Source: http://viam-works.ru/en/articles?year=2014&num=1
Timestamp: 2019-04-22 07:02:37+00:00

Document:
Gayamov A.M., Budinovskiy S.A., Muboyadzhyan S.A., Kosmin A.A.
Selection of heat-resistant coating with metalloceramic barrier layer for protection of details made of Re-Ru nickel-based superalloy operating at 1150°С is made. High-temperature tests of isothermic and cyclic heat-resistance and research of structure after these tests are made. Results show that the Ni–Cr–Al–Ta–Hf–Re–Y barrier layer containing tungsten carbide particles effectively suppresses forming of the secondary reaction zone. Heat-resistant coatings for Re-Ru superalloy reduce corrosion level up to a dosens of times.
1. Kablov E.N., Petrushin N.V., Svetlov I.L., Demonis I.M. Nikelevye liteynye garoproshnye splavy novogo pokoleniya [Nickel heat-resistant casting alloys of new generation] //Aviatsionnye materialy i tekhnologii. 2012. №S. S. 36–52.
2. Ospennikova O.G. Strategiya razvitiya zharoprochnykh splavov i staley special’nogo naznacheniya, zashchitnykh pokrytiy [Development strategy of heat-resistant alloys and special-purpose steels, protective and thermal-protective coatings] //Aviatsionnye materialy i tekhnologii. 2012. №S. S. 19–36.
3. Kablov E.N. Strategicheskie napravleniya razvitiya materialov i tekhnologii ikh pere-rabotki na period do 2030 goda [Strategic directions of the development of materials and technologies of their processing for the period until 2030] //Aviatsionnye materialy i tekhnologii. 2012. №S. S. 7–17.
4. Zharoprochnyy splav na nikelevoy osnove dlya monokristallicheskogo lit’ya [Nickel-based heat-resistant alloy for single crystal casting]: pat. 2439184 Ros. Federatsiya; opybl. 05.10.2010.
5. Zharoprochnyy splav na osnove nikelya [Nickel-based heat-resistant alloy]: pat. 2402624 Ros. Federatsiya; opybl. 16.06.2009.
6. Zharoprochnyy liteynyy splav na osnove nikelya i izdelie, vypolnennie is nego [Nickel-based heat-resistant alloy and a product made thereof]: pat. 2365656 Ros. Federatsiya; opybl. 30.01.2008.
7. Kablov E.N., Muboyadzhyan S.A. Zhrostoykie i teplozashchitnye pokrytiya dlya lopatok turbiny vysokogo davleniya perspektivnykh GTD [Heat-resistant and thermal-protective coatings for the high-pressure turbine blades of promising GTEs] //Aviatsionnye materialy i tekhnologii. 2012. №S. S. 60–70.
8. Matveev P.V., Budinovskiy S.A., Muboyadzhyan S.A., Kos’min A.A. Zashchitny zharostoykie pokrytiya slya splavov na osnove intermetallidiv nikelya [Protective heat-resistant coatings for alloys based on nickel intermetallic compounds] //Aviatsionnye materialy i tekhnologii. 2012. №2. S. 12–15.
9. Kablov E.N., Muboyadzhyan S.A. Heat-resistant coatings for the high-pressure turbine blades of promising gtes [Heat-resistant coatings for the high-pressure turbine blades of promising GTEs] //Russian metallurgy (Metally). 2012. №1. P. 1–7.
10. Suzuki A., Rae C.M.F. Secondary reaction zone formations in coated Ni-base single crystal superalloys [Secondary reaction zone formations in coated Ni-base single crystal superalloys] //Journal of Physics: Conference Series 2009. Р. 165.
11. Suzuki A., Rae C.M.F., Hobbs R.A., Murakami H. Secondary reaction zone formations in Pt-Aluminised fourth generation Ni-base single crystal superalloys [Secondary reaction zone formations in Pt-Aluminised fourth generation Ni-base single crystal superalloys] //Advanced Materials Research. 2011. V. 278. P. 78–83.
12. Muboyadzhyan S.A., Budinovskiy S.A., Gayamov A.M., Matveev P.V. Vysokotemperaturnye zharostoykie pokrytiya i zharostoykie sloi dlya teplozashchitnykh pokrytiy [High-temperature heat-resistant coatings and heat-resistant layers for thermal-protective coatings] //Aviatsionnye materialy i tekhnologii. 2012. №1. S. 17–20.
13. Budinovskiy S.A., Muboyadzhyan S.A., Gayamov A.M., Kos’min A.A. Zharostoykie ionnoplazmennye pokrytiya dlya lopatok turbin iz nikelevykh splavov, legirovannykh reniem [Heat-resistant plasma-ion coatings for the turbine blades made of rhenium-alloyed nickel alloys] //MiTOM. 2008. №6. S. 31–36.
