Source: http://viam-works.ru/en/articles?year=2015&num=5
Timestamp: 2019-04-22 06:03:37+00:00

Document:
Vershkov A.V., Ospennikova O.G., Nerush S.V.
A concept of an integrated information system proposed for development to provide dataware for researches in the field of aviation materials is formulated. The main task of the information system and the basic criteria for its internal structure and development are defined.
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Results of the research dedicated to the time-dependent formation of composite granules are described in the paper. Results of research of technological parameters of briquettes formed from the produced composite granules are shown. Process parameters for production of metal composite material based on magnesium reinforced by refractory particles (10-30 % vol.) by extrusion are analyzed. Mechanical properties of the material were tested and test results were used for correction of the process parameters of composite material formation.
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An effect of filler material composition and conditions of heat treatment on mechanical properties, the level of residual stresses, structural features and the nature of fracture of welded joints of semiproducts (sheets and plates) from near α-titanium alloy made by automatic argon tungsten-arc welding and electron-beam welding was investigated. An influence of ultrasonic impact treatment (UIT) of welded joints on LCF characteristics was analyzed. It was established that UIT provides an improvement of fatigue characteristics more than 5 times.
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Lukin V.I., Koval’chuk V.G., Golev E.V., Khodakova E.A.
The modes of electron beam, automatic and manual argon-arc welding of new corrosion-resistant steels hardened by various processes and filler materials were chosen; processing characteristics, mechanical properties and structures of welded joints were investigated. VNS-72 and VNS-73-Sh steels alloyed with carbon and nitrogen are superior to carbon-bearing alloys in the complex of mechanical and corrosion properties. Welded joints from VNS-72 steel are applied after full heat treatment of joints. Welding of parts from VNS-73-Sh steel is carried out both prior to strengthening heat treatment and in heat-treated state. Welding of VNS-63-Sh steel is carried out in the annealed state; besides heat treatment, welded products are subjected to cementation.
3. Panin V.E., Kablov E.N., Pleshanov V.S. i dr. Vlijanie ul'trazvukovoj udarnoj obrabotki na strukturu i soprotivlenie ustalosti svarnyh soedinenij vysokoprochnoj stali VKS-12 [Influence of ultrasonic shock processing on structure and resistance of fatigue of welded compounds of VKS-12 high-strength steel] //Fizicheskaja mezomehanika. 2006. T. 9. №2. S. 85–96.
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7. Tonysheva O.A., Voznesenskaja N.M. Perspektivnye vysokoprochnye korrozionnostojkie stali, legirovannye azotom (sravnitel'nyj analiz) [Perspective high-strength corrosion-resistant became, alloyed by nitrogen (the comparative analysis)] //Aviacionnye materialy i tehnologii. 2014. №3. S. 27–32.
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9. Zhukov A.A., Navoev A.P. Opredelenie modulja uprugosti cementovannogo sloja [Definition of elastic modulus of tsementovanny layer] //Uprochnjajushhie tehnologii i pokrytija. 2012. №5. S. 37–40.
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A review of state-of-the art scientific literature dedicated to synthesis and investigation of glass enamel coatings for protection of stainless steels against gas corrosion is presented. The results of investigations performed currently and the ways of enhancing the resistance properties and service life of products are shown. The compositions of advanced coatings under investigation providing better properties are given. The experience of VIAM to synthesize heat-resistant glass enamel coatings providing an effective long-term operation of parts made of nickel alloys and stainless steels at high operation temperatures was demonstrated.
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The results of rheological investigations of alumina-based slurries are presented in the present article. It was considered that the mutually attractive forces appear between solid phase particles in suspensions providing formation of interconnections between the particles. The ranges for ratios between solid phase (sintered powders) and liquid phase (technological binding agent) were determined experimentally for slurries, when coagulation contacts and direct contacts between solid phase particles appear in the slurries.
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19. Kirienko T.A., Balinova Ju.A. Vlijanie atmosfernoj vlazhnosti na reologiju tonkih sloev koncentrirovannyh vodnyh rastvorov sistemy «neorganicheskie soli–organicheskij polimer» [Influence of atmospheric humidity on rheology of thin coats of the concentrated aqueous solutions of system «inorganic salts-organic polymers»] //Aviacionnye materialy i tehnologii. 2014. №2. S. 56–58.
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Khokhlov Y.A., Bogatov V.A., Berezin N.M., Krynin A.G.
