Shvets N.I., Postnov V.I., Serkova E.A. Fenolformaldegidnye svjazuyushhie novogo pokoleniya dlya materialov interera [Phenolformaldehyde binding new generation for interior materials] // Aviacionnye materialy i tehnologii. 2012. №S. S. 265–272.

    20. Zastrogina O.B., Shvets, N.I., Serkova E.A., Veshkin A.E. Pozharobezopasnyye materialy na osnove fenoloformaldegidnykh svyazuyushchikh [Fireproof materials based on phenol-formaldehyde binders] // Klei. Germetiki. Tekhnologii. 2017. №7. S. 22–27.

    21. Shvets N.I., Zastrogina O.B., Barbotko S.L., Aleksashin V.M. Fenolformaldegidnoye svyazuyushcheye ponizhennoy goryuchesti [Phenol-formaldehyde binder of low flammability] // Pozharovzryvobezopasnost. 2013. T. 22. S. 26–32.

    22. Minakov V.T., Shvets N.I., Zastrogina O.B., Postnov V.I., Chursova L.V., Barbot'ko S.L. Pozharobezopasnyye materialy, ne soderzhashchiye antipirenov, dlya inter'yera passazhirskikh samoletov [Fireproof materials that do not contain flame retardants for the interior of passenger aircraft] // Izvestiya Samarskogo nauchnogo tsentra Rossiyskoy akademii nauk. Spets. vyp.: Chetvert veka izyskaniy i eksperimentov po sozdaniyu unikalnykh tekhnologiy i materialov dlya aviastroyeniya UNTTS-FGUP «VIAM». 2008. S. 24–28.

    23. Davydova I.F., Kavun N.S. Stekloplastiki ‒ mnogofunkcionalnye kompozicionnye materialy [Fibreglasses ‒ multipurpose composite materials] //Aviacionnye materialy i tehnologii. 2012. №S. S. 253–260.

    24. Kitayeva N.S., Minakov V.T., Shvets N.I., Deev I.S., Babin A.N., Ponitkova E.M. 50 let laboratorii «Polimernyye svyazuyushchiye dlya nemetallicheskikh materialov i spetsialnyye zhidkosti» [50 years of the laboratory «Polymeric binders for non-metallic materials and special liquids»]. M.: VIAM, 2010. 30 s.

    25. Davydova I.F., Kablov E.N., Kavun N.S. Termostoykiye negoryuchiye poliimidnyye steklotekstolity dlya izdeliy aviatsionnoy i raketnoy tekhniki [Heat-resistant non-flammable polyimide fiberglass for aviation and rocket technology products] // Vse materialy. Entsiklopedicheskiy spravochnik. 2009. №7. S. 2–11.

    26. Davydova I.F., Kavun N.S. Poliimidnyj steklotekstolit s ponizhennoj temperaturoj otverzhdeniya [Polyimide fiberglass plastic with lower curing temperature] // Trudy VIAM: elektron. nauch.-tehnich. zhurn. 2015. №2. St. 09. Available at: http://www.viam-works.ru (accessed: March 06, 2019). DOI: 10.18577/2307-6046-2015-0-2-8-8.

    27. Gulyaev I.N., Vlasenko F.S., Zelenina I.V., Raskutin A.E. Napravleniya razvitiya termostojkih ugleplastikov na osnove poliimidnyh i geterociklicheskih polimerov [Development Directions of heat-resistant carbon–fiber–reinforced–plastics based on polimide and heterocyclic polymers] // Trudy VIAM: elektron. nauch.-tehni. zhurn. 2014. №1. St. 04. Available at: http://www.viam-works.ru (accessed: March 06, 2019). DOI: 10.18577/2307-6046-2014-0-1-4-4.

    28. Trostyanskaya E.B., Mikhaylin Yu.A., Khokhlova L.F. i dr. Ugleplastiki na osnove polimerizuyushchikhsya imidov API-2 [Carbon plastics based on polymerizing imides API-2] // Voprosy aviatsionnoy nauki i tekhniki. Ser.: Aviacionnye materialy. M.: VIAM, 1985. S. 12–19.