14. Budinovskiy S.A., Muboyadzhyan S.A., Gayamov A.M., Stepanova S.V. Ionno-plazmennye zharostoykie pokrytiya s kompozitsionnym bar’ernym sloem dlya zashchity ot okisleniya splava ZhS36VI [Heat-resistant plasma-ion coatings with composite barrier layer for protection of ZhS36VI alloy from oxidation] //MiTOM. 2011. №1. S. 34–40.
15. Gayamov A.M. Zharostoykie pokrytiya s kompozitsionnym bar’ernym sloem dlya zashchity vneshney poverkhnosti rabochikh lopatok GTD iz reniysoderzhashchikh zharoprochnykh nikelevykh splavov [Heat-resistant coating with composite barrier layer to protect the outer surface of the GTE blades made of heat-resistant rhenium-bearing nickel alloys] /V sb. materialov XI Rossiyskoy ezhegodnoy konf. molodykh nautsnykh sotrudnikov i aspirantov „Fiziko-khimiya i tekhnologiya neorganicheskikh materialov”. M.: IMET RAN. 2012. S. 473–475.
16. Muboyadzhyan S.A., Lutsenko A.N., Aleksandrov D.A., Gorlov D.S. Issledovanie vozmozhnosti povysheniya sluzhebnykh kharakteristik lopatok kompressora GTD metodom ionnogo modifitsirovaniya poverkhnosti [Study of possibility to improve the service performance of GTE compressor blades by the ionic-modification of surfaces] //Trudy VIAM. 2013. №1. St. 01 (viam-works.ru).
Afanasiev-Khodykin A.N., Rylnikov V.S., Farafonov D.P.
This article contains information about a new porous fibrous sealing material for sealing the flow of the gas turbine engine. Highlight features of its brazing. The results of testing various solders for the brazing of porous fibrous sealant. Provides basic in-formation about the new composite solder iron base specifically designed for brazing porous fibrous sealant type alloy «fehral».
1. Kablov E.N. Strategicheskie napravleniya razvitiya materialov i tehnologiy ih pererabotki na period do 2030 goda [Strategic approaches to the development of materials and technologies of their processing for the period until 2030] //Aviatsionnye materialy i tehnologii. 2012. №S. S. 7–17.
2. Ospennikova O.G. Strategiya razvitiya zharoprochnyh splavov i staley spetsial'nogo naznacheniya, zaschitnyh i teplozaschitnyh pokrytiy [Development strategy of heat-resistant alloys and special-purpose steels, protective and thermal-protective coatings] //Aviatsionnye materialy i tehnologii. 2012. №S. S. 19–35.
3. Kablov E.N., Muboyadzhyan S.A. Zharostoykie i teplozaschitnye pokrytiya dlya lopatok turbiny vysokogo davleniya perspektivnyh GTD [Heat-resistant and thermal-protective coatings for the high-pressure turbine blades of promising GTEs] //Aviatsionnye materialy i tehnologii. 2012. №S. S. 60–70.
4. Kablov E.N., Bondarenko Yu.A., Echin A.B., Surova V.A. Razvitie protsessa napravlennoy kristallizatsii lopatok GTD iz zharoprochnyh splavov s monokristallicheskoy i kompozitsionnoy strukturoy [Development of directional solidification process in the GTE blades made of heat-resistant alloys with single crystal and composite structure] //Aviatsionnye materialy i tehnologii. 2012. №1. S. 3–8.
5. Kablov E.N. Litye lopatki gazoturbinnyh dvigateley [Cast blades of gas-turbine engines]. M.: MISIS. 2001. 632 s.
6. Kablov E.N., Ospennikova O.G., Bazyleva O.A. Materialy dlya vysokoteplonagruzhennyh detaley gazoturbinnyh dvigateley [Materials for highly thermal-loaded parts of gas-turbine engines] //Vestnik MGTU im. N.E. Baumana. 2011. Spets. vyp. «Perspektivnye konstruktsionnye materialy i tehnologii». S. 13–19.
7. Ryl'nikov V.S., Afanas'ev-Hodykin A.N., Krasikov M.I. Issledovanie remontnoy tehnologii ispravleniya defektov payanyh soedineniy toplivnyh kollektorov [Study of repair technology to correct the defects of soldered joints in fuel manifolds] //Trudy VIAM. 2013. №12. St. 02 (viam-works.ru).
8. Lashko N.F., Lashko S.V. Voprosy teorii i tehnologii payki [Theoretical and practical issues of soldering]. M.: Izd-vo Saratovskogo un-ta. 1974. 248 s.
9. Lashko N.F., Lashko S.V. Payka metallov [Soldering metals]. M.: Mashinostroenie. 1967. 368 s.
10. Horunov V.F., Maksimova S.V. Payka zharoprochnyh splavov na sovremennom etape [Soldering of heat-resistant alloys at the current stage] //Svarochnoe proizvodstvo. 2010. №10. S. 24–27.
