ARCHIVE

Aviation materials and technologies №2, 2026

Contents

Heat-resistant alloys and steels

  • K.V. Dulnev, G.S. Sevalnev

    STRUCTURE FORMATION AND FORMATION OF PROPERTIES DURING THERMAL CYCLING OF HIGH-STRENGTH HIGH-NITROGEN ECONOMY-ALLOYED STEEL

    5-14
    https://journal.viam.ru/sites/default/files/uploads/contents/2026/2026_2_content.pdf
  • N.V. Petrushin, E.S. Elyutin, E.M. Visik

    STRUCTURE AND MECHANICAL PROPERTIES OF THE SIX-GENERATION SINGLE CRYSTAL NICKEL-BASED SUPERALLOY

    15-28
    https://journal.viam.ru/sites/default/files/uploads/contents/2026/2026_2_content.pdf
  • S.V. Ovsepyan, I.S. Kononova, A.S. Shpagin, M.V. Akhmedzyanov

    RHEOLOGICAL CHARACTERISTICS AND MICROSTRUCTURE DURING HOT UPSETTING OF P/M NICKEL-BASED SUPERALLOY EP975 FOR DISKS OF AVIATION GAS TURBINE ENGINES

    29-39
    https://journal.viam.ru/sites/default/files/uploads/contents/2026/2026_2_content.pdf
  • M.D. Panteleev, A.V. Sviridov, S.D. Zotov, E.A. Kudryavtsev, M.G. Yakovlev, G.R. Isakhanov

    THE FEATURES OF INERTIAL FRICTION WELDING TECHNOLOGY OF GRANULATED HEAT-RESISTANT NICKEL ALLOYS

    40-50
    https://journal.viam.ru/sites/default/files/uploads/contents/2026/2026_2_content.pdf

Light-metal alloys

  • V.A. Duyunova, I.A. Petrov, A.A. Leonov, N.V. Trofimov

    DEVELOPMENT OF MATHEMATICAL MODELS FOR PREDICTING THE PROPERTIES OF THE Mg–REE–Zn–Zr MAGNESIUM ALLOY SYSTEM AND EVALUATION OF ITS CONVERGENCE 

    51-63
    https://journal.viam.ru/sites/default/files/uploads/contents/2026/2026_2_content.pdf
  • Yu.S. Oglodkova, K.V. Antipov, A.A. Selivanov, E.A. Shestakova, A.S. Rudchenko

    TECHNOLOGICAL TESTING OF PILOT-INDUSTRIAL SEMI-FINISHED PRODUCTS FROM THE ALLOY V-1381 OF THE Al–Mg–Si–Cu SYSTEM

    64-76
    https://journal.viam.ru/sites/default/files/uploads/contents/2026/2026_2_content.pdf
  • T.A. Shlyapnikova, A.L. Ivanov, A.V. Somov, A.F. Dorzhiev

    MODERN TRENDS IN HEAT TREATMENT AND THERMOMECHANICAL TREATMENT OF HIGH-STRENGTH Al–Zn–Mg–Cu ALUMINUM ALLOYS 

    77-93
    https://journal.viam.ru/sites/default/files/uploads/contents/2026/2026_2_content.pdf

Polymer materials

  • P.G. Belinis, Yu.V. Lukyanenko, V.N. Rogozhnikov, R.G. Tsykun, K.I. Donetskiy

    STUDYING THE POSSIBILITY OF APPLYING POLYMER COMPOSITES  BASED ON 3D REINFORCED PREFORMS FOR THE MANUFACTURING  OF AIRCRAFT FRAME STRUCTURES

    94-107
    https://journal.viam.ru/sites/default/files/uploads/contents/2026/2026_2_content.pdf

Composite materials

  • Yu.A. Egorov, M.A. Guseva, E.V. Kurshev, N.V. Antyufeeva

    INVESTIGATION OF THE CURING PROCESS OF THERMOSETTING EPOXY SYSTEMS FOR COMPOSITE MATERIALS

    108-121
    https://journal.viam.ru/sites/default/files/uploads/contents/2026/2026_2_content.pdf
  • R.K. Salakhova, E.A. Veshkin, V.V. Kalenov

    TWO-FACTOR OPTIMIZATION MODELS OF PHYSICAL, CHEMICAL, AND MECHANICAL PROPERTIES OF STRUCTURAL ORGANOPLASTIC

    122-131
    https://journal.viam.ru/sites/default/files/uploads/contents/2026/2026_2_content.pdf
  • D.I. Vershinin, V.V. Kholodova, K.O. Loginov

    THE INFLUENCE OF THE INTRODUCTION OF A SINTERING ADDITIVE OF THE CaO‒ZnO‒Al2O3‒SiO2 SYSTEM ON THE SINTERING PROCESS, MICROSTRUCTURE, PHYSICAL AND MECHANICAL PROPERTIES OF CERAMICS BASED ON α-Al2O3

    132-144
    https://journal.viam.ru/sites/default/files/uploads/contents/2026/2026_2_content.pdf
  • N.E. Shchegoleva, S.A. Evdokimov, D.I. Vershinin, V.V. Kholodova, M.L. Vaganova, A.S. Chaynikova

    SILICON NITRIDE BASED CERAMICS AS A PROMISING MATERIAL FOR HYBRID BEARINGS

    145-159
    https://journal.viam.ru/sites/default/files/uploads/contents/2026/2026_2_content.pdf

Protective and functional coatings

  • Yu.G. Yushkov, A.A. Andronov, I.Yu. Bakeev, D.B. Zolotukhin, A.A. Zenin, E.M. Oks, A.V. Tyunkov

    PILOT TECHNOLOGICAL INSTALLATION OF ELECTRON BEAM SPRAYING OF HEAT-SHIELDING CERAMIC COATINGS ON TURBINE BLADES

    160-170
    https://journal.viam.ru/sites/default/files/uploads/contents/2026/2026_2_content.pdf

Material tests

  • A.D. Monakhov, N.O. Yakovlev

    STUDY OF CRACK RESISTANCE CHARACTERISTICS OF ALUMINUM ALLOY USING MULTIPARAMETRIC CRITERIA OF FRACTURE MECHANICS

    171-182
    https://journal.viam.ru/sites/default/files/uploads/contents/2026/2026_2_content.pdf
  • D.S. Skorobogatko, A.N. Golovkov, I.I. Kudinov, S.I. Kulichkova

    COMPARISON OF THE EFFICIENCY OF THE KITS OF DEFECTOSCOPIC MATERIALS LUM1-OV AND LUM33-OV IN DETECTING LOW-CYCLE FATIGUE CRACKS

    183-193
    https://journal.viam.ru/sites/default/files/uploads/contents/2026/2026_2_content.pdf
  • A.G. Argunova, E.S. Petukhova, A.L. Fedorov

    STUDY OF THE ULTRAVIOLET RADIATION INFLUENCE ON THE PROPERTIES OF LOW-DENSITY POLYETHYLENE CONTAINING STERICALLY HINDERED PHENOLIC STABILIZERS

    194-208
    https://journal.viam.ru/sites/default/files/uploads/contents/2026/2026_2_content.pdf
  • A.A. Igolkin, P.A. Popov, A.I. Safin, М.V. Hardin

    THE INVESTIGATION OF VIBROACOUSTIC PROPERTIES AND THE POSSIBILITY OF USING COMPOSITE MATERIAL OF SYSTEM «ALUMINUM–POLYMER–ALUMINUM» 

    209-219
    https://journal.viam.ru/sites/default/files/uploads/contents/2026/2026_2_content.pdf
  • V.S. Shitikov, S.S. Pichugin

    FEATURES OF SIGNAL FILTERING APPLICATION IN NON-DESTRUCTIVE TESTING BY THE EDDY CURRENT METHOD

    220-229
    https://journal.viam.ru/sites/default/files/uploads/contents/2026/2026_2_content.pdf
  • P.S. Marakhovskii, M.G. Razmakhov, N.S. Skuridina, A.N. Savritsky

    INFLUENCE OF TECHNOLOGICAL PARAMETERS OF MATERIALS PROCESSING ON THE MEASUREMENT OF THEIR THERMOPHYSICAL PROPERTIES

    230-240
    https://journal.viam.ru/sites/default/files/uploads/contents/2026/2026_2_content.pdf
  • N.G. Pavlukovich, M.S. Ivanov, M.A. Guseva, E.A. Borisova, V.S. Morozova, I.V. Mekalina

    THERMO-OXIDATIVE STABILITY OF PEEK AND CARBON FIBER-REINFORCED PEEK COMPOSITES

    241-252
    https://journal.viam.ru/sites/default/files/uploads/contents/2026/2026_2_content.pdf
Содержание номера
1.

DOI: 10.18577/2713-0193-2026-0-2-5-14

UDC: 669.018.292

Pages:: 5-14

K.V. Dulnev1, G.S. Sevalnev1

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

STRUCTURE FORMATION AND FORMATION OF PROPERTIES DURING THERMAL CYCLING OF HIGH-STRENGTH HIGH-NITROGEN ECONOMY-ALLOYED STEEL

Thermocycling treatment of high-strength high-nitrogen economy-alloyed structural martensitic steel of the Cr–Ni–Si–Mo–Mn–V alloying system has been carried out. It has been established that thermocycling leads to the formation of a martensitic structure. The level of hardness and strength characteristics during thermocycling remains almost the same as during heat treatment using the «quenching + low tempering» scheme. At the same time, thermocycling increases the KCV impact strength and improves the tribotechnical properties

Keywords: high nitrogen steels, super-equilibrium nitrogen content, heat treatment, thermal cycling, microstructure, hardness, construction steel