The distribution of thickness and properties (transmission coefficient, surface resistance) of an ITO coating fabricated by the reactive magnetron deposition on a polymer film using a sectionalized reactive gas feed system was investigated. It was shown that the uniformity of coating thickness and properties can be enhanced by optimizing the oxygen flow rate through different sections of the gas feed system.
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6. Davydova I.F., Kablov E.N., Kavun N.S. Termostojkie negopjuchie poliimidnye steklotekstolity dlja izdelij aviacionnoj i paketnoj tehniki [Heat-resistant nonflammable polyimide glass fiber laminate for products of aviation and rocket engineering] //Vse materialy. Jenciklopedicheskij spravochnik. 2009. №7. S. 2–11.
7. Bogatov V.A., Kondrashov S.V., Hohlov Ju.A. Mnogofunkcional'nye opticheskie pokrytija i materialy [Multifunction optical coatings and materials] //Aviacionnye materialy i tehnologii. 2012. №S. S. 343–348.
8. Kisljakov P.P., Hohlov Ju.A., Krynin A.G., Kondrashov S.V. Poluchenie i primenenie polimernoj plenki s prozrachnym jelektroprovodjashhim pokrytiem na osnove oksida indija, legirovannogo olovom [Receiving and application of polymer film with transparent electroconducting coating on the basis of the indium oxide alloyed by tin] //Trudy VIAM. 2013. №11. St. 06 (viam-works.ru).
9. Krynin A.G., Hohlov Ju.A., Bogatov V.A., Kisljakov P.P. Prozrachnye interferencionnye pokrytija dlja funkcional'nyh materialov osteklenija [Transparent interferential coatings for functional materials of glazing] //Trudy VIAM. 2013. №11. St. 05 (viam-works.ru).
10. Bogatov V.A., Hohlov Ju.A. Mnogofunkcional'nye opticheskie pokrytija, poluchaemye metodami plazmennoj tehnologii, i sposoby kontrolja ih optiko-fizicheskih harakteristik [The multifunction optical coatings received by methods of plasma technology, and ways of control of their optiko-physical characteristics] /V sb. Aviacionnye materialy i tehnologii. Vyp. «Metody ispytanij i kontrolja kachestva metallicheskih i nemetallicheskih materialov». M.: VIAM. 2001. S. 93–99.
11. Kuz'michev A.I. Magnetronnye raspylitel'nye sistemy. Kn. 1. Vvedenie v fiziku i tehniku magnetronnogo raspylenija [Magnetronnye spraying systems. Book 1. Introduction in physics and equipment of magnetron sputtering]. K.: Avers. 2008. 244 s.
12. Komlev A.E., Shapovalov V.I., Shutova N.S. Magnetronnyj razrjad v srede argona i kisloroda pri osazhdenii plenki oksida titana [Magnetronny discharge in the environment of argon and oxygen at titanium oxide film deposition] //ZhTF. 2012. T. 82. №7. S. 134–136.
13. Bogatov V.A., Kondrashov S.V., Hohlov Ju.A. Poluchenie gradientnogo pokrytija oksinitrida aljuminija metodom reaktivnogo magnetronnogo raspylenija [Receiving gradient covering oksinitrida aluminum method of reactive magnetron sputtering] //Aviacionnye materialy i tehnologii. 2010. №3. S. 19–21.
14. Kurdesau F., Khripunov G., da Cunha A.F. et al. Comparative study of ITO layers deposited by DC and RF magnetron sputtering at room temperature //Journal of Non-Crystalline Solids. 2006. V. 352. №19–20. P. 1466–1470.
15. Marchenko V.A. Processy na poverhnosti misheni pri reaktivnom raspylenii V v Ar–O2 sredah [Processes on target surface at reactive spraying of V in Ar–O2 Wednesdays] //Izvestija RAN. Serija fizicheskaja. 2009. T. 73. №7. S. 920–923.
16. Hohlov Ju.A., Krynin A.G., Bogatov V.A., Kisljakov P.P. Opticheskie konstanty tonkih plenok oksida indija, legirovannogo olovom, osazhdennyh na polijetilentereftalatnuju plenku metodom reaktivnogo magnetronnogo raspylenija (blizhnjaja infrakrasnaja oblast' spektra) [Optical constants of thin films of the indium oxide alloyed by tin, besieged on polietilentereftalatny film method of reactive magnetron sputtering (near infrared region of range)] //Aviacionnye materialy i tehnologii. 2013. №1. S. 24–28.