11. Lukin V.I., Ryl'nikov V.S., Afanas'ev-Hodykin A.N. Osobennosti polucheniya payanyh soedineniy iz splava ZhS36 [Peculiarities of soldered joints of ZhS36 alloy] //Tehnologiya mashinostroeniya. 2010. №5. S. 21–25.
12. Lukin V.I., Ryl'nikov V.S., Afanas'ev-Hodykin A.N., Orehov N.G. Osobennosti payki monokristallicheskih otlivok iz splava ZhS32 [Peculiarities of ZhS 32 alloy single crystal castings soldering] //Svarochnoe proizvodstvo. 2012. №5. S. 24–30.
13. Kablov E.N., Evgenov A.G., Ryl'nikov V.S., Afanas'ev-Hodykin A.N. Issledovanie melkodispersnyh poroshkov pripoev dlya diffuzionnoy vakuumnoy payki, poluchennyh metodom atomizatsii rasplava [Research of solder fine powders for diffusion vacuum soldering, obtained by melt atomization] //Vestnik MGTU im. N.E. Baumana. Ser. «Mashinostroenie». 2011. Spets. vyp. «Perspektivnye konstruktsionnye materialy i tehnologii». S. 79–87.
14. Shmotin Yu.N., Starkov R.Yu., Danilov R.V., Ospennikova O.G., Lomberg B.S. Novye materialy dlya perspektivnogo dvigatelya OAO «NPO „Saturn”» [New materials for advanced engine of JSC NPO SATURN] //Aviatsionnye materialy i tehnologii. 2012. №2. S. 6–8.
Consideration high-temperature erosion and functional of coatings for heat- protec-tion, heat-insulation, pack condense materials and technology coatings. Demonstration results testings and effectiveness of sol-gel technology repairs, marking and other func-tional coatings.
2. Ospennikova O.G. Strategiya razvitiya zharoprochnyh splavov i staley spetsial'nogo naznacheniya, zaschitnyh i teplozaschitnyh pokrytiy [Development strategy of heat-resistant alloys and special-purpose steels, protective and thermal-protective coatings] //Aviatsionnye materialy i tehnologii. 2012. №S. S. 19–36.
3. Solntsev St.S., Rozenenkova V.A., Mironova N.A. Vysokotemperaturnye steklokeramicheskie pokrytiya i kompozitsionnye materialy [High-temperature glass-ceramic coatings and composite materials] //Aviatsionnye materialy i tehnologii. 2012. №S. S. 359–368.
4. Rozenenkova V.A., Solntsev St.S., Mironova N.A. Steklokeramicheskie elektroizolyatsionnye pokrytiya dlya tolstoplenochnyh energonasyschennyh sistem [Glass-ceramic insulating coatings for thick-film energy-intensive systems] //Steklo i keramika. 2013. №7. S. 27–29.
5. Jones R.W. Sol-gel preparation of ceramics and glasses [Sol-gel preparation of ceramics and glasses] //Metals and Materials. 1988. December. P. 748–751.
6. Livage J. Sol-gel processing of metal oxides [Sol-gel processing of metal oxides] //Chemica Scripta. 1988. V. 28. P. 9–13.
7. Sumio Sakka. Sol-gel glasses and their future applications [Sol-gel glasses and their future applications] //Trans. of the Indian Ceramic Society. 1987. V. 46. №l. P. 1–11.
8. Solntsev St.S. High-Temperature CompositeMaterials and Coatings on the Basis of Glass and Ceramics for Aerospase Technics [High-Temperature Composite Materials and Coatings on the Basis of Glass and Ceramics for Aerospace Techniques] //Russian Journal of General Chemistry. 2001. V. 81. №5. P. 992–1000.
9. Rozenenkova V.A., Solntsev St.S., Mironova N.A., Gavrilov S.V. Keramicheskie pokrytiya dlya gradientnyh vysokotemperaturnyh teplozaschitnyh materialov [Ceramic coatings for thermal-protective high-temperature gradient materials] //Steklo i keramika. 2013. №1. S. 29–33.
10. Solntsev St.S., Rozenenkova V.A., Mironova N.A., Solov'eva G.A. Vysokotemperaturnye pokrytiya dlya voloknistyh teploizolyatsionnyh materialov [High-temperature coatings for fibrous heat-insulating materials] //Steklo i keramika. 2013. №5. S. 27–31.
11. Schetanov B.V., Ivahnenko Yu.A., Babashov V.G. Teplozaschitnye materialy [Thermal-protective materials] //Rossiyskiy Himicheskiy zhurnal. 2010. T. LIV. №1. S. 12–19.
12. Solntsev St.S. Vysokotemperaturnye kompozitsionnye materialy i pokrytiya na osnove stekla i keramiki [High-temperature composite materials and glass- and ceramic-based coatings] /V sb.: Aviatsionnye materialy. Izbrannye trudy «VIAM» 1932–2007. Yubileynyj nauch.-tehnich. sb. M.: VIAM. 2007. S. 90–99.