    29. Zharinov M.A., Shimkin A.A., Akhmadiyeva K.R., Zelenina I.V. Osobennosti i svoystva rasplavnogo poliimidnogo svyazuyushchego polimerizatsionnogo tipa [Features and properties of solvent-free PMR-type polyimide resin] // Trudy VIAM: elektron. nauch.-tehnich. zhurn. 2018. №12 (72). St. 05. Available at: http://www.viam-works.ru (accessed: March 06, 2019). DOI: 10.18577/2307-6046-2018-0-12-46-53.

    30. Mukhametov R.R., Merkulova Yu.I., Chursova L.V. Termoreaktivnyye polimernyye svyazuyushchiye s prognoziruyemym urovnem reologicheskikh i deformatsionnykh svoystv // Klei. Germetiki. Tekhnologii. 2012. №5. S. 19–21.

    31. Merkulova Yu.I., Muhametov R.R., Dolgova E.V., Ahmadieva K.R. Policianuratnoe svyazuyushhee dlya polucheniya kompozitov propitkoj pod davleniem [Polycyanurates binding for composites production by impregnation under pressure] // Trudy VIAM: elektron. nauch.-tehnich. zhurn. 2016. №11 (47). St. 05. Available at: http://www.viam-works.ru (accessed: March 06, 2019). DOI: 10.18577/2307-6046-2016-0-11-5-5.

    32. Zheleznyak V.G., Chursova L.V., Merkulova Yu.I., Dolgova E.V. Svyazuyushchiye dlya PKM s povyshennoy vyazkostyu razrusheniya [Binders for PCM with increased fracture toughness] // Klei. Germetiki. Tekhnologii. 2015. №1. S. 26–28.

    33. Zheleznyak V.G., Chursova L.V. Modifikaciya svyazujushhih i matric na ih osnove s celyu povysheniya vyazkosti razrusheniya [Modification of binders and matrixes based on them to increase fracture toughness] // Aviacionnye materialy i tehnologii. 2014. №1. S. 47–50. DOI: 10.18577/2071-9140-2014-0-1-47-50.

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DOI: 10.18577/2071-9140-2019-0-3-59-66

UDC: 621.357.74

Pages:: 59-66

S.S. Vinogradov1, A.A. Nikiforov1, L.I. Zakirova2

[1] ALL-RUSSIAN SCIENTIFIC RESEARCH INSTITUTE OF AVIATION MATERIALS, admin@viam.ru
[2] Federal state unitary enterprise «All-Russian Scientific-Research Institute of Aviation Materials» of National Research Center «Kurchatov Institute»

CADMIUM REPLACEMENT. STAGE 2 – FINAL. GALVANIC THERMAL COATING OF  ZINC–TIN SYSTEM – REAL ALTERNATIVE TO CADMIUM PLATING

In VIAM the galvanic thermal coating of zinc–tin system possessing high protective ability has been developed and patented: with cut to steel basis for more than 6000 h in the salt spray chamber, this corresponds to protective ability of cadmium coating. Forming of galvanic thermal coating of the zinc–tin system is as follows: consecutive electrochemical plating of zinc and tin layers, thermal processing at temperature not higher than 200°С and such duration at which there is no «germination» of hypereutectic tin-zinc alloy through tin layers.

Keywords: galvanic thermal coating, cadmium plating, level-by-level plating, thermal processing, alloy tin-zinc, protective ability, electrochemical researches, adhesion, mechanical properties of carbon steels.

Reference List

    1. Kablov E.N. Korroziya ili zhizn [Corrosion or life] // Nauka i zhizn. 2012. №11. S. 16–21.

    2. Kablov E.N., Startsev O.V. Fundamentalnye i prikladnye issledovaniya korrozii i stareniya materialov v klimaticheskih usloviyah (obzor) [The basic and applied research in the field of corrosion and ageing of materials in natural environments (review)] // Aviacionnye materialy i tehnologii. 2015. №4 (37). S. 38–52. DOI: 10.18577/2071-9140-2015-0-4-38-52.