17. Hohlov Ju.A., Bogatov V.A., Berezin N.M. Stabilizacija reaktivnogo magnetronnogo osazhdenija magnitnym polem [Stabilization of reactive magnetronny sedimentation by magnetic field] //Fizika i himija obrabotki materialov. 2012. №5. S. 46–50.
18. Hohlov Ju.A., Berezin N.M., Bogatov V.A., Krynin A.G. Reaktivnoe magnetronnoe osa-zhdenie oksida indija, legirovannogo olovom, s kontrolem rabochego davlenija [Reactive magnetronny sedimentation of the indium oxide alloyed by tin, with control of working pressure] //Aviacionnye materialy i tehnologii. 2015 (v pechati).
19. Hohlov Ju.A., Berezin N.M., Bogatov V.A., Krynin A.G. Kontrol' reaktivnogo osazhdenija ITO pokrytija po jemissionnomu spektru plazmy magnetronnogo razrjada [Control of reactive sedimentation of ITO of covering on emission spectrum of plasma of magnetronny discharge] //Aviacionnye materialy i tehnologii. 2015 (v pechati).
20. Hohlov Ju.A., Bogatov V.A., Krynin A.G. Vlijanie raspredelenija magnitnogo polja na svojstva ITO pokrytija, poluchaemogo na polimernoj plenke metodom reaktivnogo magnetronnogo osazhdenija [Influence of distribution of magnetic field on ITO properties of the covering received on polymer film by method of reactive magnetronny sedimentation] //Trudy VIAM. 2014. №12. St. 11 (viam-works.ru).
21. Bogatov V.A., Hohlov Ju.A., Sytyj Ju.V., Zhadova N.S. Vlijanie obrabotki v razrjade s za-mknutym drejfom jelektronov na adgezionnye svojstva i prochnost' kleevyh soedinenij polimerov [Processing influence in discharge with the closed drift of electrons on adhesive properties and durability of glued joints of polymers] //Klei. Germetiki. Tehnologii. 2011. №9. S. 27–31.
22. Krylova T.N. Interferencionnye pokrytija [Interferential coverings]. L.: Mashinostroenie. 1973. 224 s.
23. Krynin A.G., Hohlov Ju.A. Opticheskie harakteristiki termostabilizirovannoj polijetilen-tereftalatnoj plenki, ispol'zuemoj dlja funkcional'nyh materialov osteklenija [Optical characteristics of the thermostabilized polietilentereftalatny film used for functional materials of glazing] //Aviacionnye materialy i tehnologii. 2013. №4. S. 31–34.
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Stolyankov Yu.V., Beider E.Ya., Platonov M.M., Petrova G.N.
Some features of foamed polymer materials based on structure-purposed polyimides are considered in the article. Comparison of domestic foamed materials with their foreign analogues is also provided in the article to illustrate the possibility of their usage in the resource- and energy saving technology for production of three-layer sandwich panels. Existing processes for machining of the foamed material materials are described in the article in comparison with the offered device. Description of its structure and main advantages at machining of foamed polymers is given as well.
4. Kablov E.N. Razrabotki VIAM dlja gazoturbinnyh dvigatelej i ustanovok [Development of VIAM for gas turbine engines and installations] //Kryl'ja Rodiny. 2010. №4. S. 31–33.
5. Kablov E.N., Solntsev S.S., Rozenenkova V.A., Mironova N.A. Composite glass-metal coatings for protecting beryllium at high temperatures //Glass and Ceramics. 2012. P. 1–4.
6. Fizicheskie i himicheskie processy pri pererabotke polimerov [Physical and chemical processes when processing polymers]. SPb: Nauchnye osnovy i tehnologii. 2013. 314 s.
7. Bejder Je.Ja., Petrova G.N., Izotova T.F., Barbot'ko S.L. Stekloplastiki na termoplastichnoj matrice [Fibreglasses on thermoflexible matrix] //Trudy VIAM. 2013. №7. St. 03 (viam-works.ru).
8. Doroshenko N.I., Chursova L.V. Jevoljucija materialov dlja lopastej vertoletov [Evolution of materials for blades of helicopters] //Aviacionnye materialy i tehnologii. 2012. №2. S. 16–18.