13. Ivahnenko Yu.A., Babashov V.G., Zimichev A.M., Tinyakova E.V. Vysokotemperaturnye teploizolyatsionnye i teplozaschitnye materialy na osnove volokon tugoplavkih soedineniy [High-temperature heat-insulating and thermal-protective materials based on refractory compound fibers] //Aviatsionnye materialy i tehnologii. 2012. №S. S. 380–385.
14. Solntsev Ct.C. Zaschitnye tehnologicheskie pokrytiya i tugoplavkie email [Protective processing coatings and refractory enamels]. M.: Mashinostroenie. 1984. 255 s.
15. Solntsev St.S. Zaschitnye pokrytiya metallov pri nagreve [Protective coatings for metals at heating]: Spravochnoe posob. 2-e izd. M.: Librokom. 2009. 248 s.
16. Solntsev S.S. Rozenenkova V.A. Mironova N.A. Gavrilov S.G. Teplozaschitnyj material na osnove keramicheskih armiruyuschih napolniteley [Thermal-protective material based on ceramic reinforcing fillers] //Steklo i keramika. 2012. №4. S. 22–25.
17. Solntsev St.S., Rozenenkova V.A., Mironova N.A., Gavrilov S.V. Zaschitnye tehnologicheskie pokrytiya dlya termicheskoy obrabotki vysokoprochnyh staley tipa VKS [Protective coatings for thermal processing of VKS-type high-strength steels] //Steklo i keramika. 2011. №10. S. 28–30.
18. Kondrashov E.K., Kozlova A.A., Malova N.E. Issledovanie kinetiki otverzhdeniya ftorpoliuretanovyh emaley alifaticheskimi poliizotsianatami razlichnyh tipov [Kinetics study of fluoropolyurethane enamels curing by aliphatic polyisocyanates of various types] //Aviatsionnye materialy i tehnologii. 2013. №1. S. 48‒49.
19. Nefedov N.I., Semenova L.V. Tendentsii razvitiya v oblasti konformnyh pokrytiy dlya vlagozaschity i elektroizolyatsii plat pechatnogo montazha i elementov radioelektronnoy apparatury [Trends in the development of conformal coatings for moisture protection and electrical insulation of printed-circuit boards and radio equipment components] //Aviatsionnye materialy i tehnologii. 2013. №1. S. 50‒52.
Gulyaev I.N., Vlasenko F.S., Zelenina I.V., Raskutin A.E.
The main tendencies of development of receiving high-temperature polymeric com-posite materials, in particular carbon plastics are considered. Perspective types of the polymers, allowing to provide heat resistance to 400°С and technologies of receiving products on their basis are considered. The main directions of development of PCM on the basis of polyimide, bismaleimide resin and the phthalonitrile binding are revealed. The works which are carried out to Federal State Unitary Enterprise «VIAM» for re-ceiving heat resistant carbon plastics are provided.
1. Kablov E.N. Strategicheskie napravleniya razvitiya materialov i tehnologiy ih pererabotki na period do 2030 goda [Strategic directions of the development of materials and technologies of their processing for the period till 2030] //Aviatsionnye materialy i tehnologii. 2012. №S. S. 7–17.
3. Raskutin A.E., Sokolov I.I. Ugleplastiki i stekloplastiki novogo pokoleniya [Carbon-filled plastics and fiber glass of new generation] //Trudy VIAM. 2013. №4. (viam-works.ru).
4. Prepregi i izdelie, vypolnennoe iz nego [Prepregs and products thereof]: pat. 2427594 Ros. Federatsii opubl. 21.12.2009.
5. Zainul Huda, Prasetyo Eddi. Materials selection in design of structures and engines of supersonic aircrafts: a review //Materials & Design. 2013. V. 46. P. 552–560.
6. Vicki P. McConnell. Resins for the Hote zone. Part 2: BMIs, CEs, benzoxazines and phthalonitriles /High-Performance Composites. 2009. (material iz seti Internet).
7. Kuznetsov A.A., Semenova G.K. Perspektivnye vysokotemperaturnye termoreaktivnye svyazuyuschie dlya polimernyh kompozitsionnyh materialov [Promising high-temperature thermo-reactive binders for polymer composite materials] //Rossiyskiy himicheskiy zhurnal. 2009. T. LIII. №4. S. 86–96.
8. Raskutin A.E., Panina T.V. Problemy sozdaniya konstruktsionnyh ugleplastikov s povyshennoy termookislitel'noy stoykost'yu [Problems of creating structural carbonplastics with increased thermal-oxidative resistance] /V sb. Aviatsionnye materialy i tehnologii: nauch.-tehnich. sb. 2002. №3. S. 18–23.
9. Mihaylin Yu.A. Termoustoychivye polimery i polimernye materialy [Heat-resistant pol-ymers and polymeric materials]. SPb.: 2006. 610 s.
10. Chuang K.C., Bowles K.J. A high Tg PMR polyimide composites (DMBZ-15) //Journal of Advanced Materials. 2001. V. 33. №4. P. 1–17.