Reference List

    1. Kablov E.N. What will the future be made of? New-generation materials, their creation and processing technologies – the basis of innovation. Krylya Rodiny, 2016, no. 5, pp. 8–18.
    2. Kablov E.N. New-Generation Materials – the Basis of Innovation, Technological Leadership, and Russia’s National Security. Intellekt i tekhnologii, 2016, no. 2 (14), pp. 16–21.
    3. Kablov E.N. New-generation materials and digital technologies for their processing. Vestnik Rossiyskoy akademii nauk, 2020, vol. 90, no. 4, pp. 331–334.
    4. Gromov V.I., Yakusheva N.A., Vostrikov A.V., Cherkashneva N.N. High strength structural steels for gas-turbine engine shafts (review). Aviation materials and technology, 2021, no. 1 (62), pp. 3–12. URL: http://www.journal.viam.ru (accessed: October 10, 2025). DOI: 10.18577/2713-0193-2021-0-1-3-12.
    5. Alekseeva M.S., Slobodskoy P.A., Lukina Е.А., Yakusheva N.A. Patterns of structure formation for open-hearth steel of the Fe–Cr–Ni–Mo–Ti system during heat treatment. Trudy VIAM, 2024, no. 2 (132), pp. 3–12. Available at: http://www.viam-works.ru (accessed: October 11, 2025). DOI: 10.18577/2307-6046-2024-0-2-3-12.
    6. Blinov V.M., Lukin E.I., Blinov E.V. et al. Tensile Fracture of Austenitic Corrosion-Resistant Steels with an Overequilibrium Nitrogen Content and Various Vanadium Contents. Russian Metallurgy (Metally), 2021, vol. 2021, is. 10, pp. 1265–1269. DOI: 10.1134/S0036029521100062.
    7. Trojahn W., Streit E., Chin H., Ehlert D. Progress in bearing performance of advanced nitrogen alloys stainless steel, Cronidur 30. Bearing steels: into the 21-st century: ASTM STP 1327. Eds. J.J.C. Hoo, W.B. Green. American Society for Testing Material, 1998, p. 440.
    8. Rashev Ts.V. High-Nitrogen Steels. Pressure Metallurgy. Sofia: Prof. Marin Drinov Publ. House, 1995, 272 p.
    9. Gudremon, E. Special Steels. Second ed. Trans. from Germ. Moscow: Metallurgiya, 1966, 1274 p.
    10. Siwka J., Hutny A. An universal formula for the calculation of nitrogen solubility in liquid nitrogen-alloyed steels. Metalurgija, 2009, vol. 48, no. 1, pp. 23–27.
    11. Krylov S.A., Makarov A.A., Druzhnov M.A. Study of high-strength low-alloy steel with super-equilibrium nitrogen content. Trudy VIAM, 2020, no. 12 (94), pp. 3‒13. Available at: http://www.viam-works.ru (accessed: October 10, 2025). DOI: 10.18577/2307-6046-2020-0-12-3-13.
    12. Fedyukin V.K., Smagorinsky M.E. Thermal Cycling of Metals and Machine Parts. Leningrad: Mashinostroenie, 1989, 255 p.
    13. Shmatov A.A. Methods of Thermal Cycling for Volumetric Hardening of Steel Tools. Prikladnye issledovaniya, 2015. Available at: https://applied-research.ru/article/view?id=13249 (accessed: October 08, 2025).
    14. Kablov E.N. 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, no. 1 (34), pp. 3–33. DOI: 10.18577/2071-9140-2015-0-1-3-33.
    15. Gavriljuk V.G., Berns H. High nitrogen steels: structure, properties, manufacture, applications. Springer Science & Business Media, 1999, 364 p.
    16. Dulnev K.V., Sevalnev G.S., Pahomkina T.N., Buzenkov A.V. Study of changes in microstructure, grain size and nitrogen concentration depending on heat treatment temperature of high-strength structural high-nitrogen steel. Aviation materials and technologies, 2025, no. 3 (80), pp. 3–14. Available at: http://www.journal.viam.ru (accessed: October 10, 2025). DOI: 10.18577/2713-0193-2025-0-3-3-14.
    17. Vostrikov A.V., Sevalnev G.S., Bannykh I.O., Vlasov I.I., Romanenko D.N., Dulnev K.V. Microstructure, hardness and tribotechnical properties evolution of economically alloyed high nitrogen martensitic steel. Trudy VIAM, 2022, no. 9 (115), pp. 3‒14. Available at: http://www.viam-works.ru (accessed: October 10, 2025). DOI: 10.18577/2307-6046-2022-0-9-3-14.
    18. Arzamasov B.N., Makarova V.I., Mukhin G.G. Materials Science: Textbook for Universities. 3rd ed., rev. and add. Moscow: Publishing house of Bauman MSTU, 2001, 646 p.

Full version (rus)
2.

DOI: 10.18577/2713-0193-2026-0-2-15-28

UDC: 678.83

Pages:: 15-28

N.V. Petrushin1, E.S. Elyutin1, E.M. Visik1

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

STRUCTURE AND MECHANICAL PROPERTIES OF THE SIX-GENERATION SINGLE CRYSTAL NICKEL-BASED SUPERALLOY

The article presents the design and experimental studies of a new rhenium-ruthenium-containing VI generation heat-resistant nickel alloy VZhM10 for the working blades of advanced aircraft gas-turbine engines. The microstructure of the alloy single crystals with crystallographic orientation <001> is shown. In the study presented data on the temperatures of γ'-solvus, solidus, and liquidus, the amount of γ'-phase, the periods of the crystal lattices of the γ- and γ'-phases, γ/γ'-misfit, the characteristics of short-term and long-term strength, creep strength at temperatures up to 1250 °C.

Keywords: nickel-based superalloys, single crystals, microstructure, phase transformations and characteristics, shot-term strength, long-term strength, rhenium, ruthenium

Reference List

    1. The Work of Leading Aircraft Engine Manufacturing Companies in Ensuring the Creation of Advanced Aircraft Engines (Analytical Review). Eds. V.A. Skibin, V.I. Solonin. Moscow: TsIAM, 2010, 678 p.
    2. Palkin V.A. Review of Work in the USA and Europe on the Creation of New-Generation Aviation Complexes and Engines for Their Power Plants. Aviatsionnye dvigateli, 2021, no. 1 (10), pp. 57–80.
    3. Inozemtsev A.A., Koryakovtsev A.S., Lesnikov V.P., Kuznetsov V.P. The Role of Materials and Protective Coatings of Turbine Blades in Ensuring the Reliability and Efficiency of Gas Turbine Engines. Proceedings of the Int. Sc. and Tech. Conf. «Scientific Ideas of S.T. Kishkin and Modern Materials Science». Moscow: VIAM, 2006, pp. 84–87.
    4. Cast blades of gas turbine engines. Alloys, technologies, coatings. Ed. E.N. Kablova. 2nd ed. Moscow: Nauka, 2006, 632 p.
    5. Reed R.C. The Superalloys. Fundamentals and Applications. Cambridge: United Kingdom at University Press, 2006, 372 p.
    6. Logunov A.V. Heat-Resistant Nickel Alloys for Gas Turbine Blades and Disks. Rybinsk: Gas Turbine Technologies, 2017, 854 p.
    7. Aviation Materials: Handbook in 13 vols. 7th ed., rev and add. Ed. E.N. Kablov. Moscow: NRC «Kurchatov Institute» – VIAM, 2022, vol. 3: Casting Heat-Resistant and Intermetallic Nickel-Based Alloys, 200 p.
    8. Harada H. Development of Superalloys for 1700°C ultra-efficient gas turbines. Proceedings of the 9th Liége-Conference on Materials for Advanced Power Engineering. Liége: Schriften des Forschungszentrum Julich, 2010, pp. 604–614.
    9. Svetlov I.L., Petrushin N.V., Epishin A.I., Karashaew M.M., Elyutin E.S. Single crystals of nickel-based superalloys alloyed with rhenium and ruthenium (review). Part 1. Aviation materials and technologies, 2023, no. 1 (70), pp. 30–50. Available at: http://www.journal.viam.ru (accessed: November 28, 2025). DOI: 10.18577/2713-0193-2023-0-1-30-50.
    10. PD-14 engine and a family of advanced engines. Available at: http://www.avid.ru/pd14 (accessed: August 30, 2025).
    11. Kablov E.N. VIAM: new generation materials for PD-14. Krylya Rodiny, 2019, no. 7–8, pp. 54–58.
    12. Ding Q., Li S., Chen L.-Q. et al. Re segregation at interfacial dislocation network in nickel-base superalloys. Acta Materialia, 2018, vol. 154, pp. 137‒146. DOI: 10.1016/j.actamat.2018.05.025.
    13. Lilensten L., Kürnsteiner P., Mianroodi J.R. et al. Segregation of solutes at dislocations: A new alloy design parameter for advanced superalloys. Superalloys 2020. Pennsylvania: Minerals, Metals & Materials Society, 2020, pp. 41–51. DOI: 10.1007/978-3-030-51834-9_4.
    14. Huang M., Zhu J. An overview of rhenium effect in single-crystal superalloys. Rare Metals, 2016, vol. 35, is. 2, pp. 127–139. DOI: 10.1007/s12598-015-0597-z.
    15. Svetlov I.L., Petrushin N.V., Epishin A.I., Karashaew M.M., Elyutin E.S. Single crystals of nickel-based superalloys alloyed with rhenium and ruthenium (review). Part 2. Aviation materials and technologies, 2023, no. 2 (71), pp. 3–22. Available at: http://www.journal.viam.ru (accessed: November 28, 2025). DOI: 10.18577/2713-0193-2023-0-2-3-22.
    16. Sato A., Koizumi Y., Kobayashi T. et al. TTT Diagram for TCP Phases Precipitation of 4th Generation Ni-Base Superalloys. The Japan Institute of Metals, 2004, vol. 68, no. 8, pp. 507‒510.
    17. Zhao Y., Zhao J., Long H. et al. Effects of TCP and creep cavity on creep life in the rafting regime for Ru-containing nickel-based single crystal superalloys. Materials Research Letters, 2023, vol. 11, no. 8, pp. 623–629. DOI: 10.1080/21663831.2023.2207580.
    18. Matuszewski K., Rettig R., Singer R. The effect of Ru on precipitation of topologically close packed phases in Re-containing Ni base superalloys: quantitative FIB-SEM investigation and 3D image modeling. Proceedings of 2nd European Symposium on Superalloys and their Applications (Eurosuperalloys 2014). MATEC Web of Conferences, 2014, no. 14, pp. 129–134. DOI: 10.1051/matecconf/20141409001.
    19. Elyutin E.S. Development of heat-resistant nickel alloys of the 5th and 6th generations with increased long-term strength for single-crystal blades of promising aircraft gas turbine engines: thesis abstract Cand. Sc. (Thech.). Moscow, 2023, 28 p.
    20. Yu X.X., Wang C.Y., Zhang X.N. et al. Synergistic effect of rhenium and ruthenium in nickel-based single crystal superalloys. Journal Alloys Compounds, 2014, vol. 582, pp. 299‒304. DOI: 10.1016/j.jallcom.2013.07.201.
    21. Kablov E.N., Petrushin N.V., Sidorov V.V., Demonis I.M. Development of single-crystal high-rhenium heat-resistant nickel alloys by computer design. Casting heat-resistant alloys. S.T. Kishkin effect. Moscow: Nauka, 2006, pp. 79–97.
    22. Calculation of parameters of heat-resistant nickel alloys: Certificate of State Registration of Computer Program No. RU 2019661855; application No. 2019660611 dated 28.08.2019; registered 10.09.2019.
    23. Morozova G.I. Balanced alloying of heat-resistant nickel alloys. Metally, 1993, no. 1, pp. 38–41.
    24. Morinaga M., Yukawa N., Adachi H., Ezaki H. New phacomp and its applications to alloy design. Superalloys 1984. Pennsylvania: Minerals, Metals & Materials Society, 1984, pp. 523−532.
    25. Bondarenko Yu.A., Echin A.B., Surova V.A., Narsky A.R. Development of technologies and equipment for producing blades of the hot path of gas turbine engines from superalloys with directional and single-crystal structure. Trudy VIAM, 2023, no. 7 (125), pp. 3–14. Available at: http://www.viam-works.ru (accessed: November 28, 2025). DOI: 10.18577/2307-6046-2023-0-7-3-14.
    26. Kuzmina N.A. Growth structural defects in single crystals of nickel heat-resistant alloys. Aviation materials and technologies, 2022, no. 3 (68), pp. 15–26. Available at: http://www.journal.viam.ru (accessed: April 22, 2025). DOI: 10.18577/2713-0193-2022-0-3-15-26.
    27. Iskhodzhanova I.V., Bondarenko Yu.A., Lapteva M.A. Evaluation of the structure of monocrystalline Ni superalloys derived in different conditions of directional solidification using methods of quantitative analysis of video images. Trudy VIAM, 2015, no. 12, pp. 46–54. Available at: http://www.viam-works.ru (accessed: May 08, 2025). DOI: 10.18577/2307-6046-2015-0-12-6-6.
    28. Epishin A.I., Svetlov I.L., Petrushin N.V., Loshchinin Yu.V., Link T. Segregation in single crystal nickel-base superalloys. Defect and Diffusion Forum, 2011, vol. 309–310, pp. 121–126. DOI: 10.4028/www.scientific.net/DDF.309-310.121.
    29. Nazarkin R.M. X-ray diffraction techniques for precise determination of lattice constants in Ni-based superalloys: a brief review. Aviacionnye materialy i tehnologii, 2015, no. 1 (34), pp. 41–48. DOI: 10.18577/2071-9140-2015-0-1-41-48.
    30. Kablov E.N., Golubovsky E.R. Heat Strength of Nickel Alloys. Moscow: Mashinostroenie, 1998, 464 p.
    31. Epishin A.I., Link T., Bruckner U., Fedelich B. Residual Stresses in the Dendritic Structure of Single Crystals of Nickel Heat-Resistant Alloys. Fizika metallov i metallovedenie, 2005, vol. 100, no. 2, pp. 104‒112.
    32. Epishin A.I., Link T., Nolze G. et al. Diffusion Processes in the Multicomponent System Nickel Heat-Resistant Alloy-Nickel. Fizika metallov i metallovedenie, 2014, vol. 115, no. 1, pp. 23–31.
    33. Shalin R.E., Svetlov I.L., Kachanov E.B. et al. Single crystals of nickel heat-resistant alloys. Moscow: Mashinostroenie, 1997, 336 p.
    34. Tian N., Meng T., Sun S. et al. Creep behavior of a single crystal nickel-based superalloy containing high concentrations of Re/Ru at an intermediate temperature. Crystals, 2024, vol. 14, no. 11, pp. 1–11. DOI: 10.3390/cryst14110983.
    35. Bandorf J., Kirzinger A., Zenk C.H. et al. On the evolution of the γ/γ′ lattice misfit and TCP phase precipitation in a highly alloyed single crystalline Ni-based superalloy. Superalloys 2024. Pennsylvania: Minerals, Metals & Materials Society, 2024, pp. 73–83.
    36. Kawagishi K., Yeh An-C., Yokokawa T. et al. Development of an oxidation-resistant high-strength sixth-generation single-crystal superalloy TMS-238. Superalloys 2012. Pennsylvania: Minerals, Metals & Materials Society, 2012, pp. 189−195.
    37. Petrushin N.V., Elyutin E.S., Visik E.M., Golynets S.A. Development of a single-crystal heat-resistant nickel alloy of the 5th generation. Metally, 2017, no. 6, pp. 38–51.
    38. Epishin A., Link T., Bruckner U., Portella P.D. Kinetics of topological inversion of the γ/γ'-microstructure during high temperature creep of a nickel-base superalloy. Acta Materialia, 2001, vol. 49, no. 19, pp. 4017–4023.