9. Bejder Je.Ja., Gureeva E.V., Petrova G.N. Penopoliimidy [Penopoliimida] //Vse materialy. Jenciklopedicheskij spravochnik. 2012. №6. S. 2–8.
10. Bejder Je.Ja., Petrova G.N., Izotova T.F., Gureeva E.V. Kompozicionnye termoplastichnye materialy i penopoliimidy [Composite thermoflexible materials and penopoliimidy] //Trudy VIAM. 2013. №11. St. 01 (viam-works.ru).
11. Bejder Je.Ja., Petrova G.N., Malyshenok S.V. Kompozicionnye termoplastichnye materialy – svojstva i sposoby pererabotki [Composite thermoflexible materials – properties and ways of processing] //Plasticheskie massy. 2013. №7. S. 56–60.
12. Petrova G.N., Bejder Je.Ja., Izotova T.F., Malyshenok S.V. Kompozicionnye termoplastichnye materialy – sposoby poluchenija i pererabotki [Composite thermoflexible materials – ways of receiving and processing] //Vse materialy. Jenciklopedi-cheskij spravochnik. 2013. №10. S. 10–17.
13. Petrova G.N., Rumjanceva T.V., Bejder Je.Ja. Vlijanie modificirujushhih dobavok na pozharobezopasnye svojstva i tehnologichnost' polikarbonata [Influence of modifying additives on fireproof properties and technological effectiveness of polycarbonate] //Trudy VIAM. 2013. №6. St. 06 (viam-works.ru).
14. Antjufeeva N.V., Aleksashin V.M., Stoljankov Ju.V. Sovremennoe metodicheskoe obespechenie termoanaliticheskih issledovanij polimernyh kompozitov i prepergov [Modern methodical ensuring thermoanalytical researches of polymeric composites and prepergov] //Kompozity i nanostruktury. 2014. T. 6. №3. S. 176–184.
15. Stoljankov Ju.V., Ishodzhanova I.V., Antjufeeva N.V. K voprosu o defektah obrazcov dlja ispytanij ugleplastikov [To question of defects of test pieces ugleplastikov] //Trudy VIAM. 2014. №10. St. 10 (viam-works.ru).
16. Ustrojstvo dlja mehanicheskoj obrabotki vspenennyh polimernyh materialovm [The device for machining of frothed polymeric materials]: pat. №145916 Ros. Federacija; opubl. 27.09.2014.
Timoshkov P.N., Platonov A.A., Khrulkov A.V.
A rapid increase in the portion of polymer composite materials (PCM) in structures of civil aircraft occurred in the 2000-s, allowed to increase significantly reliability and service life of aviation equipment and to reduce its weight. However, there was a vital problem to reduce the cost of PCM structures, which always were more expensive than similar parts made of metal. In many ways, the high cost of PCM products depends on high labor- and power consumption of autoclave technology, which at present is most widely used in the aircraft industry, as well as by high costs of relevant equipment. In recent years, VIAM actively develops the out-of-autoclave production of PCM parts. The results of the works performed by VIAM to develop PCM-based woven fillers produced by impregnation with film binder are described. Comparative elastic-strength characteristics of the produced carbon fiber-reinforced plastic are given.
2. Dushin M.I., Hrul'kov A.V., Platonov A.A., Ahmadieva K.R. Bezavtoklavnoe formovanie ugleplastikov na osnove prepregov, poluchennyh po rastvornoj tehnologii [Bezavtoklavnoye formation ugleplastikov on the basis of the prepregs received on solution technology] //Aviacionnye materialy i tehnologii. 2012. №2. S. 43–48.
3. Hrul'kov A.V., Dushin M.I., Popov Ju.O., Kogan D.I. Issledovanija i razrabotka avtoklavnyh i bezavtoklavnyh tehnologij formovanija PKM [Researches and development of avtoklavny and bezavtoklavny technologies of formation of PKM] //Aviacionnye materialy i tehnologii. 2012. №S. S. 292–301.
4. Chursova L.V., Dushin M.I., Kogan D.I., Panina N.N., Kim M.A., Gurevich Ja.M., Platonov A.A. Plenochnye svjazujushhie dlja RFI-tehnologii [Film binding for RFI technology] //Rossijskij himicheskij zhurnal. 2010. №1. S. 63–66.