11. Sposob polucheniya svyazuyuschego dlya prepregov [Technique to obtain binders for prepreg]: pat. 2052474 Ros. Federatsiya; opubl. 20.01.1996.
12. Geterotsiklicheskiy termoreaktivnyj polimer [Heterocyclic thermoreactive polymer]: pat. 2225417 Ros. Federatsiya; opubl. 10.03.2004.
13. Trostyanskaya E.B., Mihaylin Yu.A., Hohlova L.F., Miychenko I.P., Borovskaya S.M., Pomerantseva K.P. Ugleplastiki na osnove polimerizuyuschihsya imidov API-2 [Carbon-filled plastics based on polymerizing imides API-2] /V sb. Voprosy aviatsionnoy nauki i tehniki. Ser. Aviatsionnye materialy. M.: VIAM. 1985. S. 12–19.
14. Polimernye materialy i vysokoprochnye termostoykie kompozitsionnye materialy na ego osnove [Polymeric materials and high-strength heat-resistant composite materials obtained on their basis]: pat. 2201423 Ros. Federatsiya; opubl. 26.12.2000.
15. Low-Toxicity, high-temperature polyimides: pat. 99/36462 WO; opubl. 22.07.1999.
16. Composition of and method for making high performance resins for infusion and transfer mol-ding processes: pat. 6359107 US; opubl.19.03.2002.
17. Imide oligomers endcapped with phenylethynil phthalic anhydrides and polymers therefrom: pat. 5760168 US; opubl. 02.06.1998.
18. Sastri S.B., Armistead J.P., Keller T.M., Sorathia U. Phthalonitrile-glass fabric composites //Polymer Composites. 1997. V. 18. №1. P. 48–54.
19. Sastri S.B., Armistead J.P., Keller T.M. Phthalonitrile-carbon fiber composites //Polymer Composites. 1996. V. 17. №6. P. 816–822.
20. Mukhametov R.R., Akhmadieva K.R., Chursova L.V. New thermostable heterocyclic binders and environmentally friendly technologies of production of composite materials //Russian Journal of General Chemistry. 2011. V. 81. №5. P. 1025–1031.
21. Raskutin A.E., Davydova I.F., Muhametov R.R., Minakov V.T. Novoe termostoykoe svyazuyuschee dlya steklo- i ugleplastikov [New heat-resistant binder for glass fiber and carbon-filled plastics] //Klei. Germetiki. Tehnologii. 2007. №11. S. 20–23.
22. Muhametov R.R., Ahmadieva K.R., Chursova L.V., Kogan D.I. Novye polimernye svyazuyuschie dlya perspektivnyh metodov izgotovleniya konstruktsionnyh voloknistyh PKM [New polymeric binders for promising production methods of structural fibrous polymer composite materials] //Aviatsionnye materialy i tehnologii. 2011. №2. S. 38–42.
23. Phthalonitrile thermoset polymers and composites cured with halogen-containing aromatic amine cutting agents: pat. 5925475 US; opubl. 20.07.1999.
24. Fiber reinforced phtalonitrile composites cured with low reactivity aromatic amine curing agent: pat. 6001926 US; opubl. 14.12.1999.
25. Phthalonitrile prepolymerization composition: pat. 6297298 US; opubl. 02.10.2001.
26. Phthalonitrile composites: pat. 7642336 US; opubl. 05.01.2010.
27. Bi-phthalonitrile resin glass fiber composite material toughened by poly(arylene ether nitrile) and preparation method thereof: pat. 101831173 SN; opubl. 15.09.2010.
28. Heng Zhoul, Amir Badashah, Zhenhua Luol et al. Preparation and property comparison of orto, meta and para autocatalytic phthalonitrile compounds with amino group //Polymers for Advanced Technologies. 2011. V. 22. №10. P. 1459–1465.
29. Heng Guo, Zhiran Chen, Xulin Yang et al. Self-promoted curingphtalonitrile whith high glass transition temperature for advanced composites //Journal of Polymer Research. 2012. V. 19. №7. P. 1–8.
30. System and methods for modified resin and composite material: pat. 2008176987 US; opubl. 24.07.2008.
31. Polimer nanocomposites and methods of preparation: pat. 7049353 US; opubl. 23.05.2006.
32. Thermosetting resin glass fiber laminating composite material and preparation method thereof: pat. 101700705 SN; opubl. 05.05.2010.
33. Magnetic ferrocene-double-terminal phthalonitrile resin, condensate and preparation thereof: pat. 101463049 SN; opubl. 24.06.2009.
34. High temperature epoxy-phthalonitrile blends: pat. 5939508 US; opubl. 17.08.1999.
35. Dushin M.I., Hrul'kov A.V., Muhametov R.R., Chursova L.V. Osobennosti izgotovleniya izdeliy iz PKM metodom propitki pod davleniem [Peculiarities of production of polymer composite products using pressure impregnation method] //Aviatsionnye materialy i tehnologii. 2012. №1. S. 18–26.