Full version (rus)
3.

DOI: 10.18577/2713-0193-2026-0-2-29-39

UDC: 669.018.44:669.245

Pages:: 29-39

S.V. Ovsepyan1, I.S. Kononova1, A.S. Shpagin1, M.V. Akhmedzyanov1

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

RHEOLOGICAL CHARACTERISTICS AND MICROSTRUCTURE DURING HOT UPSETTING OF P/M NICKEL-BASED SUPERALLOY EP975 FOR DISKS OF AVIATION GAS TURBINE ENGINES

The rheological properties and microstructure during hot upsetting of granulated nickel-based superalloy EP975 for aircraft gas turbine engines were studied. Flow curves of specimens were analyzed at temperatures of 1000–1180 °C and strain rates of 10–2 to 1 s–1. The following facts were determined: maximum flow stresses and deformation activation energy. A critical single-pass deformation limit was established, at which cracks do not form in the metal and grains after quenching do not grow abnormally coarse.

Keywords: nickel-based superalloy, gas turbine engine, powder metallurgy, deformation, rheology, flow curves, deformation activation energy

Reference List

    1. Kablov E.N., Antipov V.V. The Role of New Generation Materials in Ensuring the Technological Sovereignty of the Russian Federation. Vestnik Rossiyskoy akademii nauk, 2023, vol. 93, no. 10, pp. 907–916. DOI: 10.31857/S0869587323100055.
    2. Aviation Materials: A Handbook in 13 vols. 7th ed., rev. and add. Ed. E.N. Kablov. Moscow: VIAM, 2018, vol. 2: Deformable heat-resistant steels and alloys. Alloys based on refractory metals, 248 p.
    3. Lomberg B.S., Ovsepjan S.V., Bakradze M.M., Letnikov M.N., Mazalov I.S. The application of new wrought nickel alloys for advanced gas turbine engines. Aviacionnye materialy i tehnologii, 2017, no. S, pp. 116–129. DOI: 10.18577/2071-9140-2017-0-S-116-129.
    4. Kabanov I.V., Lisovsky A.V., Dmitriev A.I. Alternative scheme for the production of blanks for gas turbine engines from nickel-based heat-resistant alloy EP975-ID under the conditions of JSC metallurgical plant elektrostal. Elektrometallurgiya, 2024, no. 13, pp. 22–26.
    5. Lomberg B.S., Bakradze M.M., Chabina E.B., Filonova E.V. Interrelation of structure and properties of high-heat resisting nickel alloys for disks of gas turbine engines. Aviacionnye materialy i tekhnologii, 2011, no. 2, pp. 25–30.
    6. Logunov A.V. Heat-resistant nickel alloys for gas turbine blades and disks. Moscow: Moscow Textbooks, 2018, 592 p.
    7. Zhang B., Huang S., Zhang W. et al. Recent Development of Nickel-based Disc Alloys and Corresponding Cast-Wrought Processing Techniques. Acta Metallurgica Sinica, 2019, vol. 55, no. 9, pp. 1095–1114.
    8. Mazalov I.S., Volkov A.M., Lomberg B.S., Chabina E.B. Microstructure and mechanical properties of Ni-base superalloy VZh172, produced from granules by method of hot isostatic pressing. Trudy VIAM, 2022, no. 9 (115), pp. 15–27. Available at: http://www.viam-works.ru (accessed: June 19, 2025). DOI: 10.18577/2307-6046-2022-0-9-15-27.
    9. Volkov A.M., Karyagin D.A., Letnikov M.N. et al. Features of the production of gas turbine engine disk blanks from granules of high-heat-resistant nickel alloys. Metallurg, 2020, no. 4, pp. 75–80.
    10. Razuvaev E.I., Bubnov M.V., Bakradze M.M., Sidorov S.A. HIP and deformation of the granulated heat resisting nickel alloys. Aviacionnye materialy i tehnologii, 2016, no. S1, pp. 80–86. DOI: 10.18577/2071-9140-2016-0-S1-80-86.
    11. Mukhtarov Sh.Kh., Karyagin D.A., Logunov A.V. et al. Effect of hot working on the microstructure and tensile properties of a novel PM Re-bearing nickel base superalloy. Letters on Materials, 2022, vol. 12 (4s), pр. 457–462. URL: www.lettersonmaterials.com (accessed: June 19, 2025). DOI: 10.22226/2410-3535-2022-4-457-462.
    12. Tian G., Zou J., Wang Y., Wang W. Hot deformation behaviors and microstructure evolution in a new PM nickel-base superalloy. Advanced Materials Research, 2011, vol. 278, pp. 411–416.
    13. Gorelik S.S., Dobatkin S.V., Kaputkina L.M. Recrystallization of metals and alloys. 3rd ed., rev. and add. Moscow: MISiS, 2005, 432 p.
    14. Kochubey A.Ya., Medvedev P.N., Zhuravleva P.L. Application of X-ray diffractometry for researching structural formation processes during the hot pressure working and heat treatment of deformed metals and alloys. Trudy VIAM, 2024, no. 5 (135), pp. 50–60. Available at: http://www.viam-works.ru (accessed: June 19, 2025). DOI: 10.18577/2307-6046-2024-0-5-50-60.
    15. Ryndenkov D.V., Perevozov A.S., Rybantsova E.N., Khomutov M.G. Rheological properties of heat-resistant nickel granulated alloy EP962NP during deformation in the two-phase region at industrial stamping speeds and structural changes corresponding to deformation. Izvestiya vysshikh uchebnykh zavedeniy. Tsvetnaya metallurgiya, 2017, no. 5, pp. 69–75.
    16. Shpagin A.S., Bazhenov A.R., Antipov K.V., Oglodkova Yu.S. Construction of a rheological model of deformable aluminum alloy 1163 for computer simulation of metal pressure processes. Trudy VIAM, 2024, no. 10 (140), pp. 24–33. Available at: http://www.viam-works.ru (accessed: June 19, 2025). DOI: 10.18577/2307-6046-2024-0-10-24-33.
    17. Antolovich S.D., Armstrong R.W. Plastic strain localization in metals: origins and consequences. Progress in Materials Science, 2014, no. 59, pp. 1–160. DOI: 10.1016/j.pmatsci.2013.06.001.
    18. Localization of plastic deformation and nonequilibrium structural-deformational transformations: selected works. Almaty: Complex, 2004, 271 p.
    19. Galpin S.J. A review of microstructure phenomena during manufacture of polycrystalline Ni-based superalloys. Materials Science and Technology. Taylor & Francis Group, 2022, pp. 2–17.
    20. Gong Z., Bao H., Yang G. Dynamic Recrystallization and Hot-Working Characteristics of Ni-Based Alloy with Different Tungsten Content. Metals, 2019, vol. 9 (3), p. 298. DOI: 10.3390/met9030298.
    21. Shchetinina N.D., Rudchenko A.S., Selivanov A.A. The approaches that are used for developed of optimal strain modes of aluminum-lithium alloys (review). Trudy VIAM, 2020, no. 8 (90), pp. 20–34. Available at: http://www.viam-works.ru (accessed: June 19, 2025). DOI: 10.18577/2307-6046-2020-0-8-20-34.
    22. Tian G., Zou J., Wang Y., Wang W. Hot deformation behaviors and microstructure evolution in a new PM nickel-base superalloy 2011. Advanced Materials Research, 2011, vol. 278, pp. 411–416. DOI: 10.4028/www.scientific.net/AMR.278.411.

Full version (rus)
4.

DOI: 10.18577/2713-0193-2026-0-2-40-50

UDC: 621.791

Pages:: 40-50

M.D. Panteleev1, A.V. Sviridov1, S.D. Zotov1, E.A. Kudryavtsev2, M.G. Yakovlev2, G.R. Isakhanov2

[1] Federal state unitary enterprise «All-Russian Scientific-Research Institute of Aviation Materials» of National Research Center «Kurchatov Institute»
[2] Branch of Joint Stock Company «United Engine Corporation» «Research Institute of Technology and Organization of Engine Production»

THE FEATURES OF INERTIAL FRICTION WELDING TECHNOLOGY OF GRANULATED HEAT-RESISTANT NICKEL ALLOYS

The article presents specificities of inertial friction welding of large-sized workpieces made of granulated heat-resistant nickel alloys ВВ751П (ХН56КВМТЮБ), ВЖ178П and wrought heat-resistant nickel alloy ВЖ175-ИД (ХН54К15МБЮВТ). The research of welding modes’ ranges for workpieces – rings for rotors of GTE is presented. Mechanical properties of obtained welding samples are defined. The research of welding samples’ microstructure for presence of γʹ-phase is presented and characteristics of alloys behavior after welding-thermal cycle are discussed.