5. Babin A.N. Svjazujushhie dlja polimernyh kompozicionnyh materialov novogo pokolenija [Binding for polymeric composite materials of new generation] //Trudy VIAM. 2013. №4 (viam-works.ru).
6. Postnova M.V., Postnov V.I. Opyt razvitija bezavtoklavnyh metodov formovanija PKM [Experience of development of bezavtoklavny methods of formation of PKM] //Trudy VIAM. 2014. №4. St. 06 (viam-works.ru).
7. Sposob poluchenija kompozicionnogo materiala [Way of receiving composite material]: pat. №2246379 Ros. Federacija; opubl. 25.02.2004.
8. Kablov E.N., Starcev O.V., Krotov A.S., Kirillov V.N. Klimaticheskoe starenie kompozicionnyh materialov aviacionnogo naznachenija. I. Mehanizmy starenija [Climatic aging of composite materials of aviation assignment. I. Aging mechanisms] //Deformacija i razrushenie materialov. 2010. №11. S. 19–27.
9. Kablov E.N., Starcev O.V., Krotov A.S., Kirillov V.N. Klimaticheskoe starenie kompozicionnyh materialov aviacionnogo naznachenija. III. Znachimye faktory starenija [Climatic aging of composite materials of aviation assignment. III. Significant factors of aging] //Deformacija i razrushenie materialov. 2011. №1. S. 34–40.
10. Kirillov V.N., Starcev O.V., Efimov V.A. Klimaticheskaja stojkost' i povrezhdaemost' polimernyh kompozicionnyh materialov, problemy i puti reshenija [Climatic firmness and damageability of polymeric composite materials, problems and solutions] //Aviacionnye materialy i tehnologii. 2012. №S. S. 412–423.
11. Meljohina M.I., Kavun N.S., Rakitina V.P. Jepoksidnye stekloplastiki s uluchshennoj vlago- i vodostojkost'ju [Epoxy fibreglasses with improved vlago-and water resistance] //Aviacionnye materialy i tehnologii. 2013. №2. S. 29–31.
12. Dushin M.I., Muhametov R.R., Platonov A.A., Merkulova Ju.I. Issledovanie fil'tracionnyh harakteristik armirujushhih napolnitelej i svjazujushhih pri razrabotke tehnologii bezavtoklavnogo formovanija polimernyh kompozicionnyh materialov [Research of filtrational characteristics of reinforcing fillers and binding when developing technology of bezavtoklavny formation of polymeric composite materials] //Aviacionnye materialy i tehnologii. 2013. №2. S. 22–25.
13. Platonov A.A., Kogan D.I., Dushin M.I. Izgotovlenie trehmernoarmirovannyh PKM metodom propitki plenochnym svjazujushhim [Manufacturing of trekhmernoarmirovanny PKM by method of impregnation by the film binding] //Plasticheskie massy. 2013. №12. S. 56–61.
A possibility of determination of niobium content in VPr17 solder, which is used for flame soldering of thin-walled piping from 12X18H9T steel and other complex-alloyed steels was described. Weldability and solderability, as one of the indices of the physical properties of the material, are a function of its composition in terms of main alloying components and impurity elements. In this regard, it is necessary to regulate the chemical composition of different solders and to control strictly the content of chemical elements in their composition. In this work, we have developed a method for determination of niobium content in VPr17 solder within the concentration range of 0.5–1% mass.
1. Ryl'nikov V.S., Lukin V.I. Pripoi, primenjaemye dlja pajki materialov aviacionnogo naznachenija [The solders applied to the soldering of materials of aviation assignment] //Trudy VIAM. 2013. №8. St. 02 (viam-works.ru).
3. Kablov E.N., Mubojadzhjan S.A. Zharostojkie i teplozashhitnye pokrytija dlja lopatok turbiny vysokogo davlenija perspektivnyh GTD [Heat resisting and heat-protective coverings for turbine blades of high pressure of perspective GTD] //Aviacionnye materialy i tehnologii. 2012. №S. S. 60–70.
5. Lukin V.I., Ryl'nikov V.S., Afanas'ev-Hodykin A.N. Osobennosti poluchenija pajanyh soedinenij iz splava ZhS36 [Features of receiving sweated connections from alloy ЖС36] //Tehnologija mashinostroenija. 2010. №5. S. 21–25.