    3. Kablov E.N. Innovacionnye razrabotki FGUP «VIAM» GNC RF po realizacii «Strategicheskih napravlenij razvitiya materialov i tehnologij ih pererabotki na period do 2030 goda» [Innovative developments of FSUE «VIAM» SSC of RF on realization of «Strategic directions of the development of materials and technologies of their processing for the period until 2030»] // Aviacionnye materialy i tehnologii. 2015. №1 (34). S. 3–33. DOI: 10.18577/2071-9140-2015-0-1-3-33.

    4. GN 2.2.5.3532–18. Predelno dopustimyye kontsentratsii (PDK) vrednykh veshchestv v vozdukhe rabochey zony: utv. Postanovleniyem Glavnogo gosudarstvennogo sanitarnogo vracha Rossiyskoy Federatsii 13.02.2018: vvod. v dejstvie 03.05.2018.

    5. Glushko Ya.M. Vrednye neorganicheskiye soyedineniya v promyshlennykh stochnykh vodakh: spravochnik [Harmful inorganic compounds in industrial wastewater: guide]. L.: Khimiya, 1979. 160 s.

    6. Bondar V.V., Grinina V.V., Pavlov V.N. Elektroosazhdeniye dvoynykh splavov [Electrodeposition of double alloys] // Itogi nauki i tekhniki. Elektrokhimiya. M.: VINITI, T. 16. 1980. 331 s.

    7. Galvanicheskiye pokrytiya v mashinostroyenii: spravochnik v 2 t. / pod red. M.A. Shlugera, L.D. Toka [Electroplated coatings in mechanical engineering: reference book in 2 vol. / ed. M.A. Shluger, L.D. Tok]. M.: Mashinostroyeniye, 1985. T. 1. 240 s.

    8. Vyacheslavov P.M. Elektroliticheskoye osazhdeniye splavov [Electrolytic deposition of alloys]. L.: Mashinostroyeniye, 1986. 112 s.

    9. Azhogin F.F., Belenkiy M.A., Gal I.E. i dr. Galvanotekhnika [Electroplating]. M.: Metallurgiya, 1987. S. 484–485.

    10. Corrosion resistant coating system and method: pat. US 6613452; filed 16.01.01; publ. 02.09.03.

    11. Sposob naneseniya kombinirovannogo zashchitnogo pokrytiya na stalnye detali: pat. 2427671 Ros. Federatsiya [The method of applying a combined protective coating on steel parts: pat. 2427671 Rus. Federation]; zayavl. 18.08.10. opubl. 27.08.11.

    12. Sposob polucheniya pokrytiya dlya zashchity ot korrozii stalnykh detaley: pat. 2177055 Ros. Federatsiya [A method of obtaining a coating for corrosion protection of steel parts: pat. 2177055 Rus. Federation]; zayavl. 30.03.00; opubl. 20.12.01.

    13. Vinogradov S.S., Nikiforov A.A., Balahonov S.V. Zamena kadmiya. Etap 1. Povyshenie zashhitnoj sposobnosti cinkovyh pokrytij: termoimmersionnoe i modificirovannoe pokrytiya [Cadmium replacement. Part 1. Improving of protective property of zinc coatings: thermo-immersed and modified coatings] // Aviacionnye materialy i tehnologii. 2015. №4 (37). S. 53–60. DOI: 10.18577/2071-9140-2015-0-4-53-60.

    14. Sposob polucheniya zashchitnogo pokrytiya: pat. 2606364 Ros. Federatsiya [A method of obtaining a protective coating: pat. 2606364 Rus. Federation]; zayavl. 15.10.15. opubl. 10.01.17.

    15. Kablov E.N., Nikiforov A.A., Demin S.A., Chesnokov D.V., Vinogradov S.S. Perspektivnyye pokrytiya dlya zashchity ot korrozii uglerodistykh staley [Promising coatings for corrosion protection of carbon steels] // Stal. 2016. №6. S. 70–81.

    16. Vinogradov S.S., Nikiforov A.A., Demin S.A. Puti resheniya problemy zameny kadmiyevogo pokrytiya [Ways to solve the problem of cadmium coating replacement] // Galvanotekhnika i obrabotka poverkhnosti. 2018. T. 26. №2. S. 13–25.