Lukina N.F., Dement’eva L.A., Anikhovskaya L.I.
The stages of work to improve the durability and the life of the aircraft technique are described. Distinctive features of adhesive prepregs are listed and the results of their application are described. The results of studies of a new class of alumopolymer layered materials brands SIAL – hybrid material based on thin sheets of aluminum structural alloys and plastic based on adhesive prepregs obtained by a melt-type adhesive bonding and fiberglass with different reinforcement structure – are described.
3. Petrova A.P., Lukina N.F. Klei dlya mnogorazovoy kosmicheskoy sistemy [Glues for reusable space system] //Trudy VIAM. 2013. №4. St. 04 (viam-works.ru).
4. Lukina N.F., Dement'eva L.A., Petrova A.P., Serezhenkov A.A. Konstruktsionnye i termostoykie klei [Structural and heat-resistant glues] //Aviatsionnye materialy i tehnologii. 2012. №S. S. 328–335.
5. Dement'eva L.A., Serezhenkov A.A., Bocharova L.I., Anihovskaya L.I., Lukina N.F. Kompozitsionnye materialy kleevye na osnove steklyannyh i uglerodnyh napolniteley [Adhesive composite materials on the basis of glass and carbon fillers] //Klei. Germetiki. Tehnologii. 2009. №1. S. 24–27.
6. Kutsevich K.E., Dement'eva L.A., Lukina N.F., Chursova L.V. Svoystva i naznachenie kleya VK-36RM dlya aviatsionnoy tehniki [Properties and functions of VК-36RМ glue for aviation equipment] //Klei. Germetiki. Tehnologii. 2013. №8. S. 5–6.
7. Anihovskaya L.I., Minakov V.T. Klei i kleevye prepregi dlya perspektivnyh izdeliy aviakosmicheskoy tehniki [Adhesives and adhesive prepregs for advanced products of aerospace engineering] /V kn.: Aviatsionnye materialy. Izbrannye trudy «VIAM» 1932–2002: Yubileynyj nauch.-tehnich. sb. M.: MISiS–VIAM. 2002. S. 315–326.
8. Dement'eva L.A., Lukina N.F., Serezhenkov A.A., Kutsevich K.E. Osnovnye svoystva i naznachenie PKM na osnove kleevyh prepregov [Basic properties and functions of polymer composite materials based on adhesive prepregs] /V sb. tezisov dokl. XIX Mezhdunarodnoy nauch.-tehnich. konf. «Konstruktsii i tehnologiya polucheniya izdeliy iz nemetallicheskih materialov». Obninsk. 2010. S. 11–12.
9. Dement'eva L.A., Serezhenkov A.A., Lukina N.F., Kutsevich K.E. Kleevye prepregi i sloistye materialy na ih osnove [Аdhesive prepregs and laminated materials on their basis] //Aviatsionnye materialy i tehnologii. 2013. №2. S. 19–21.
10. Lukina N.F., Dement'eva L.A., Serezhenkov A.A., Kotova E.V., Senatorova O.G., Sidel'nikov V.V., Kutsevich K.E. Kleevye prepregi i kompozitsionnye materialy na ih osnove [Аdhesive prepregs and composite materials on their basis] //Rossiyskiy himicheskiy zhurnal. 2010. T. LIV. №1. S. 53–56.
11. Prepreg i izdelie, vypolnennoe iz nego [Prepreg and a product made thereof]: pat. 2427594 Ros. Federatsiya; opubl. 23.07.13.
12. Lukina N.F., Dement’eva L.A., Serezhenkov A.A., Kotova E.V., Senatorova O.G., Sidel’nikov V.V., Kutsevich K.E. Adhesive prepregs and composite materials on their basis //Russian Journal of General Chemistry. 2011. T. 81. №5. P. 1022–1024.
13. Dement'eva L.A., Serezhenkov A.A., Bocharova L.I., Lukina N.F., Kutsevich K.E., Petrova A.P. Svoystva kompozitsionnyh materialov na osnove kleevyh prepregov [Properties of composite materials based on adhesive prepregs] //Klei. Germetiki. Tehnologii. 2012. №6. S. 19–24.
14. Dement'eva L.A., Serezhenkov A.A., Lukina N.F., Kutsevich K.E. Kleevye prepregi i sloistye materialy na ih osnove [Аdhesive prepregs and laminated materials on their basis] //Aviatsionnye materialy i tehnologii. 2013. №2. S. 19–21.
15. Kablov E.N., Antipov V.V., Senatorova O.G., Lukina N.F. Novyj klass sloistyh alyumostekloplastikov na osnove alyuminiylitievogo splava 1441 s ponizhennoy plotnost'yu [New class of laminated aluminium glass-plastics based on 1441 low-density aluminum alloy] //Vestnik MGTU im. N.E. Baumana. 2011. Spets. vyp. «Perspektivnye konstruktsionnye materialy i tehnologii». S. 174–184.