6. Lukin V.I., Ryl'nikov V.S., Afanas'ev-Hodykin A.N., Orehov N.G. Osobennosti pajki monokristallicheskih otlivok iz splava ZhS32 [Features of the soldering of single-crystal otlivka from alloy ЖС32] //Svarochnoe proizvodstvo. 2012. №5. S. 24–30.
7. Lukin V.I., Koval'chuk V.G., Samorukov M.L., Gridnev Ju.M. Issledovanie vlijanija tehnologii rotacionnoj svarki treniem deformiruemogo zharoprochnogo nikelevogo splava VZh175 na strukturu i prochnostnye harakteristiki svarnyh soedinenij [Research of influence of technology of rotational friction bonding of deformable heat resisting VZh175 nickel alloy on structure and strength characteristics of welded connections] //Vestnik MGTU im. N.Je. Baumana. Ser. «Mashinostroenie». 2011. №SP2. S. 114–121.
8. Sorokin L.I. Svarivaemost' zharoprochnyh splavov, primenjaemyh v aviacionnyh gazoturbinnyh dvigateljah [Bondability of the hot strength alloys applied in aviation gas turbine engines] //Svarochnoe proizvodstvo. 1997. №4. S. 4–11.
9. Lukin V.I., Sorokin L.I., Bagdasarov Ju.S. Svarivaemost' litejnyh zharoprochnyh nikelevyh splavov tipa ZhS6M [Bondability of cast heat resisting nickel alloys of the ZhS6M type] //Svarochnoe proizvodstvo. 1997. №6. S. 12–17.
10. Lukin V.I., Semenov V.N., Starova L.L. i dr. Obrazovanie gorjachih treshhin pri svarke zharoprochnyh splavov [Formation of hot cracks when welding hot strength alloys] //MiTOM. 2007. №12. S. 7–14.
11. Horunov V.F., Maksimova S.V. Pajka zharoprochnyh splavov na sovremennom jetape [The soldering of hot strength alloys at the present stage] //Svarochnoe proizvodstvo. 2010. №10. S. 24–27.
12. Ryl'nikov V.S. Voprosy po pajke, reshennye v processe izgotovlenija izdelija «Buran» [Questions according to the soldering, the products «Buran» solved in the course of manufacturing] //Aviacionnye materialy i tehnologii. 2013. №S1. S. 33–34.
13. Lukin V.I., Banas I.P., Koval'chuk V.G., Golev E.V. Argono-dugovaja svarka vyso-koprochnoj cementuemoj stali VNS-63 [Argon-arc welding of high-strength VNS-63 tsementuyemy steel] //Trudy VIAM. 2013. №8. St. 01 (viam-works.ru).
14. Afanas'ev-Hodykin A.N., Lukin V.I., Ryl'nikov V.S. Vysokotehnologichnye polufabrikaty zharoprochnyh pripoev (lenty i pasty na organicheskom svjazujushhem) [Hi-tech semi-finished products of heat resisting solders (tape and paste on organic binding)] //Trudy VIAM. 2013. №9. St. 02 (viam-works.ru).
15. Ryl'nikov V.S., Afanas'ev-Hodykin A.N., Galushka I.A. Tehnologija pajki konstrukcii tipa «blisk» iz raznoimennyh splavov [Technology of the soldering of design of the «blisk» type from heteronymic alloys] //Trudy VIAM. 2013. №10. St. 02 (viam-works.ru).
16. Kablov E.N., Evgenov A.G., Ryl'nikov V.S., Afanas'ev-Hodykin A.N. Issledovanie melkodispersnyh poroshkov pripoev dlja diffuzionnoj vakuumnoj pajki, poluchennyh metodom atomizacii rasplava [Research of finely divided powders of solders for the diffusion vacuum soldering, received by atomizatsiya method rasplava] //Vestnik MGTU im. N.Je. Baumana. Ser. «Mashinostroenie». 2011. №SP2. S. 79–87.
17. Ryl'nikov V.S., Afanas'ev-Hodykin A.N., Krasikov M.I. Issledovanie remontnoj tehnologii ispravlenija defektov pajanyh soedinenij toplivnyh kollektorov [Research of repair technology of correction of defects of sweated connections of fuel manifolds] //Trudy VIAM. 2013. №12. St. 02 (viam-works.ru).
Basargin O.V., Kolyshev S.G., Schetanov B. V., Shcheglova T.M.