    17. Vinogradov S.S., Nikiforov A.A., Demin S.A., Chesnokov D.V. Zashchita ot korrozii uglerodistykh stalej [Protection against corrosion of carbon steel] // Aviacionnye materialy i tehnologii. 2017. №S. S. 242–263. DOI: 10.18577/2071-9140-2017-0-S-242-263.

    18. GOST 9.005–72. Dopustimyye i nedopustimyye kontakty metallov. Obshchiye trebovaniya [State Standard 9.005–72. Admissible and unacceptable metal contacts. General requirements]. M.: Izd-vo standartov, 1972. 27 s.

    19. Diagrammy sostoyaniya dvoynykh metallicheskikh sistem: spravochnik v 3 t. / pod obshch. red. N.P. Lyakisheva [State diagrams of double metal systems: guide in 3 vol. / ed. N.P. Lyakishev]. M.: Mashinostroyeniye, 2000. T. 3, kn. 2. S. 340–341.

    20. Kovenskiy I.M. Otzhig elektroosazhdennykh metallov i splavov [Annealing of electrodeposited metals and alloys]. Tyumen: TyumGNGU, 1995. 92 s.

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DOI: 10.18577/2071-9140-2019-0-3-67-74

UDC: 621.78

Pages:: 67-74

D.P. Farafonov1, N.E. Leshchev2, A.N. Afanasiev-Khodykin1, N.I. Artemenko2

[1] ALL-RUSSIAN SCIENTIFIC RESEARCH INSTITUTE OF AVIATION MATERIALS, admin@viam.ru
[2] Federal state unitary enterprise «All-Russian Scientific-Research Institute of Aviation Materials» of National Research Center «Kurchatov Institute»

ABRASIVE WEAR-RESISTANT SEAL MATERIALS OF THE GAS TURBINE ENGINE FLOW SECTION

The paper provides the main results of the works performed by VIAM Federal State Unitary Enterprise devoted to the improvement of wear resistance of seals in gas turbine engines. There are examined the tribotechnical characteristics of wear-resistant and composite abrasive materials and coatings obtained by different methods, such as: detonation spraying, electrosedimentation, vacuum soldering. Some abrasive and wear-resistant materials the basis of which represents a metal matrix with the particles of hard high-melting compounds dispersed in it are developed.

Keywords: abrasive wear-resistant material, blades tips, abrasive coatings, sealing materials, durability, gas-turbine engine.

Reference List

    1. Inozemtsev A.A., Sandratskiy V.L. Gazoturbinnyye dvigateli [Gas turbine engines]. Perm: Aviadvigatel, 2006. S. 278–280.

    2. Greshta V., Tkach D., Sotnikov Ye. et al. Studing and designing improved coatings for labyrinth seals of gas-turbine engine turbines // Eastern-European Journal of Enterprise Technologies. 2018. Vol. 4/12 (94). P. 56–63.

    3. Farafonov D.P., Migunov V.P., Sarayev A.A., Leshchev N.E. Istirayemost i erozionnaya stoykost uplotnitelnykh materialov protochnoy chasti GTD [Abradability and erosion resistance of seals in turbine engine air-gas channel] // Trudy VIAM: elektron. nauch.-tehnich. zhurn. 2018. №8 (68). St. 07. Available at: http://www.viam-works.ru (accessed: March 14, 2019). DOI: 10.18577/2307-6046-2018-0-8-70-80.

    4. Wilson S. Overview of Sulzer Metco compressor and turbine abradable technology // 8th International Charles Parsons Turbine Conference. 2011. Available at: http://www.iom3.org/sites/default/files/iom3-corp/wed%200940%20s%20Wilso... (accessed: March 14, 2019).

    5. Simms N.J., Norton J.F., McColvin G. Performance of candidate gas turbine abradeable seal materials in high temperature combustion atmospheres // Materials and Corrosion. 2005. Vol. 56. P. 765–777.