Keywords: granulated nickel alloy, inertial friction welding, microstructure, γʹ-phase, mechanical properties, low-cycle fatigue, microhardness

Reference List

    1. Kablov E.N. Dominant Focus of the National Technology Initiative. Challenges of Accelerating the Development of Additive Technologies in Russia. Metally Evrazii, 2017, no. 3, pp. 2–6.
    2. Kablov E.N. The Present and Future of Additive Technologies. Metally Evrazii, 2017, no. 1, pp. 2–6.
    3. Kablov E.N., Evgenov A.G., Bakradze M.M., Nerush S.V., Krupnina O.A. New-Generation materials and digital additive technologies for the production of resource parts by FSUE «VIAM». Part 1. Materials and synthesis technologies. Electrometallurgiya, 2022, no. 1, pp. 2–12.
    4. Brown R.J., Green A.B. Welding and processing of high-strength nickel-based superalloys. International Journal of Advanced Manufacturing Technology, 2010, vol. 48, no. 1–4, pp. 121–132.
    5. Wang L., Liu Z. Application of granular nickel-based superalloys in gas turbine blades. Aerospace Science and Technology, 2016, vol. 58, pp. 129–138.
    6. Kuznetsov E.V., Blinov A.N. Heat-resistant nickel alloys structure and properties. Metally, 2015, no. 12, pp. 45–56.
    7. Smith J.F., Jones M.T. High-temperature nickel-based alloys for aerospace applications. Journal of Materials Science and Engineering, 2008, vol. 23, no. 3, pp. 345–360.
    8. Ivanov I.I., Petrov M.A. Corrosion and protection of metals at high temperatures. Khimicheskaya promyshlennost, 1998, no. 11, pp. 67–74.
    9. Kablov E.N., Evgenov A.G., Bakradze M.M., Nerush S.V., Krupnina O.A. New generation materials and digital additive technologies for the production of resource parts by FSUE «VIAM». Part 2. Compensation and control of deviations, GIP and heat treatment. Electrometallurgiya, 2022, no. 2, pp. 2–12.
    10. Kablov E.N., Evgenov A.G., Petrushin N.V., Bazyleva O.A., Mazalov I.S., Dynin N.V. New generation materials and digital additive technologies for the production of resource parts by FSUE «VIAM». Part 3. Adaptation and creation of materials. Electrometallurgiya, 2022, no. 4, pp. 15–25.
    11. Kablov E.N., Evgenov A.G., Petrushin N.V., Bazyleva O.A., Mazalov I.S. New generation materials and digital additive technologies for the production of resource parts FSUE «VIAM». Part 4. Development of heat-resistant materials. Electrometallurgiya, 2022, no. 5, pp. 8–19.
    12. Zaitsev A.P., Kotova N.S. Alloying of Heat-Resistant Nickel Alloys: Effect on Structure and Properties. Metallurgiya, 2009, no. 8, pp. 34–40.
    13. Volkov A.M., Samorukov M.L., Ovsepyan S.V., Bakradze M.M. Features of friction rotation welding of granulated heat-resistant nickel alloy VZh178P. Svarochnoe proizvodstvo, 2020, no. 10, pp. 40–45.
    14. Lukin V.I., Kovalchuk V.G., Samorukov M.L. Development of friction rotation welding technology applied to the manufacture of a small-sized gas turbine engine rotor from heat-resistant deformable nickel alloy EP975. Proc. reports of the symposium «New materials, advanced metallurgy technologies». Moscow, 2014, p. 11.
    15. Lukin V.I., Samorukov M.L., Kovalchuk V.G. Modeling of rotational friction welding of high-heat-resistant nickel alloy VZh175. Svarochnoe proizvodstvo, 2016, no. 11, pp. 12–18.
    16. Echin A.B., Bondarenko Yu.A., Kolodyazhny M.Yu., Surova V.A. Review of perspective high-temperature superalloys based on refractory non-metallic materials for production of gas turbine engines. Aviation materials and technologies, 2023, no. 3 (72), pp. 30–41. Available at: http://www.journal.viam.ru (accessed: May 15, 2025). DOI: 10.18577/2713-0193-2023-0-3-30-41.
    17. Loshchinin Yu.V., Pakhomkin S.I., Razmakhov M.G. Phase transformation temperatures and calorimetric analysis of powder compositions of nickel-based superalloys. Aviacionnye materialy i tehnologii, 2020, no. 1 (58), pp. 79–85. DOI: 10.18577/2071-9140-2020-0-1-79-85.
    18. Davydov D.I., Kazantseva N.V., Ezhov I.V., Popov N.A. Study of structural and phase transformations in cobalt heat-resistant alloys. Proc. Int. Conf. «Physical mesomechanics. Materials with a multilevel hierarchically organized structure and intelligent production technologies». Tomsk, 2020, pp. 253–254.
    19. Smith J.F., Jones M.T. Inertia Friction Welding of Inconel 718 Turbine Blades. Journal of Materials Science and Engineering, 2008, vol. 23, no. 3, pp. 345–360.

Full version (rus)
5.

DOI: 10.18577/2713-0193-2026-0-2-51-63

UDC: 669.721.5:004.94

Pages:: 51-63

V.A. Duyunova1, I.A. Petrov1, A.A. Leonov1, N.V. Trofimov1

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

DEVELOPMENT OF MATHEMATICAL MODELS FOR PREDICTING THE PROPERTIES OF THE Mg–REE–Zn–Zr MAGNESIUM ALLOY SYSTEM AND EVALUATION OF ITS CONVERGENCE 

The article presents the results of developing statistical models for predicting the mechanical properties of magnesium alloy of the Mg–Y–Nd–Gd–Zn–Zr system. The influence analysis of yttrium, neodymium, gadolinium and zinc content on the tensile strength, yield strength and short-term strength at 250 and 300 °C is analyzed. The experimental design method was used to construct mathematical dependencies; at the first stage, a full factorial design 24 was implemented; at the second stage, an orthogonal compositional design of the second order was used. It was shown that linear regression models do not provide the required description accuracy, while second-order models are statistically adequate according to the Fisher criterion and are characterized by high values of the determination coefficient (R2 = 0,77–0,95).

Keywords: high-strength magnesium alloy, fire-resistant magnesium alloy, mathematical model, yield strength, tensile strength, short-term strength at elevated temperatures

Reference List

    1. Mordike B.L., Ebert T. Magnesium: Properties – applications – potential. Materials Science and Engineering A, 2001, vol. 302, pp. 37–45.
    2. Pekguleryuz M.O., Kaya A.A. Magnesium alloys and their applications. Advanced Engineering Materials, 2003, vol. 5, no. 12, pp. 866–878.
    3. Nie J.F. Precipitation and hardening in magnesium alloys. Metallurgical and Materials Transactions A, 2012, vol. 43, pp. 3891–3939.
    4. Rokhlin L.L. Magnesium Alloys Containing Rare Earth Metals. London: Taylor & Francis, 2003, 256 p.
    5. Easton M., StJohn D. Grain refinement of magnesium alloys. Metallurgical and Materials Transactions A, 2005, vol. 36, pp. 1911–1920.
    6. Qin G.W., Ren Y.P., Pei W.L. Effects of Zr on microstructure and mechanical properties of magnesium alloys. Materials Science and Engineering A, 2009, vol. 520, pp. 75–81.
    7. Srinivasan A., Kalidindi S.R. Computational materials science: modeling and simulation. Acta Materialia, 2010, vol. 58, pp. 1–15.
    8. Zhang Y., Liu Z., Wang Q. Prediction of mechanical properties of magnesium alloys using numerical modeling. Computational Materials Science, 2015, vol. 98, pp. 76–84.
    9. Duyunova V.A., Molodtsov S.V., Leonov A.A., Trapeznikov A.V. Application of computer modeling methods in the manufacture of complex-contoured shaped casting. Trudy VIAM, 2019, no. 11 (83), pp. 3–11. Available at: http://www.viam-works.ru (accessed: February 19, 2026). DOI: 10.18577/2307-6046-2019-0-11-3-11.
    10. Olson G.B. Computational design of hierarchically structured materials. Science, 1997, vol. 277, pp. 1237–1242.
    11. Quarteroni A., Sacco R., Saleri F. Numerical Mathematics. Berlin: Springer, 2007, 669 p.
    12. Laptev A.B., Pavlov M.R., Novikov A.A., Slavin A.V. Current trends in the development of testing materials for resistance to climate factors (review). Part 1. Testing of new materials. Trudy VIAM, 2021, no. 1 (95), pp. 114–122. Available at: http://www.viam-works.ru (accessed: February 19, 2026). DOI: 10.18577/2307-6046-2021-0-1-114-122.
    13. Saad Y. Iterative Methods for Sparse Linear Systems. Philadelphia: SIAM, 2003, 567 p.
    14. Zuev A.V., Zarichnyak Yu.P., Barinov D.Ya. Measurement of thermophysical properties rigid fiber insulation. Trudy VIAM, 2021, no. 2 (96), pp. 88–98. Available at: http://www.viam-works.ru (accessed: February 19, 2026). DOI: 10.18577/2307-6046-2021-0-2-88-98.
    15. Leonov A.A., Trofimov N.V., Duyunova V.A., Uritia Z.P. Trends in the development of cast magnesium alloys with an increased ignition temperature (review). Trudy VIAM, 2021, no. 2 (96), pp. 3–9. Available at: http://www.viam-works.ru (accessed: February 19, 2026). DOI: 10.18577/2307-6046-2021-0-2-3-9.
    16. Kablov E.N., Kutyrev A.E., Vdovin A.I., Kozlov I.A., Afanasyev-Khodykin A.N. The research of possibility of galvanic corrosion in brazed connections used in aviation engine construction. Aviation materials and technologies, 2021, no. 4 (65), pp. 3–13. Available at: http://www.journal.viam.ru (accessed: February 20, 2026). DOI: 10.18577/2713-0193-2021-0-4-3-13.
    17. Kablov E.N. Aviation Materials Science in the 21st Century. Prospects and Challenges. Aviation Materials. Selected Works of VIAM 1932–2002. Moscow: MISIS – VIAM, 2002, pp. 23–47.
    18. Kablov E.N. Modern Materials – the Basis for Innovative Modernization of Russia. Metally Evrazii, 2012, no. 3, pp. 10–15.
    19. Leonov A.A. Casting Magnesium Alloys of the Mg–REE–Zr System with Increased Ignition Temperature: thesis, Cand. Sc. (Tech.). Moscow, 2023, 125 p.
    20. Novik F.S., Arsov Ya.B. Optimization of Metal Technology Processes by Experimental Planning Methods. Moscow: Mashinostroenie; Sofia: Tekhnika, 1980, 304 p.
    21. Ksendzenko L.S., Boyko L.A., Shishkin A.V. Elements of Correlation Theory: A Textbook for Universities. Vladivostok: FEFU, 2025, 71 p.

Full version (rus)
6.

DOI: 10.18577/2713-0193-2026-0-2-64-76

UDC: 669.715

Pages:: 64-76

Yu.S. Oglodkova1, K.V. Antipov1, A.A. Selivanov1, E.A. Shestakova1, A.S. Rudchenko1

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

TECHNOLOGICAL TESTING OF PILOT-INDUSTRIAL SEMI-FINISHED PRODUCTS FROM THE ALLOY V-1381 OF THE Al–Mg–Si–Cu SYSTEM

The article describes the development from the V-1381 alloy of the Al–Mg–Si–Cu system, two structurally similar samples (SSS) of the side panel fragment of the fuselage for manufacturing by laser welding and riveting. The paper examines the influence of laser welding process parameters on the microstructure and mechanical properties of welded joints of semi-finished products in relation to SSS. Technological testing of sheets and pressed profiles from V-1381 alloy was carried out and high manufacturability of semi-finished products during mechanical processing and suitability for moulding in the annealed state was confirmed. Bench tests of manufactured SSS were carried out.