16. Fridlyander I.N., Anihovskaya L.I., Senatorova O.G., Sidel'nikov V.V., Dement'eva L.A. Kompozitsionnye kleevye i sloistye metallopolimernye kompozity [Composite adhesive and laminated metal-polymer composites] /Entsiklopediya «Tsvetnye metally i splavy. Kompozitsionnye metallicheskie materialy». M.: Mashinostroenie. 2001. S. 814–831.
17. Anihovskaya L.I., Dement'eva L.A. /V sb. trudov Mezhdunarodnoy konf. «Sloistye kompozitsionnye materialy-98». Volgograd. 1998. S. 170–171.
18. Senatorova O.G., Antipov V.V., Lukina N.F., Sidel'nikov V.V., Kotova E.V. Vysokoprochnye treschinostoykie legkie sloistye alyumostekloplastiki klassa SIAL – per-spektivnye materialy dlya aviatsionnyh konstruktsiy [High-strength crack-resistant light laminated aluminium glass-plastics of SIAL class as promising materials for aviation structures] //Tehnologiya legkih splavov. 2010. №1. S. 28–31.
19. Fridlyander I.N., Anihovskaya L.I., Senatorova O.G., Sidel'nikov V.V. i dr. Kleenye metallicheskie i sloistye metallopolimernye kompozity [Glued metal and laminated metal-polymer composites] //Tsvetnye metally i splavy. Kompozitsionnye metallicheskie materialy. 2001. T. II-3. S. 814–832.
20. Sloistyj kompozitsionnyj material i izdelie, vypolnennoe iz nego [Laminated composite material and a product made thereof]: pat. 2185964 Ros. Federatsiya; opubl. 15.04.2004.
21. Fridlyander I.N., Senatorova O.G., Lukina N.F., Antipov V.V. Sloistye alyumopolimernye materialy SIAL [SIAL layered aluminum-bearing polymer materials] /V sb. 75 let. Aviatsionnye materialy. Izbrannye trudy «VIAM» 1932–2007. M.: VIAM. 2007. S. 188–192.
22. Sharova I.A., Petrova A.P. Obzor po materialam mezhdunarodnoy konferentsii po kleyam i germetikam. Frantsiya [Review of papers of the International conference on adhesives and sealants. France.] //Trudy VIAM. 2013. №8. St. 06 (viam-works.ru).
Quality control in industrial production level is determined and provides the properties and characteristics of the final product. In such a high-process as the production of single crystal articles, quality control becomes particularly important. X-ray diffraction methods for studying the structure of crystals are the perfect advanced technologies that allow for fast, accurate and simple enough control of single-crystal products at various stages of production. The article provides an overview of existing modern X-ray diffraction techniques to control, analyze their weaknesses and make recommendations to optimize process con-trol of single crystal castings.
1. Abraimov N.V., Eliseev Yu.S., Krymov V.V. Aviatsionnoe materialovedenie i tehnologiya obrabotki metallov [Aviation material science and metal processing methods]. M.: Vysshaya shkola. 1998. S. 214–217.
2. Shalin R.E., Svetlov I.L., Kachanov E.B. i dr. Monokristally nikelevyh zharoprochnyh splavov [Single crystals of nickel heat-resistant alloys]. M.: Mashinostroenie. 1997. 336 s.
3. Kablov E.N., Petrushin N.V., Elyutin E.S. Monokristallicheskie zharoprochnye splavy dlya gazoturbinnyh dvigateley [Single crystal heat-resistant alloys for gas-turbine engines] //Vestnik MGTU im. N.E. Baumana. Ser. Mashinostroenie. 2011. №SP2. S. 38–52.
4. Kablov E.N., Petrushin N.V., Svetlov I.L., Demonis I.M. Nikelevye liteynye zharoprochnye splavy novogo pokoleniya [Nickel heat-resistant casting alloys of new generation] //Aviatsionnye materialy i tehnologii. 2012. №S. S. 36–52.
5. Kablov E.N., Gerasimov V.V., Visik E.M., Demonis I.M. Rol' napravlennoy kristallizatsii v resursosberegayuschey tehnologii proizvodstva detaley GTD [Role of directional solidification in the resource-saving technology of gas-turbine engines production] //Trudy VIAM. 2013. №3. St. 01 (viam-works.ru).
6. Gorelik S.S., Skakov Yu.A., Rastorguev L.N. Rentgenograficheskiy i elektronno-opticheskiy analiz [Radiographic and optoelectronic analysis]. M.: MISiS. 2002. 360 s.
7. Sidohin F.A., Sidohin A.F., Sidohin E.F. Ob opredelenii kristallograficheskoy orientatsii monokristallov metodom Laue [On determination of crystallographic orientation of monocrystals using Laue method] //Zavodskaya laboratoriya. Diagnostika materialov. 2009. T. 75. №1. S. 35–37.