The development of high-temperature structural materials means determination of their strength properties at operation temperatures. The decisions of the main problems of mechanical tests of specimens made from Nb-based matrix composite materials (CM) at 1300–1400°С are described in this work.
2. Kablov E.N., Shhetanov B.V., Ivahnenko Ju.A., Balinova Ju.A. Perspektivnye armirujushhie vysokotemperaturnye volokna dlja metallicheskih i keramicheskih kompozicionnyh materialov [Perspective reinforcing high-temperature fibers for metal and ceramic composite materials] //Trudy VIAM. 2013. №2. St. 05 (viam.works.ru).
3. Kablov E.N., Grashhenkov D.V., Isaeva N.V., Solncev S.S. Perspektivnye vysokotemperaturnye keramicheskie kompozicionnye materialy [Perspective high-temperature ceramic composite materials] //Rossijskij himicheskij zhurnal. 2010. T. LIV. №1. S. 20–24.
4. Kablov E.N., Kondrashov S.V., Jurkov G.Ju. Perspektivy ispol'zovanija uglerodsoderzhashhih nanochastic v svjazujushhih dlja polimernyh kompozicionnyh materialov [Perspectives of use of carbon-containing nanoparticles in binding for polymeric composite materials] //Rossijskie nanotehnologii. 2013. T. 8. №3–4. S. 24–42.
5. Gunjaev G.M., Kablov E.N., Aleksashin V.M. Modificirovanie konstrukcionnyh ugleplastikov uglerodnymi nanochasticami [Modifying constructional ugleplastikov carbon nanoparticles] //Rossijskij himicheskij zhurnal. 2010. T. LIV. №1. S. 5–11.
6. Kablov E.N., Shhetanov B.V., Grashhenkov D.V., Shavnev A.A., Njafkin A.N. Metallomatrichnye kompozicionnye materialy na osnove Al–SiC [Metalmatrix composite materials on the basis of Al–SiC] //Aviacionnye materialy i tehnologii. 2012. №S. S. 373–380.
7. Varrik N.M., Ivahnenko Ju.A., Maksimov V.G. Oksid-oksidnye kompozicionnye materialy dlja gazoturbinnyh dvigatelej (obzor) [Oksid-oksidnye composite materials for gas turbine engines (review)] //Trudy VIAM. 2014. №8. St. 03 (viam.works.ru).
8. Shhetanov B.V., Strjukov D.O., Kolyshev S.G., Murasheva V.V. Monokristallicheskie volokna oksida aljuminija: poluchenie, struktura, svojstva [Single-crystal fibers of aluminum oxide: receiving, structure, properties] //Vse materialy. Jenciklopedicheskij spravochnik. 2014. №4. S. 14–18.
9. Kablov E.N., Svetlov I.L., Efimochkin I.Ju. Vysokotemperaturnye Nb–Si-kompozity [High-temperature Nb-Si-composites] //Vestnik MGTU im. N.Je. Baumana. Ser. «Mashinostroenie». 2011. №SP2. S. 164–173.
10. Grashhenkov D.V., Shhetanov B.V., Efimochkin I.Ju. Razvitie poroshkovoj metallurgii zha-roprochnyh materialov [Development of powder metallurgy of heat resisting materials] //Vse materialy. Jenciklopedicheskij spravochnik. 2011. №5. S. 13–26, №6. S. 10–22.
11. Maksimov V.G., Basargin O.V., Shheglova T.M., Nikitina V.Ju. O projavlenii sverhplastich-nosti v polidispersnoj keramike mullit–oksid cirkonija s razmerom kristallov bolee 10 mkm [About superplasticity manifestation in unequigranular ceramics mullit-zirconium oxide with size of crystals more than 10 microns] //Trudy VIAM. 2013. №6. St. 04 (viam-works.ru).
12. Basargin O.V., Shcheglova T.M., Kolyshev S.G., Nikitina V.Yu., Maksimov V.G., Babashov V.G. Determination of the high-temperature strength of ceramic oxide materials //Glass and Ceramics. 2013. V. 70. №1–2. P. 43–46.
13. Maksimov V.G., Grashhenkov D.V., Lomovskoj V.A., Babashov V.G., Basargin O.V., Kolyshev S.G. Issledovanie vysokotemperaturnoj polzuchesti v polidispersnoj keramike mullit – oksid cirkonija [Research of high-temperature creep in unequigranular ceramics mullit – zirconium oxide] //Steklo i keramika. 2014. №5. S. 36–40.