Keywords: Al–Mg–Si–Cu system, 6xxx series alloys, V-1381 alloy, laser welding, riveting, structural-similar sample, technological testing

Reference List

    1. Antipov V.V., Serebrennikova N.Yu., Nefedova Yu.N., Kozlova O.Yu., Panteleev M.D., Osipov N.N., Klychеv A.V. Manufacturing capability of Al–Li 1441 alloy details. Trudy VIAM, 2018, no. 10 (70), pp. 17–26. Available at: http://www.viam-works.ru (accessed: April 14, 2025). DOI: 10.18577/2307-6046-2018-0-10-17-26.
    2. Kablov E.N. New generation materials and digital technologies for their processing. Vestnik Rossiyskoy akademii nauk, 2020, vol. 90, no. 4, pp. 331–334.
    3. Kablov E.N. 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, no. 1 (34), pp. 3–33. DOI: 10.18577/2071-9140-2015-0-1-3-33.
    4. Kablov E.N. The strategic directions of development of materials and technologies of their processing for the period to 2030. Aviacionnye materialy i tehnologii, 2012, no. S, pp. 7–17.
    5. Antipov V.V., Klochkova Yu.Yu., Romanenko V.A. Modern aluminum and aluminum-lithium alloys. Aviacionnye materialy i tehnologii, 2017, no. S, pp. 195−211. DOI: 10.18577/2071-9140-2017-0-S-195-211.
    6. Duyunova V.A., Nechaikina T.A., Oglodkov M.S., Yakovlev A.L., Leonov A.A. Promising developments in the field of lightweight materials for modern aerospace technology. Tekhnologiya legkikh splavov, 2018, no. 4, pp. 28–43.
    7. Panteleev M.D., Sviridov A.V., Odintsov N.S., Bondarenko S.V. Survivability of welded fuselage elements made of heat-resistant aluminum alloys V-1213 and 1151. Trudy VIAM, 2024, no. 3 (133), pp. 30–40. Available at: http://www.viam-works.ru (accessed: April 15, 2025). DOI: 10.18577/2307-6046-2024-0-3-30-40.
    8. Antipov V.V., Panteleev M.D., Sviridov A.V., Skupov A.A., Odintsov N.S. Heat-resistant aluminum alloys 1151 and B-1213 welded fuselage panels fabrication and testing. Trudy VIAM, 2023, no. 5 (123), pp. 27–39. Available at: http://www.viam-works.ru (accessed: April 15, 2025). DOI: 10.18577/2307-6046-2023-0-5-33-42.
    9. Kolobnev N.I., Ber L.B., Khokhlatova L.B., Ryabov D.K. Structure, properties and application of alloys of the Al–Mg–Si–(Cu) system. Metallovedenie i termicheskaya obrabotka metallov, 2011, no. 9, pp. 40–45.
    10. Selivanov A.A., Antipov K.V., Oglodkova Yu.S., Rudchenko A.S. Structure and properties of sheets from the new alloy B-1381. Perspektivnye materialy, 2021, no. 5, pp. 18–27. DOI: 10.30791/1028-978Х-2021-5-18-27.
    11. Antipov K.V., Benarieb I., Oglodkova Yu.S., Rudchenko A.S. Structure and properties of industrial semi-finished products made of welded corrosion-resistant aluminum alloy of the Al–Mg–Si–Cu system. Perspektivnye materialy, 2022, no. 3, pp. 24–35. DOI: 10.30791/1028-978Х-2022-3-24-35.
    12. Kuznetsov A.O., Oglodkov M.S., Klimkina A.A. The influence of chemical composition on structure and properties of Al–Mg–Si alloy. Trudy VIAM, 2018, no. 7 (67), pp. 3–9. Available at: http://www.viam-works.ru (accessed: April 15, 2025). DOI: 10.18577/2307-6046-2018-0-7-3-9.
    13. Oglodkova Yu.S., Antipov K.V., Panteleev M.D., Rudchenko A.S. Study of weldability of semi-finished products from Al–Mg–Si–Cu alloy system. Perspektivnye materialy, 2023, no. 3, pp. 5–13. DOI: 10.30791/1028-978Х-2023-3-5-13.
    14. Panteleev M.D., Sviridov A.V., Skupov A.A., Odintsov N.S. Perspective welding technologies of aluminum-lithium alloy V-1469 applied to fuselage panels. Trudy VIAM, 2020, no. 12 (94), pp. 35–46. Available at: http://www.viam-works.ru (accessed: April 04, 2025). DOI: 10.18577/2307-6046-2020-0-12-35-46.
    15. Panteleev M.D., Bakradze M.M., Skupov A.A., Scherbakov A.V., Belozor V.E. Technological features of fusion welding of aluminum alloy V-1579. Aviacionnye materialy i tehnologii, 2018, no. 3 (52), pp. 11–17. DOI: 10.18577/2071-9140-2018-0-3-11-17.
    16. Panteleev M.D., Sviridov A.V., Skupov A.A. Welding features of heat-resistant aluminum alloys, alloy V-1213 and 1151. Trudy VIAM, 2022, no. 9 (115), pp. 28–39. Available at: http://www.viam-works.ru (accessed: April 04, 2025). DOI: 10.18577/2307-6046-2022-0-9-28-38.

Full version (rus)
7.

DOI: 10.18577/2713-0193-2026-0-2-77-93

UDC: 620.179.162

Pages:: 77-93

T.A. Shlyapnikova1, A.L. Ivanov1, A.V. Somov1, A.F. Dorzhiev1

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

MODERN TRENDS IN HEAT TREATMENT AND THERMOMECHANICAL TREATMENT OF HIGH-STRENGTH Al–Zn–Mg–Cu ALUMINUM ALLOYS 

The article presents an overview of domestic and foreign research devoted to methods of heat and thermomechanical treatment of high-strength aluminum alloys of the Al–Zn–Mg–Cu system, with emphasis on their application in the aerospace industry. Key areas for improving conventional techniques (homogenization, quenching, stepped aging) and development of innovative processing regimes are considered, aiming to provide modern aircraft structures with materials possessing a required set of properties ‒ high strength, corrosion resistance and fracture toughness, as well as manufacturability in the production of semi-finished products and components.

Keywords: high-strength aluminum alloy, Al–Zn–Mg–Cu system alloys, heat treatment, thermo-mechanical treatment, artificial aging, structure, mechanical properties, autoclave forming