    6. Bill R.C., Ludwig L.P. Wear of seal materials used in aircraft // Wear. 1980. Vol. 59. P. 165–189.

    7. Migunov V.P. Materialy dlya uplotneniya gazovogo kontura v kompressore i turbine [Materials for sealing the gas circuit in the compressor and the turbine] // Aviacionnye materialy i tehnologii. 2003. №1. S. 165–169.

    8. Afanasev-Khodykin A.N., Rylnikov V.S., Farafonov D.P. Tekhnologiya pajki poristo-voloknistogo materiala iz splava tipa «fekhral» dlya uplotneniya protochnoj chasti GTD [Technology soldering porous fibrous material of the alloy of the «fehral» to seal the flow part of GTE] // Trudy VIAM: elektron. nauch.-tehnich. zhurn. 2014. №1. St. 02. Available at: http://www.viam-works.ru (accessed: March 14, 2019). DOI: 10.18577/2307-6046-2014-0-1-2-2.

    9. Smarsly W., Zheng N., Buchheim C.S. et al. Advanced High Temperature Turbine Seals Materials and Designs // Material Science Forum. 2005. Vol. 492–493. P. 21–26.

    10. Davenport J.R., Mendez-Garcia L., Purkayastha S. et al. Material needs for turbine sealing at high temperature // Materials Science and Technology. 2014. Vol. 30. No 15. P. 1877–1883.

    11. Kablov E.N. Innovacionnye razrabotki FGUP «VIAM» GNC RF po realizacii «Strategicheskih napravlenij razvitiya materialov i tehnologij ih pererabotki na period do 2030 goda» [Innovative developments of FSUE «VIAM» SSC of RF on realization of «Strategic directions of the development of materials and technologies of their processing for the period until 2030»] // Aviacionnye materialy i tehnologii. 2015. №1 (34). S. 3–33. DOI: 10.18577/2071-9140-2015-0-1-3-33.

    12. Kablov E.N. Materialy novogo pokoleniya – osnova innovatsiy, tekhnologicheskogo liderstva i natsionalnoy bezopasnosti Rossii [Kablov E.N. Materials of the new generation - the basis of innovation, technological leadership and national security of Russia] // Intellekt i tekhnologii. 2016. №2 (14). S. 16–21.

    13. Kablov E.N. Strategicheskie napravleniya razvitiya materialov i tehnologij ih pererabotki na period do 2030 goda [The strategic directions of development of materials and technologies of their processing for the period to 2030] // Aviacionnye materialy i tehnologii. 2012. №S. S. 7–17.

    14. Farafonov D.P., Bazyleva O.A., Rogalev A.M. Splavy dlya uprochneniya bandazhnyh polok rabochih lopatok GTD [Alloys for blade shroud hardening] // Trudy VIAM: elektron. nauch.-tehnich. zhurn. 2016. №9. St. 07. Available at: http://www.viam-works.ru (accessed: March 15, 2019). DOI: 10.18577/2307-6046-2016-0-9-7-7.

    15. Coating forming method and coating forming material, and abrasive coating forming sheet: pat. 7063250 B2 US; field 13.05.04; publ. 20.07.06.

    16. Abrasive coating and manufacture and use methods: pat. 10018056 B2 US; field 25.06.2015; publ. 10.07.18.

    17. Wear-resistant coating and method for applying it: pat. 6811898 B2 US; field 01.04.03; publ. 2.11.04.

    18. Kablov E.N., Muboyadzhyan S.A. Erozionnostoykiye pokrytiya dlya lopatok kompressora gazoturbinnykh dvigateley [Erosion-resistant coatings for compressor blades for gas turbine engines] // Elektrometallurgiya. 2016. №10. S. 23–38.

    19. Kablov E.N., Muboyadzhyan S.A., Budinovskiy S.A., Egorova L.N., Lutsenko A.N., Galoyan A.G. Zashchitnyye i uprochnyayushchiye pokrytiya lopatok i detaley GTD [Protective and hardening coatings of blades and parts of the CCD] // 75 let. Aviatsionnyye materialy. M.: VIAM, 2007. S. 107–124.