14. Ivahnenko Ju.A., Babashov V.G., Zimichev A.M., Tinjakova E.V. Vysokotemperaturnye teploizoljacionnye i teplozashhitnye materialy na osnove tugoplavkih soedinenij [High-temperature heatinsulating and heat-protective materials on the basis of high-melting connections] //Aviacionnye materialy i tehnologii. 2012. №S. S. 380–386.
15. Tinjakova E.V., Grashhenkov D.V. Teploizoljacionnyj material na osnove mullito-korundovyh i kvarcevyh volokon [Heatinsulating material on the basis of mullito-korundovy and quartz fibers] //Aviacionnye materialy i tehnologii. 2012. №3. S. 43–46.
16. Shhetanov B.V., Balinova Ju.A., Ljuljukina G.Ju., Solov'eva E.P. Struktura i svojstva nepre-ryvnyh polikristallicheskih volokon α-Al2O3 [Structure and properties of continuous polycrystalline fibers α-Al2O3] //Aviacionnye materialy i tehnologii. 2012. №1. S. 13–17.
Sentiourin E.G., Mekalina I.V., Petrova A.P., Frolkov Y.A.
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2. Kablov E.N. Innovacionnye razrabotki FGUP «VIAM» GNC RF po realizacii «Strategicheskih napravleniy razvitiya materialov i tekhnologiy ih pererabotki na period do 2030 goda» [Innovative development of VIAM Federal State Unitary Enterprise of GNTs Russian Federation on implementation «The strategic directions of development of materials and technologies of their processing for the period till 2030»] //Aviacionnye materialy i tekhnologii. 2015. №1 (34). S. 3–33.
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6. Gudimov M.M., Sentyurin E.G. Prozrachnaya bronya i organicheskie stekla [The transparent reservation and organic glasses] /V kn. Aviacionnye materialy na rubezhe ХХ–ХХI vekov: Nauch.-tekhnich. sb. M.: VIAM. 1994. S. 370–373.
7. Erasov V.S., Nuzhnyy G.A., Grinevich A.V., Terekhin A.L. Treshchinostoykost' aviacionnyh materialov v processe ispytaniya na ustalost' [Treshchinostoykost of aviation materials in the course of fatigue test] //Trudy VIAM. 2013. №11. St. 01 (viam-works.ru).
8. Sentyurin E.G., Mekalina I.V., Trigub T.S., Klimova S.F. Modificirovannye organicheskie stekla dlya perspektivnoy aviacionnoy tekhniki [The modified organic glasses for perspective aviation engineering] //Vse materialy. Enciklopedicheskiy spravochnik. 2012. №2. S. 2–4.
9. Mekalina I.V., Sentyurin E.G., Klimova S.F., Bogatov V.A. Novye «serebrostoykie» organicheskie stekla [New «serebrostoyky» organic glasses] //Aviacionnye materialy i tekhnologii. 2012. №4. S. 45–48.
10. Mekalina I.V., Bogatov V.A., Trigub T.S., Sentyurin E.G. Aviacionnye organicheskie stekla [Aviation organic glasses] //Trudy VIAM. 2013. №11. St. 04 (viam-works.ru).
11. Mekalina I.V., Sentyurin E.G., Trigub T.S., Ayzatulina M.K. Aviacionnye organicheskie stekla dlya samoletov i vertoletov, ehkspluatiruyushchihsya v morskih usloviyah [Aviation organic glasses for airplanes and the helicopters which are maintaining in sea conditions] //Plasticheskie massy. 2013. №3. S. 63–64.
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14. Mekalina I.V., Trigub T.S., Bogatov V.A., Sentyurin E.G. Novoe vysokoteplostoykoe orientirovannoe orgsteklo marki VOS-2AO [The new high-heatresistant oriented organic glass of the VOS-2AO brand] //Aviacionnye materialy i tekhnologii. 2010. №3. S. 14–19.
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21. Petrov A.A., Mekalina I.V., E.G. Sentyurin, Bogatov V.A. Issledovanie osobennostey izgo-tovleniya detaley ostekleniya iz chastichno sshityh organicheskih stekol [Research of features of manufacturing of details of glazing from partially sewed organic glasses] //Aviacionnye materialy i tekhnologii. 2013. №2. S. 32–34.

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