Reference List

    1. Kablov E.N. 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, no. 1 (34), pp. 3–33. DOI: 10.18577/2071-9140-2015-0-1-3-33.
    2. Kablov E.N., Antipov V.V. The Role of New Generation Materials in Ensuring the Technological Sovereignty of the Russian Federation. Vestnik Rossiyskoy akademii nauk, 2023, vol. 93, no. 10, pp. 907–916.
    3. Fridlyander I.N., Senatorova O.G., Tkachenko E.A., Molostova I.I. Development and application of high-strength Al–Zn–Mg–Cu alloys for aerospace technology. 75th Anniversary. Aviation Materials. Moscow: VIAM, 2007, pp. 155–163.
    4. Kablov E.N. New Generation Materials and Digital Technologies for Their Processing. Vestnik Rossiyskoy akademii nauk, 2020, vol. 90, no. 4, pp. 331–334. DOI: 10.31857/S0869587320040052.
    5. Fridlyander I.N. Aluminum alloys in aircraft in the period 1970–2015. Tekhnologiya legkikh splavov, 2002, no. 4, pp. 12–17.
    6. Antipov V.V. Prospects for development of aluminium, magnesium and titanium alloys for aerospace engineering. Aviacionnye materialy i tehnologii, 2017, no. S, pp. 186–194. DOI: 10.18577/2071-9140-2017-0-S-186-194.
    7. Kolobnev N.I., Ber L.B., Tsukanov S.L. Heat Treatment of Wrought Aluminum Alloys. Moscow: APRAL, 2020, 552 p.
    8. Selivanov A.A., Tkachenko E.A., Astashkin A.I., Oglodkova Yu.S. Trends in the development of aluminum alloys for power elements of aviation products in Russia and abroad. Review. Part 1: Alloys based on the Al–Cu–Mg, Al–Zn–Mg–Cu systems. Metallurg, 2023, no. 11, pp. 33–39. DOI: 10.52351/00260827_2023_11_33.
    9. Nefedova Yu.N., Shlyapnikova T.A., Ivanov A.L., Sedelnikov V.V. Methods for reducing residual stresses during hardening of high-strength aluminum alloys. Trudy VIAM, 2023, no. 7 (125), pp. 23–33. Available at: http://www.viam-works.ru (accessed: March 10, 2025). DOI: 10.18577/2307-6046-2023-0-7-23-33.
    10. Guo Z., Zhao G., Chen X.G. Effects of two-step homogenization on precipitation behavior of Al3Zr dispersoids and recrystallization resistance in 7150 aluminum alloy. Materials Characterization, 2015, vol. 102, pp. 122–130. DOI: 10.1016/j.matchar.2015.02.016.
    11. Lu X.Y., Guo E.J., Rometsch P., Wang L.J. Effect of one-step and two-step homogenization treatments on distribution of Al3Zr dispersoids in commercial AA7150 aluminium alloy. Transactions of Nonferrous Metals Society of China, 2012, vol. 22, no. 11, pp. 2645–2651. DOI: 10.1016/S1003-6326(11)61512-4.
    12. Ou B.L., Yang J.G., Wei M.Y. Effect of homogenization and aging treatment on mechanical properties and stress-corrosion cracking of 7050 alloys. Metallurgical and Materials Transactions A, 2007, vol. 38, pp. 1760–1773. DOI: 10.1007/s11661-007-9200-z.
    13. Deng Y.L., Zhang Y.Y., Wan L. et al. Three-stage homogenization of Al–Zn–Mg–Cu alloys containing trace Zr. Metallurgical and Materials Transactions A, 2013, vol. 44, pp. 2470–2477. DOI: 10.1007/s11661-013-1639-5.
    14. Tkachenko E.A., Latushkina L.V., Valkov V.Ya., Shomin V.A. Influence of homogenization modes on the structure and properties of ingots and pressed-stamped semi-finished products from alloy 1933. Tekhnologiya legkikh splavov, 2002, no. 4, pp. 34–38.
    15. Vakhromov R.O., Tkachenko E.A., Lukina E.A., Selivanov A.A. Influence of homogenization annealing on structure and properties of ingots from 1933 alloy of Al–Zn–Mg–Cu system. Trudy VIAM, 2015, no. 11, pp. 3–12. Available at: http://www.viam-works.ru (accessed: February 26, 2025). DOI: 10.18577/2307-6046-2015-0-11-1-1.
    16. Astashkin A.I., Babanov V.V., Selivanov A.A., Tkachenko E.A. Influence of homogenization modes of ingots and heat treatment of sheets from alloy V95oсh-Т2 on their structure and properties. Trudy VIAM, 2025, no. 3 (145), pp. 12–22. Available at: http://www.viam-works.ru (accessed: April 07, 2025). DOI: 10.18577/2307-6046-2025-0-3-12-22.
    17. Huang Y., Zhang C., Ma Y., Liu Y. Effect of homogenization on the dissolution and precipitation behaviors of intermetallic phase for a Zr and Er containing Al–Zn–Mg–Cu alloy. Progress in Natural Science: Materials International, 2020, vol. 30 (1), pp. 47–53. DOI: 10.1016/j.pnsc.2019.12.002.
    18. Kolobnev N.I., Senatorova O.G. Patterns of change in properties during hardening. Metallurgy of aluminum and its alloys: handbook. Moscow: Metallurgiya, 1983, рp. 143–180.
    19. Tsukrov S.L. Development of continuous heat treatment lines for aluminum alloy strips. Tekhnologiya legkikh splavov, 2018, no. 4, pp. 85–91.
    20. Nechaykina T.A., Oglodkov M.S., Ivanov A.L., Kozlova O.Yu., Yakovlev S.I., Shlyapnikov M.A. Features of hardening of wide cladding sheets from V95p.ch. aluminum alloy on a continuous heat treatment line. Trudy VIAM, 2021, no. 11 (105), pp. 25–33. Available at: http://www.viam-works.ru (accessed: March 12, 2025). DOI: 10.18577/2307-6046-2021-0-11-25-33.
    21. Koptyug V.A., Fridlyander I.N. Cooling media with polymer additives for low-deformation hardening of aluminum alloys. Metallurgy of aluminum alloys. Moscow: Nauka, 1985, pp. 55–60.
    22. Ivanov A.L., Sidelnikov V.V., Nechaikina T.A., Kozlova O.Yu. Influence of low-deformation hardening on a set of properties of sheet parts made of aluminum alloys. Metallovedenie i termicheskaya obrabotka metallov, 2021, no. 10, pp. 9–15. DOI: 10.30906/mitom.2021.10.9-15.
    23. Low-deformation hardening of aluminum alloys: pat. 2574928 Rus. Federation; appl. 14.11.14; publ. 02.10.16.
    24. Bates S.E., Totten J.E. Method of selecting a quenching medium for aluminum parts. Promyshlennaya teplotekhnika, 1989, vol. 11, no. 6, pp. 86–100.
    25. Goryushin V., Shevchenko S.Yu. On the use of polymer quenching media in industry. Metallovedenie i termicheskaya obrabotka metallov, 2010, no. 6 (60), pp. 26–30.
    26. Zhou В., Liu B., Zhang S. The advancement of 7XXX series aluminum alloy for aircraft structures: a review. Metals, 2021, vol. 11 (5), no. 718, pp. 1–29. DOI: 10.3390/met11050718.
    27. Vahromov R.O., Tkachenko E.A., Popova O.I., Milevskaya T.V. Summarizing of the experience of usage and optimization of manufacturing technology semi-fished product of high strength aluminum alloy 1933 for the primary structures of modern aircraft. Aviacionnye materialy i tehnologii, 2014, no. 2, pp. 34–39. DOI: 10.18577/2071-9140-2014-0-2-34-39.
    28. Senatorova O.G., Antipov V.V., Bronz A.V., Somov A.V., Serebrennikova N.Yu. High-strength and super-strong alloys of the traditional Al–Zn–Mg–Cu system, their role in technology and development possibilities. Tekhnologiya legkikh splavov, 2016, no. 2, pp. 43–49.
    29. Senatorova O.G., Bronz A.V., Cheverikin V.V., Somov A.V., Blinova N.E. Study of the structure and properties of high-strength aluminum alloys of the Al–Zn–Mg–Cu system. Metallurg, 2016, no. 9, pp. 78–82.
    30. Nechaikina T.A., Somov A.V., Ivanov A.L., Kozlova O.Yu. Study of the influence of thermal strengthening in the T1 mode on the structure and set of properties of pressed strips from a promising super-strong aluminum alloy of the Al–Zn–Mg–Cu system. Materialovedenie, 2020, no. 10, pp. 11–16.
    31. Kablov E.N., Nechaikina T.A., Somov A.V., Ivanov A.L., Murzabaeva O.Yu. Influence of heat treatment on the structure and properties of pressed semi-finished products from a promising super-strong aluminum alloy B-1977. Metallovedenie i termicheskaya obrabotka metallov, 2023, no. 1 (811), pp. 28–33. DOI: 10.30906/mitom.2023.1.28-33.
    32. Astashkin A.I., Babanov V.V., Selivanov A.A., Tkachenko E.A., Gusev D.V., Tsarev M.V. Improving the hardenability of massive forgings from alloys of the Al–Zn–Mg–Cu system by balanced alloying with zinc and magnesium. Aviation materials and technologies, 2021, no. 2 (63), pp. 35–42. Available at: http://www.journal.viam.ru (accessed: February 14, 2025). DOI: 10.18577/2713-0193-2021-0-2-35-42.
    33. Astashkin A.I., Babanov V.V., Selivanov A.A., Tkachenko E.A. Structure and properties of massive forgings with a reduced level of residual stresses made of aluminum alloy 1933sb of balanced composition. Trudy VIAM, 2021, no. 7 (101), pp. 13–21. Available at: http://www.viam-works.ru (accessed: February 06, 2025). DOI: 10.18577/2307-6046-2021-0-7-13-21.
    34. Shlyapnikova T.A., Somov A.V., Ivanov A.L. Structure and properties of pressed semi-finished products made of high-strength aluminum alloy B-1977 after three-stage aging. Metallovedenie i termicheskaya obrabotka metallov, 2024, no. 10 (832), pp. 44–51. DOI: 10.30906/mitom.2024.10.44–51.
    35. Ranganatha R., Anil Kumar V., Vaishaki Nandi S. et al. Multi-stage heat treatment of aluminum alloy AA7049. Transactions of Nonferrous Metals Society of China, 2013, vol. 23 (6), pp. 1570–1575. DOI: 10.1016/S1003-6326(13)62632-1.
    36. Wang Y.L., Pan Q.L., Wei L.L. et al. Effect of retrogression and reaging treatment on the microstructure and fatigue crack growth behavior of 7050 aluminum alloy thick plate. Materials and Design, 2014, vol. 55, pp. 857–863. DOI: 10.1016/j.matdes.2013.09.063.
    37. Birbilis D.K.N., Rometsch P.A. The effect of pre-ageing temperature and retrogression heating rate on the strength and corrosion behavior of AA7150. Corrosion Science, 2012, vol. 54, pp. 17–25. DOI: 10.1016/j.corsci.2011.08.042.
    38. Zhu Q.Q., Cao L.F., Wu X.D. et al. Effect of Ag on age-hardening response of Al–Zn–Mg–Cu alloys. Materials Science and Engineering: A, 2019, vol. 754, pp. 265–268. DOI: 10.1016/j.msea.2019.03.090.
    39. He B., Cao L., Wu X. et al. Effect of continuous retrogression and re-ageing treatment on mechanical properties, corrosion behavior and microstructure of an Al–Zn–Mg–Cu alloy. Journal of Alloys and Compounds, 2024, vol. 970, art. 172592. DOI: 10.1016/j.jallcom.2023.172592.
    40. Huo W., Hou L., Cui H. et al. Fine-grained AA 7075 processed by different thermo-mechanical processings. Materials Science and Engineering: A, 2014, vol. 618, pp. 244–253. DOI: 10.1016/j.msea.2014.09.026.
    41. Li H., Xu W., Wang Z. et al. Effects of re-ageing treatment on microstructure and tensile properties of solution treated and cold-rolled Al‒Cu‒Mg alloys. Materials Science and Engineering: A, 2016, vol. 650, pp. 254–263. DOI: 10.1016/j.msea.2015.10.051.
    42. Zuo J.R., Hou L.G., Shi J.T. et al. Effect of deformation induced precipitation on grain refinement and improvement of mechanical properties AA 7055 aluminum alloy. Materials Characterization, 2017, vol. 130, pp. 123–134. DOI: 10.1016/j.matchar.2017.05.038.
    43. Chen Z., Lu C., Peng J., Yuan Z. Thermo-mechanical treatment regulation of microstructure and comprehensive performance in Al–Zn–Mg–Cu alloy. MATEC Web of Conferences, 2020, vol. 326, no. 05004. DOI: 10.1051/matecconf/202032605004.
    44. Pitcher P.D., Styles C.M. Creep age forming of 2024A, 8090 and 7449 Alloys. Materials science forum, 2000, vol. 331–337, pp. 455–460. DOI: 10.4028/www.csientific.net/MSF.331-337.455.
    45. Adachi T., Kimura S., Nagayama T. et al. Age forming technology for aircraft wing skin. Proceedings of 9-th International Conference on Aluminium Alloys (Australia). Institute of Materials Engineering Australasia Ltd., 2004, pp. 202–207.
    46. Robey R.F., Prangnell P.B., Dif R. A comparison of the stress relaxation behavior of three aluminium aerospace alloys for use in age forming applications. Proceedings of 9-th International Conference on Aluminium Alloys (Australia). Institute of Materials Engineering Australasia Ltd., 2004, pp. 132–138.
    47. Bakavos D., Prangnell P.B., Dif R. A comparison of the effects of ageforming on the precipitation behaviour in 2XXX, 6XXX and 7XXX aerospace alloys. Proceedings of 9-th International Conference on Aluminium Alloys (Australia). Institute of Materials Engineering Australasia Ltd., 2004, pp. 124–131.
    48. Ogurtsov P.S., Soloviev V.A., Senatorova O.G., Shestov V.V., Antipov V.V. Studies of the process of autoclave forming of aircraft wing panels made of high-strength aluminum alloys in the creep state. Reports of Int. Sci.-tech. conf. «Development of fundamental principles of materials science of light alloys and composite materials based on them for the creation of products of aerospace and nuclear engineering». Moscow, 2013, p. 21.
    49. Kablov E.N., Antipov V.V., Serebrennikova N.Yu., Sidelnikov V.V., Nefedova Yu.N., Ogurtsov Yu.N., Soloviev V.A. Technological features of autoclave molding of complex-shaped parts from B95och alloy sheet. Vestnik mashinostroyeniya, 2021, no. 6, pp. 62–66. DOI: 10.36652/0042-4633-2021-6-62-66.

Full version (rus)
8.

DOI: 10.18577/2713-0193-2026-0-2-94-107

UDC: 678.8

Pages:: 94-107

P.G. Belinis1, Yu.V. Lukyanenko1, V.N. Rogozhnikov1, R.G. Tsykun1, K.I. Donetskiy2

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

STUDYING THE POSSIBILITY OF APPLYING POLYMER COMPOSITES  BASED ON 3D REINFORCED PREFORMS FOR THE MANUFACTURING  OF AIRCRAFT FRAME STRUCTURES

This article considers developments in the manufacturing and research of carbon fiber-reinforced composites based on 3D reinforced carbon fiber preforms. The obtained material samples of various thicknesses were milled and then used as aircraft structural frames. The failure behavior of polymer matrix composites reinforced with 3D woven preforms under mechanical loading is analyzed. The advantages of using such materials as functional components exposed to intense vibration are demonstrated.

Keywords: 3D weaving, polymer composite materials, volume-reinforced woven preforms, non-autoclave molding, polymer matrix, aircraft