    20. Aleksandrov D.A., Artemenko N.I. Iznosostojkie pokrytiya dlya zashhity detalej treniya sovremennyh GTD [Wear-resistant coatings to protect friction parts of modern gas turbine engines] // Trudy VIAM: elektron. nauch.-tehnich. zhurn. 2016. №10. St. 06. Available at: http://www.viam-works.ru (accessed: March 15, 2019). DOI: 10.18577/2307-6046-2016-0-10-6-6.

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DOI: 10.18577/2071-9140-2019-0-3-75-82

UDC: 669.017

Pages:: 75-82

S.P. Konokotin1, R.M. Nazarkin1

[1] ALL-RUSSIAN SCIENTIFIC RESEARCH INSTITUTE OF AVIATION MATERIALS, admin@viam.ru

THЕ TRAVELLING MAGNETIC FIELD OF BIPOLAR ELECTROMAGNETIC INDUCTOR AND ITS INFLUENCE ON THE PROPERTIES OF Cr- AND Ni-BASED POLYCRYSTALLINE ALLOYS. Part 2

For the increase of physical and mechanical properties of the Ni-based alloys by technique of equiaxial solidification in the traveling magnetic field, the design of the bipolar cylindrical electromagnetic inductor is studied. The application of the improved design of electromagnetic inductor is provided at the solidification of alloys: change of alloy microstructure, formation of directional crystallographic structure in the castings, change of phase composition and increase of heat resistance at 1250°C.

Keywords: bipolar electromagnetic inductor, traveling magnetic field, Cr-based alloys, Ni-ased alloys, alloy solidification, crystallographic texture, x-ray diffraction analysis, mechanical properties.

Reference List

    1. Kablov E.N., Petrushin N.V., Parfenovich P.I. Konstruirovaniye liteynykh zharoprochnykh nikelevykh splavov s polikristallicheskoy strukturoy [Design of heat-resistant nickel alloys with a polycrystalline structure] // Metallovedeniye i termicheskaya obrabotka metallov. 2018. №2 (752). S. 47–55.

    2. Bazyleva O.A., Arginbayeva E.G., Lutskaya S.A. Metody povysheniya korrozionnoy stoykosti zharoprochnykh nikelevykh splavov (obzor) [Ways of increasing corrosion resistance of superalloys (review)] // Trudy VIAM: elektron. nauch.-tehnich. zhurn. 2018. №4. St. 01. Available at: http://www.viam-works.ru (accessed: September 03, 2018). DOI: 10.18577/2307-6046-2018-0-4-3-8.

    3. Wang J., Qian J., Zhang X., Wang Y. Research status and progress of NiAl based alloys as high temperature structure materials // Rare Metals. 2011. Vol. 30. Suppl. 1. P. 422–426.

    4. Petrushin N.V., Svetlov I.L., Ospennikova O.G. Liteynyye zharoprochnyye nikelevyye splavy [Heat-resistant foundry nickel alloys] // Vse materialy. Entsiklopedicheskiy spravochnik. 2012. №6. S. 16–21.

    5. Sims C.T., Stoloff N.S., Hagel W.C. Superalloys II: High-Temperature Materials for Aerospace and Industrial Power. N.-Y.: John Wiley & Sons, 1987. 640 p.

    6. Kablov E.N., Petrushin N.V., Elyutin E.S. Monokristallicheskiye zharoprochnyye splavy dlya gazoturbinnykh dvigateley [Monocrystalline heat-resistant alloys for gas turbine engines] // Vestnik MGTU im. N.E. Baumana. Ser.: Mashinostroyeniye. 2011. №SP2. S. 38–52.

    7. Kablov E.N., Ospennikova O.G., Svetlov I.L. Vysokoeffektivnoe ohlazhdenie lopatok goryachego trakta GTD [Highly efficient cooling of GTE hot section blades] // Aviacionnye materialy i tehnologii. 2017. №2 (47). S. 3–14. DOI: 10.18577/2071-9140-2017-0-2-3-14.

    8. Grinberg B.A., Ivanov M.A. Intermetallidy Ni3Al i TiAl: mikrostruktura, deformatsionnoye povedeniye [Intermetallides Ni3Al and TiAl: microstructure, deformation behavior]. Ekaterinburg: Izd-vo UrO RAN, 2002. 360 s.