8. Bokiy G.B., Poray-Koshits M.A. Rentgenostrukturnyj analiz [X-ray crystallographic analysis]. M.: Izd-vo MGU. 1964. T. 1. S. 220.
9. Kablov E.N., Bondarenko Yu.A., Kablov D.E. Osobennosti struktury i zharoprochnyh svoystv monokristallov <001> vysokorenievogo nikelevogo zharoprochnogo splava, poluchennogo v usloviyah vysokogradientnoy napravlennoy kristallizatsii [Structural features and heat-resistant properties of monocrystals <001> of high-Re heat-resistant nickel-based alloy, obtained under high-gradient directional solidification conditions] //Aviatsionnye materialy i tehnologii. 2011. №4. S. 25–31.
10. Kuz'mina N.A., Vasikova L.M. Vliyanie skorosti vrascheniya obraztsa na kachestvo spektra pri opredelenii kristallograficheskoy orientatsii monokristal'nyh otlivok zharoprochnyh splavov [An influence of the spin rate of a sample on the spectrum quality when determining crystallographic orientation of single crystal castings made of heat-resistant alloys] //Metallurgiya mashinostroeniya. 2009. №5. S. 19–20.
11. Tolorayya V.N., Kuz'mina N.A., Demonis I.M., Vasikova L.M. Metody kontrolya rostovoy struktury monokristallicheskih otlivok nikelevyh zharoprochnyh splavov [Growth structure control methods for single crystal castings made of nickel heat-resistant alloys] /V sb. tezisov dokl. Mezhdunarodnoy nauch.-tehnich. konf. «Aktual'nye voprosy aviatsionnogo materialovedeniya». M.: VIAM. 2007. S. 74.
12. Zharoprochnyj splav na osnove nikelya dlya monokristallicheskogo lit'ya [Nickel-based heat-resistant alloy for single crystal casting]: pat. 2465359 Ros. Federatsiya; opubl. 15.09.2011.
13. Treninkov I.A., Alekseev A.A., Polyakov S.N. Metodika opredeleniya ostatochnyh napryazheniy v monokristallah zharoprochnyh nikelevyh splavov na difraktometre shirokogo naznachaeniya s ispol'zovaniem Cu Kβ-izlucheniya [Methods to determine re-sidual stresses in single crystals of nickel-based heat-resistant alloys using versatile diffractometer with Cu Kβ-radiation] //Aviatsionnye materialy i tehnologii. 2010. №1. S. 8–12.
14. Kuz'mina N.A., Ezubchenko S.N. Metodika polucheniya pryamyh polyusnyh figur ot monokristallov zharoprochnyh splavov [Methods to obtain straight pole figures from heat-resistant allots monocrystals] //Metallurgiya mashinostroeniya. 2012. №3. S. 33–34.
15. Treninkov I.A., Alekseev A.A., Petrushin N.V. Difraktometricheskiy kachestvennyj fazovyj analiz monokristallov zharoprochnyh nikelevyh splavov [Diffractometric qualitative phase analysis of single crystals of nickel heat-resistant alloys] /V sb. tezisov dokl. Mezhdunarodnoy nauch.-tehnich. konf. «Aktual'nye voprosy aviatsionnogo materialovedeniya». M.: VIAM. 2007. S. 138.
16. Treninkov I.A., Alekseev A.A., Zaytsev D.V., Filonova E.V. Issledovaniya fazovyh i strukturnyh izmeneniy, a takzhe ostatochnyh napryazheniy v protsesse vysokotemperaturnoy polzuchesti v splave VZhM4 [Reserch of phase and structural changes and residual stresses in VZhМ4 alloy in the course of high-temperature creep] //Aviatsionnye materialy i tehnologii. 2011. №2. S. 11–19.
17. Svetlov I.L., Oldakovskiy I.V., Petrushin N.V., Ignatova I.A. Kontsentratsionnaya zavisimost' periodov reshetok γ- i γꞌ-faz nikelevyh zharoprochnyh splavov [Concentration dependence of γ- and γꞌ-phase lattice spacing in nickel heat-resistant alloys] //Metally. 1991. №6. S. 150–156.
18. Protasova N.A., Svetlov I.L., Bronfin M.B., Petrushin N.V. Razmernoe nesootvet-stvie periodov kristallicheskih reshetok γ- i γꞌ-faz v monokristallah zharoprochnyh nikelevyh splavov [Dimectional discrepancy of γ- and γꞌ-phase lattice spacing in heat-resistant single crystal nickel-based alloys] //FMM. 2008. T. 106. №5. S. 512–519.
19. Protasova N.A., Svetlov I.L. Vliyanie otzhiga na harakter strukturno-fazovogo nesootvetstviya v monokristallah nikelevyh splavov [Influence of annealing on the nature of structural-phase discrepancy in single crystals of nickel-based alloys] //Materialovedenie. 2012. №5. S. 44–50.

References: V. 
 V. 
 V. 
 V. 
 V. 
 V. 
 V. 
 V. 
 V. 
 V. 
 V.