Reference List

    1. Kablov E.N., Antipov V.V. The role of new generation materials in ensuring the technological sovereignty of the Russian Federation. Vestnik Rossiyskoy akademii nauk, 2023, vol. 93, no. 10, pp. 907–916.
    2. Kablov E.N. New Generation Materials and Technologies for Their Digital Processing. Herald of the Russian Academy of Sciences, 2020, vol. 90, no. 2, pp. 225–228.
    3. Onishchenko G.G., Kablov E.N., Ivanov V.V. Scientific and technological development of Russia in the context of achieving national goals: problems and solutions. Innovatsii, 2020, no. 6 (260), pp. 3–16.
    4. Yakovlev N.O., Gulyaev A.I., Lashov O.A. Crack firmness of layered polymeric composite materials (review). Trudy VIAM, 2016, no. 4, pp. 106–114. Available at: http://www.viam-works.ru (accessed: August 26, 2025). DOI: 10.18577/2307-6046-2016-0-4-12-12.
    5. Doneckij K.I., Karavaev R.Yu., Raskutin A.E., Panina N.N. Properties of carbon fiber and fiberglass on the basis of braiding preforms. Aviacionnye materialy i tehnologii, 2016, no. 4 (45), pp. 54–59. DOI: 10.18577/2071-9140-2016-0-4-54-59.
    6. Donetskiy K.I., Karavayev R.Yu., Raskutin A.Ye., Dun V.A. Carbon fibers composite material on the basis of volume reinforcing triax braiding preformes. Trudy VIAM, 2019, no. 1 (73), pp. 55–63. Available at: http://www.viam-works.ru (accessed: September 10, 2025). DOI: 10.18577/2307-6046-2019-0-1-55-63.
    7. Mohamed M.H., Bogdanovich А.Е. Comparetive analysis of different 3D weaving processes, machines and products. Report theses «ICCM 17, 3D Textiles & Composites». Edinburgh, 2009, pp. 1–10.
    8. Lee B., Leong K.H., Herszberg I. Effect of weaving on the tensile properties of carbon fibre tows and woven composites. Journal of Reinforced Plastics and Composites, 2001, nо. 20 (8), pp. 652–670. DOI: 10.1177/073168401772679011.
    9. Ding Y.Q., Yan Y., M Ilhagger R., Brown D. Comparison of the fatigue behavior of 2-D and 3-D woven fabric reinforced composites. Journal of Materials Processing Technology, 1995, nо. 55, pp. 171–177. DOI: 10.1016/0924-0136(95)01950-2.
    10. Belinis P.G., Donetskiy K.I., Lukyanenko Yu.V., Rogozhnikov V.N., Mayer Yu., Bystrikova D.V. Volume reinforcing solid-woven preforms for manufacturing of polymer composite materials (review). Aviacionnye materialy i tehnologii, 2019, no. 4 (57), pp. 18–26. DOI: 10.18577/2071-9140-2019-0-4-18-26.
    11. Saleh M.N., Yudhanto A., Potluri P. et al. Characterising the loading direction sensitivity of 3D woven composites: Effect of z-binder architecture. Composites Part A: Applied Science and Manufacturing, 2016, no. 90, pp. 577–588. DOI: 10.1016/j.compositesa.2016.08.028.
    12. Lomov S.V., Bogdanovich A.E., Ivanov D.S. et al. A comparative study of tensile properties of non-crimp 3D orthogonal weave and multi-layer plain weave E-glass composites. Part 1: Materials, methods and principal results. Composites Part A: Applied Science and Manufacturing, 2009, no. 40, pp. 1134–1143. DOI: 10.1016/j.compositesa.2009.03.012.
    13. Gerlach R., Siviour C.R., Wiegand J., Petrinic N. In-plane and through-thickness properties, failure modes, damage and delamination in 3D woven carbon fibre composites subjected to impact loading. Composites Science and Technology, 2012, no. 72, pp. 397–411. DOI: 10.1016/j.compscitech.2011.11.032.
    14. Startsev V.O., Antipov V.V., Slavin A.V., Gorbovets M.A. Modern domestic polymer composite materials for aviation industry (review). Aviation materials and technologies, 2023, no. 2 (71), pp. 122–144. Available at: http://www.journal.viam.ru (accessed: August 31, 2025). DOI: 10.18577/2713-0193-2023-0-2-122-144.
    15. Karimbaev T.D., Luppov A.A., Afanasyev D.V. Carbon Fiber Fan Blades for Advanced Engines. Achievements and Challenges. Dvigatel, 2011, no. 6, pp. 4–9.
    16. Bogomolov P.I., Kozlov I.A., Birulya M.A. Review of Modern Manufacturing Technologies for Volume-Reinforcing Preforms for Advanced Composite Materials. Tekhniko-tekhnologicheskiye problemy servisa, 2017, no. 1, pp. 22–27.
    17. Evdokimov A.A., Gulyaev I.N., Zelenina I.V. Investigation of the physicomechanical properties and microstructure of volume-reinforced carbon fiber reinforced plastic. Trudy VIAM, 2019, no. 4 (76), pp. 38–47. Available at: http://www.viam-works.ru (accessed: August 11, 2025). DOI: 10.18577/2307-6046-2019-0-4-38-47.
    18. Lee L., Rudov-Clark S., Mouritz A. et al. Effect of weaving damage on the tensile properties of three-dimensional woven composites. Composite Structures, 2002, no. 57, pp. 405–413. DOI: 10.1016/s0263-8223(02)00108-3.
    19. Callus P.J., Mouritz A.P., Bannister M.K., Leong K.H. Tensile properties and failure mechanisms of 3D woven GRP composites. Composites, 1999, no. 30A, pp. 1277–1287.
    20. Kuo W.-S., Ko T.-H. Compressive damage in 3-axis orthogonal fabric composites. Composites, 2000, no. 31A, pp. 1091–1105.
    21. Donetskiy K.I., Usacheva M.N., Khrulkov A.V. Infusion methods for the manufacture of polymer composite materials (review). Part 1. Trudy VIAM, 2022, no. 6 (112), pp. 58–67. Available at: http://www.viam-works.ru (accessed: August 26, 2025). DOI: 10.18577/2307-6046-2022-0-6-58-67.
    22. Composition of and method for making high performance resins for infusion and transfer molding processes: pat. 6359107 US; appl. 18.05.00; publ. 19.03.02.
    23. Panina N.N., Kim M.A., Gurevich Ya.M. et al. Binders for non-autoclave molding of products from polymer composite materials. Klei. Germetiki. Tekhnologii, 2013, no. 10, pp. 18–27.
    24. Merkulova Yu.I., Muhametov R.R. Development of a low-viscosity epoxy binder for processing by vacuum infusion. Aviacionnye materialy i tehnologii, 2014, no. 1, pp. 39–41. DOI: 10.18577/2071-9140-2014-0-1-39-41.
    25. Khaliullin V.I., Batrakov V.V. Technology of manufacturing products from composites: technology of integrated structures: textbook. Kazan: KNITU-KAI Publ. House, 2018, 92 p.
    26. Fishpool D.T., Rezai A., Baker D. et al. Interlaminar toughness characterisation of 3D woven carbon fibre composites. Plastics, Rubber and Composites, 2013, no. 42, pp. 108–114. DOI: 10.1179/1743289812Y.0000000036.
    27. Khusnullina A.R. A Review of Modern Technologies for the Manufacturing of Solid-Woven Volume-Reinforced Preforms Used for the Production of Polymer Composite Materials. Proceedings of the 20th All-Rus. with Int. Participation Sc. and Pract. Conf. with Elements of a Scientific School for Students and Young Scientists. Kazan: KNITU Publ. House, 2024, pp. 322–325.
    28. Components and Spare Parts for Quadcopters. Available at: https://carbonstore.ru/article/quadro/ (accessed: October 10, 2025).
    29. Kakhanchik-Pilinoga E., Svistunova A., Luzan M., Bakaev A. Application of advanced composite materials in unmanned aerial vehicles. Nauka i innovatsii, 2017, no. 6 (172), pp. 34–38.
    30. Mishkin S.I. Application of carbon fiber plastics in constructions of pilotless devices (review). Trudy VIAM, 2022, no. 5 (111), pp. 87–95. Available at: http://www.viam-works.ru (accessed: October 10, 2025). DOI: 10.18577/2307-6046-2022-0-5-87-95.
    31. Application of carbon fiber/plastic products and parts. Available at: https://comcarbo.ru/news/primenenie-izdeliy-i-detaley-iz-ugleplastika-ka... (accessed: October 10, 2025).

Full version (rus)
9.

DOI: 10.18577/2713-0193-2026-0-2-108-121

UDC: 678:541.64

Pages:: 108-121

Yu.A. Egorov1, M.A. Guseva1, E.V. Kurshev1, N.V. Antyufeeva1

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

INVESTIGATION OF THE CURING PROCESS OF THERMOSETTING EPOXY SYSTEMS FOR COMPOSITE MATERIALS

Investigations of the curing process of two thermosetting compositions were performed using oscillatory rheometry and dielectric analysis. These compositions differ in component content and functionality – the structure of the initial epoxy components and aromatic amines acting as hardeners. The glass transition temperatures of the binders cured under different regimes were determined. Scanning electron microscopy revealed differences in the microphase composition and homogeneity of the obtained materials.

Keywords: thermosetting epoxy resins, polymer composite material, morphology, thermal analysis, monitoring of curing process