    9. Povarova K.B., Drozdov A.A., Bazyleva O.A., Morozov A.E., Antonova A.V., Bondarenko Yu.A., Bulakhtina M.A., Ashmarin A.A., Arginbayeva E.G., Aladin N.A. Konstruktsionnyye zharostoykiye (b-NiAl+γ′-Ni3Al) splavy sistemy Ni–Al–Co. I. Osobennosti kristallizatsii i struktury splavov [Structural heat-resistant (β-NiAl+γ′-Ni3Al) alloys of the Ni–Al–Co system. I. Features of crystallization and structure of alloys] // Metally. 2017. №5. S. 20–30.

    10. Povarova K.B., Drozdov A.A., Bazyleva O.A., Morozov A.Ye., Antonova A.V., Arginbayeva E.G., Aladin N.A., Sirotinkin V.P. Konstruktsionnyye zharostoykiye (b-NiAl+γ′-Ni3Al) splavy sistemy Ni–Al–Co. II. Osobennosti kristallizatsii i struktury splavov [Structural heat-resistant (β-NiAl+γ′-Ni3Al) alloys of the Ni – Al – Co system. II. Features of crystallization and alloy structure] // Metally. 2017. №5. S. 31–36.

    11. Li H.T., Wang Q., Wang K. et al. Improvement of compressive strength and ductility in NiAl based eutectic alloy by uniform high magnetic field treatment // Intermetallics. 2011. Vol. 19. Issue 2. P. 187–190.

    12. Nikrityuk P.A., Eckert K., Grundmann R. Electromagnetically Forced Swirling Flow During Solidification of a Binary Metal alloy // Journal of Computational and Applied Mechanics. 2004. Vol. 5. No. 2. P. 337–352.

    13. Verte L.A. MGD-tekhnologiya v proizvodstve chernykh metallov [MHD technology in the production of ferrous metals]. M.: Metallurgiya, 1990. 119 s.

    14. Samoylov A.I., Konokotin S.P., Roshchina I.N. i dr. Povysheniye plastichnosti materialov kristallizatsiyey v elektromagnitnom pole [Increasing the ductility of materials by crystallization in an electromagnetic field] // Aviacionye materialy i tehnologii. 2008. Vyp. 1. S. 32–37.

    15. Bolkhovitov N.F. Metallovedeniye i termicheskaya obrabotka. M.: Mashgiz, 1961. S. 17.

    16. Mneyan M.G. Novyye professii magnita [Metal science and heat treatment]. M.: Prosveshcheniye, 1985. S. 28–35.

    17. Konokotin S.P., Moiseyeva N.S. Vliyaniye metoda kristallizatsii na strukturu splava sistemy Ni–Al posle vysokotemperaturnogo nagreva [The influence of the crystallization method on the structure of the alloy of the Ni – Al system after high-temperature heating] // Metallurgiya mashinostroyeniya. 2013. №4. S. 27–31.

    18. Konokotin S.P., Moiseeva N.S. Povyshenie fiziko-mehanicheskih svojstv splavov na osnove hroma i sistemy Ni–Al, sklonnyh k hladnolomkosti, metodom ravnoosnoj kristallizacii v elektromagnitnom pole [An increase of physical and mechanical properties of Cr-based and Ni–Al alloys by using the equiaxed crystallization in electromagnetic field] // Aviacionnye materialy i tehnologii. 2015. №3 (36). S. 15–26. DOI: 10.18577/2071-9140-2015-0-3-15-26.

    19. Nazarkin R.M., Konokotin S.P. Vliyaniye obrabotki elektromagnitnym polem pri kristallizatsii na mekhanicheskiye svoystva splavov sistem Ni–Al i Co–Cr–Al–Ni [Influence of electro-magnetic field treatment at the solidification process on mechanical properties of Ni–Al and Co–Cr–Al–Ni alloys] // Trudy VIAM: elektron. nauch.-tehnich. zhurn. 2017. №5 (53). St. 10. Available at: http://www.viam-works.ru (accessed: September 03, 2018). DOI: 10.18577/2307-6046-2017-0-5-10-10.

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11.

DOI: 10.18577/2071-9140-2019-0-3-83-88

UDC: 620.179

Pages:: 83-88

A.S. Boychuk1, I.A. Dikov1, A.S. Generalov1

[1] Federal state unitary enterprise «All-Russian Scientific-Research Institute of Aviation Materials» of National Research Center «Kurchatov Institute»

THE INCREASE OF SENSITIVITY AND RESOLUTION OF FRP SOLID SAMPLES NONDESTRUCTIVE ULTRASONIC TESTING USING THE ULTRASONIC PHASED ARRAY 

Wide scatter of the defined values is observed during the testing of Fibre-Reinforced Plastics (FRP) solid-cast samples for definition of their physical and mechanical properties. One of the factors affecting this scatter is the presence of internal defects in the test samples. Nowadays the nondestructive inspection sensitivity of FRP solid-cast sample structures which equals to 5 mm diameter flat bottom hole detection is insufficient for detection of defects affecting the mechanical test results. This article gives the test results and shows that it is possible to increase the sensitivity and resolution of CFRP and GFRP solid-cast samples ultrasonic testing by using ultrasonic beam focusing,  increasing the number of elements in phased array transducer in electronic scanning group and decreasing scanning pitch.

Keywords: polymer composite materials, nondestructive testing, ultrasonic testing, phased array, sensitivity, resolution.

Reference List

    1. Kablov E.N. Iz chego sdelat budushcheye? Materialy novogo pokoleniya, tekhnologii ikh sozdaniya i pererabotki – osnova innovatsiy [What to make the future from? Materials of the new generation, technologies of their creation and processing - the basis of innovation] // Krylya Rodiny. 2016. №5. S. 8–18.
    2. Savin S.P. Primeneniye sovremennykh polimernykh kompozitsionnykh materialov v konstruktsii planera samoletov semeystva MS-21 [The use of modern polymer composite materials in the construction of a glider of airplanes of the MS-21 family] // Izvestiya Samarskogo nauchnogo tsentra Rossiyskoy akademii nauk. 2012. T. 14. №4 (2). S. 686–693.
    3. Timoshkov P.N., Platonov A.A., Hrulkov A.V. Propitka plenochnym svyazuyushhim (RFI) kak perspektivnaya bezavtoklavnaya tehnologiya polucheniya izdelij iz PKM [Film resin infusion as an advanced method for out-of-autoclave processing of polymer composites] // Trudy VIAM: elektron. nauch.-tehnich. zhurn. 2015. №5. St. 09. Available at: http://www.viam-works.ru (accessed: February 05, 2019). DOI: 10.18577/2307-6046-2015-0-5-9-9.
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DOI: 10.18577/2071-9140-2019-0-3-89-94

UDC: 579.8

Pages:: 89-94

A.A. Krivushina1, T.V. Bobyreva1, T.V. Yakovenko2, E.V. Nikolaev1

[1] Federal state unitary enterprise «All-Russian Scientific-Research Institute of Aviation Materials» of National Research Center «Kurchatov Institute»
[2] ALL-RUSSIAN SCIENTIFIC RESEARCH INSTITUTE OF AVIATION MATERIALS, admin@viam.ru

METHODS OF MICROORGANISMS-DESTRUCTORS STORAGE IN FSUE «VIAM» COLLECTION (review)

Cultures of microorganisms-destructors are used for testing the microbiological resistance of materials and products. The collection in the laboratory of FSUE «VIAM» numbers over a hundred of strains of microorganisms collected from various climatic zones. Various methods of microorganism culture storage are used to preserve the collection. Short-term methods include subculturing and storage on samples of biodegradable materials. Long-term methods include the method of cryogenic freezing and lyophilization. All four methods of storage are used to preserve the viability and the necessary physiological properties of strains of microorganisms-destructors.

Keywords: biodeterioration, microorganisms-destructors, microbiological resistance, storage methods, subculturing, freezing, lyophilization

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