Reference List

    1. Composite materials in aerospace design. Еds. G.I. Zagainov, G.E. Lozino-Losinsky. Springer Science+Business Media, B.V., 1996, 445 p.
    2. Maenson J.-A.E., Wakeman M.D., Bernet N. Composite processing and manufacturing – An overview. Comprehensive composite materials, 2000, vol. 2, pp. 577–607.
    3. Parveez B., Kittur M.I., Badruddin I.A. et al. Scientific advancements in composite materials for aircraft applications: A review. Polymers, 2022, vol. 14, p. 5007. DOI: 10.3390/polym14225007.
    4. Gunyaeva A.G., Kurnosov A.O., Gulyaev I.N. High-temperature polymer composite materials developed FSUE «VIAM» for aerospace engineering: past, present and future (review). Trudy VIAM, 2021, no. 1 (95), pp. 43–53. Available at: http://www.viam-works.ru (accessed: April 15, 2025). DOI: 10.18577/2307-6046-2021-0-1-43-53.
    5. Mikhailin Yu.A. Structural polymer composite materials. 2nd ed. St. Petersburg: Scientific Foundations and Technologies, 2010, 822 p.
    6. Bazhenov S.L., Berlin A.A., Kulkov A.A., Oshmyan V.G. Polymer composite materials. Dolgoprudny: Intellect, 2010, 352 p.
    7. Ivanov N.V., Gurevich Ya.M., Khaskov M.A., Akmeev A.R. Mode studying curing binding VSE-34 and its influences on mechanical properties. Aviacionnyye materialy i tehnologii, 2017, no. 2 (47), pp. 50−55. DOI: 10.18577/2071-9140-2017-0-2-50-55.
    8. Veshkin E.A., Slavin A.V., Postnova M.V., Apalkova A.V. The role of temperature-time curing conditions in the formation of unidirectional and equally strong carbon fiber plastics properties. Aviation materials and technologies, 2025, no. 2 (79), pp. 59–71. Available at: http://www.journal.viam.ru (accessed: April 10, 2025). DOI: 10.18577/2713-0193-2025-0-2-59-71.
    9. Gamazina A.V., Kurnosov A.O., Vavilova M.I., Kochetov N.R. Investigation of fiberglass properties based on the melt binder VSE-1212 for radio engineering purposes. Trudy VIAM, 2024, no. 12 (142), pp. 56–65. Available at: http://www.viam-works.ru (accessed: April 15, 2025). DOI: 10.18577/2307-6046-2024-0-12-56-65.
    10. Malkin A.Ya., Begishev V.P. Chemical molding of polymers. Moscow: Khimiya, 1991, 239 p.
    11. Deev I.S., Kobets L.P. Structure formation in filled thermosetting polymers. Kolloidnyj zurnal, 1999, vol. 61, no. 5, pp. 650–660.
    12. Nawab Y., Shahid S., Boyard N., Jacquemin F. Chemical shrinkage characterization techniques for thermoset resins and associated composites. Journal of Materials Science, 2013, vol. 48 (16), pp. 5387–5409. DOI: 101007/s10853-013-7333-6.
    13. Jorgensen J.K., Maes V.K., Mikkelsen L.P., Andersen T.L. A precise prediction of the chemical and thermal shrinkage during curing of an epoxy resin. Polymers, 2024, vol. 16, p. 2435. DOI: 10.3390/polym16172435.
    14. Pham H.Q., Marks M.J. Ероху resins. Encyclopedia of Polymer Science and Technology. 2nd ed. New York: John Wiley & Sons, Inc., 2014, vol. 9, pp. 678−804.
    15. Irzhak V.I. Epoxy polymers and nanocomposites. Chernogolovka: Publ. house of the Institute of Problems of Chemical Physics of RAS, 2021, 319 p.
    16. Shundo A., Yamamoto S., Tanaka K. Network formation and physical properties of epoxy resins for future practical application. JACS Au, 2022, vol. 2, pp. 1522–1542. DOI: 10.1021/jacsau.2c00120.
    17. Batog A.E., Pet'ko I.P., Penczek P. Aliphatic-cycloaliphatic epoxy compounds and polymers. Advanced in Polymer Science, 1999, vol. 144, pp. 49–113.
    18. Mukhametov R.R., Petrova A.P. Thermosetting binders for polymer composites (review). Aviacionnye materialy i tehnologii, 2019, no. 3 (56), pp. 48−58. DOI: 10.18577/2071-9140-2019-0-3-48-58.
    19. Hsieh T.H., Su A.C. Cure kinetics of an epoxy-novolac molding compound. Journal of Applied Polymer Science, 1990, vol. 41 (5−6), pp. 1271−1280. DOI: 10.1002/app.1990.060410535.
    20. Salakhova R.K., Veshkin E.A., Sudin Yu.I., Tikhoobrazov A.B. Research of the properties of epoxy compositions modified with polyarylsulphone and polymer composite materials based on them. Trudy VIAM, 2023, no. 12 (130), pp. 53–62. Available at: http://www.viam-works.ru (accessed: April 15, 2025). DOI: 10.18577/2307-6046-2023-0-12-53-62.
    21. Solodilov V.I., Tretyakov I.V., Petrova T.V. et al. Influence of polyethersulfone on the fracture toughness of epoxy matrices reinforced plastics on their basis. Mechanics of composite materials, 2023, vol. 59, no. 4, pp. 743–756.
    22. Gaw K.O., Kakimoto M. Polyimide-epoxy composites. Progress in polyimide chemistry I. Advanced in Polymer Science, 1999, vol. 140, pp. 107–136.
    23. Girard-Reydet E., Riccardi C.C., Sautereau H., Pascault J.P. Epoxy-aromatic diamine kinetics. 1. Modeling and Influence of the diamine structure. Macromoleules, 1995, vol. 28, pp. 7599–7607.
    24. Flory J.P. Principles of polymer chemistry. New York: Cornell University Press, 1953, 672 p.
    25. Mezhikovsky S.M., Irzhak V.I., Chalykh A.E. Chemical physics of oligomer curing. Moscow: Yurait, 2019, 276 p.
    26. Deng Y., Martin G.C. Diffusion and diffusion-controlled kinetics during epoxy-amine cure. Macromolecules, 1994, vol. 27, pp. 5147–5153.
    27. Han C.D. Rheology and processing of polymeric materials. Oxford University Press, 2007, vol. 1: Polymer rheology, pp. 683–687.
    28. Arinina M.P., Kostenko V.A., Gorbunova I.Yu. et al. Kinetics of curing of epoxy oligomer with diaminodiphenyl sulfone. Rheology and calorimetry. Vysokomolekulyarnye soedineniya. Ser.: A. 2018, vol. 60, no. 5, pp. 418−425. DOI: 10.1134/S2308112018050012.
    29. Gonzalez M.G., Cabanelas J.C., Baselga J. Applications of FT-IR on epoxy resins – identification, monitoring the curing process, phase separation and water uptake. Infrared spectroscopy − materials science, engineering and technology. Ed. Th. Theophanides. In Tech Publishers, 2012, pp. 261−284.
    30. Malkin A.Ya., Kulichikhin S.G. Rheology in the processes of formation and transformation of polymers. Moscow: Khimiya, 1985, 240 p.
    31. Read D.J. From reactor to rheology in industrial polymers. Journal of Polymer Science. Part B: Polymer Physics, 2015, vol. 53, pp. 123–141. DOI: 10.1002/polb.23551.
    32. Senturia S.D., Sheppard Jr. N.F. Dielectric analysis of thermoset cure. Advanced in Polymer Science, 1986, vol. 80, pp. 1–47.
    33. Schultz J.W. Dielectric spectroscopy in analysis of polymers. Encyclopedia of Analytical Chemistry. John Wiley and Sons, 2006, pp. 1–17. DOI: 10.1002/9780470027318.a2004.
    34. Vassilikou-Dova A., Kalogeras I.M. Dielectric analysis (DEA). Thermal analysis of polymers: fundamentals and application. Eds. J.D. Menczel, R.B. Prime. John Wiley and Sons, 2009, pp. 497–613.
    35. Winter H.H., Chambon F. Analysis of linear viscoelasticity of a crosslinking polymer at the gel point. Journal of Rheology, 1986, vol. 30, pp. 367–382. DOI: 10.1122/1.549853.
    36. Shigue C.Y., dos Santos R.G.S., de Abreu M.S.P. et al. Dielectric thermal analysis as a tool for quantitative evaluation of the viscosity and the kinetics of epoxy resin cure. IEEE transactions on applied superconductivity, 2006, vol. 16, no. 2, pp. 1786–1789. DOI: 10.1109/TASC.2005.869624.
    37. Anu S., Jomon J., Jyotishkumar P. et al. An overview of viscoelastic phase separation in epoxy based blends. Soft matter, 2020, vol. 16 (14), pp. 3363–3377. DOI: 10.1039/C9SM02361E.
    38. Tcharkhtchi A., Nony F., Khelladi S. et al. Epoxy/amine reactive systems for composite materials and their thermomechanical properties. Advances in composite manufacturing and process design. Elsevier, 2015, pp. 269–296. DOI: 10.1016/B978-1-78242-307-2/00013-0.
    39. Cheng J., Li J., Zhang J.Y. Curing behavior and thermal properties of trifunctional epoxy resin cured by 4,4′-diaminodiphenyl sulfone. eXPRESS Polymer Letters, 2009, vol. 3, no. 8, pp. 501–509. DOI: 10.3144/expresspolymlett.2009.62.
    40. Lee J.K., Pae K.D. Mechanical and thermal properties of a diglycidyl ether of bisphenol-A (DGEBA) – 4,4′-diaminodiphenyl sulfone (DDS) system cured under hydrostatic pressure. Polymer Journal, 1994, vol. 26, no. 10, pp. 1093–1099.
    41. Kablov E.N. 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, no. 1 (34), pp. 3–33. DOI: 10.18577/2071-9140-2015-0-1-3-33.

Full version (rus)
10.

DOI: 10.18577/2713-0193-2026-0-2-122-131

UDC: 678.83

Pages:: 122-131

R.K. Salakhova1, E.A. Veshkin1, V.V. Kalenov1

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

TWO-FACTOR OPTIMIZATION MODELS OF PHYSICAL, CHEMICAL, AND MECHANICAL PROPERTIES OF STRUCTURAL ORGANOPLASTIC

Adequate two-factor models for optimizing sheet thickness and tensile strength of structural organoplastic laminate based on SVM aramid fabric and an epoxy adhesive film are presented. Regression equations are derived that describe the dependence of response functions (sheet thickness, tensile strength) on optimization factors (fabric surface density, adhesive film mass per square meter, and fabric breaking load on the warp). Ranges of model factors are determined that ensure optimal thickness and strength properties of the organotextolite.

Keywords: organotextolite, two-factor model, thickness of organotextolite sheets, tensile strength, multiple correlation coefficient, regression coefficient, analysis of variance

Reference List

    1. Kablov E.N. Composites: Today and Tomorrow. Metally Evrazii, 2015, no. 1, pp. 36–39.
    2. Kablov E.N. Science as a Branch of the Economy. Nauka i zhizn, 2009, no. 10, pp. 6–10.
    3. Kablov E.N. New generation materials – the Basis for innovation, technological leadership, and national security of Russia. Intellekt i tekhnologii, 2016, no. 2 (14), pp. 16–21.
    4. Raskutin A.E. Development strategy of polymer composite materials. Aviacionnye materialy i tehnologii, 2017, no. S, pp. 344–348. DOI: 10.18577/2071-9140-2017-0-S-344-348.
    5. Mishkin S.I. Application of carbon fiber plastics in constructions of pilotless devices (review). Trudy VIAM, 2022, no. 5 (111), pp. 87–95. Available at: http://www.viam-works.ru (accessed: March 04, 2025). DOI: 10.18577/2307-6046-2022-0-5-87-95.
    6. Kablov E.N. New generation materials. Zashchita i bezopasnost, 2014, no. 4, pp. 28–29.
    7. Zhelezina G.F., Matveeva N.N. Structural organoplastics. Vse materialy. Entsiklopedicheskiy spravochnik, 2007, no. 1, pp.11–12.
    8. Zhelezina G.F., Kulagina G.S., Kan A.Ch., Startsev V.O. Resistance of aramid organic plastics to the effects of natural environment factors. Trudy VIAM, 2024, no. 5 (135), pp. 13–24. Available at: http://www.viam-works.ru (accessed: April 04, 2025). DOI: 10.18577/2307-6046-2024-0-5-13-24.
    9. Kulagina G.S., Zhelezina G.F., Shuldeshova P.M., Kurshev E.V. Structure and physical-mechanical properties of a new generation organoplastic based on Rusar-NT brand aramid fiber fabric and melt binder. Trudy VIAM, 2022, no. 10 (116), pp. 55–65. Available at: http://www.viam-works.ru (accessed: April 08, 2025). DOI: 10.18577/2307-6046-2022-0-10-55-65.
    10. Zhelezina G.F., Gulyaev I.N., Soloveva N.A. Aramide organic plastics of new generation for aviation designs. Aviacionnye materialy i tehnologii, 2017, no. S, pp. 368–378. DOI: 10.18577/2071-9140-2017-0-S-368-378.
    11. Kablov E.N., Shchetanov B.V., Bolshakova A.N., Efimochkin I.Yu., Shcherbakov E.M. Niobium reinforced by α-Al2O3 fibers. Part 1. Two-Component Compositions. Aviation materials and technologies, 2021, no. 3 (64), pp. 58–77. Available at: http://www.journal.viam.ru (accessed: April 09, 2025). DOI: 10.18577/2307-6046-2021-0-3-58-67.
    12. Salakhova R.K., Veshkin E.A., Sudin Yu.I., Tikhoobrazov A.B. Research of the properties of epoxy compositions modified with polyarylsulphone and polymer composite materials based on them. Trudy VIAM, 2023, no. 12 (130), pp. 53–62. Available at: http://www.viam-works.ru (accessed: March 31, 2025). DOI: 10.18577/2307-6046-2023-0-12-53-62.
    13. Salakhova R.K. Chrome Plating in an Electrolyte Containing Trivalent Chromium Salts and Nanopowders as an Alternative to Chrome Plating from Standard Electrolytes. Izvestiya Samarskogo nauchnogo tsentra Rossiyskoy akademii nauk, 2008, vol. 1, special issue: A Quarter Century of Research and Experiments on the Creation of Unique Technologies and Materials for Aircraft Construction at the UNTC of the VIAM, pp. 77–82.
    14. Sidnyaev N.I. Experimental Planning Theory and Statistical Data Analysis: Textbook and Workshop for Universities. Moscow: Yurait, 2022, 495 p.
    15. Belokopytov V.I. Organization, Planning, and Processing of Experimental Results. Krasnoyarsk: SFU, 2020, 132 p.
    16. Kublanov M.S. Verification of the adequacy of mathematical models. Nauchniy vestnik MGTU GA, 2015, no. 211, pp. 29–36.

Full version (rus)
11.

DOI: 10.18577/2713-0193-2026-0-2-132-144

UDC: 666.3

Pages:: 132-144

D.I. Vershinin1, V.V. Kholodova1, K.O. Loginov1

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

THE INFLUENCE OF THE INTRODUCTION OF A SINTERING ADDITIVE OF THE CaO‒ZnO‒Al2O3‒SiO2 SYSTEM ON THE SINTERING PROCESS, MICROSTRUCTURE, PHYSICAL AND MECHANICAL PROPERTIES OF CERAMICS BASED ON α-Al2O3

The article studies the effect of the introduction of a sintering additive of the CaO–ZnO–Al2O3–SiO2 system on the sintering process, microstructure and mechanical properties of ceramics based on α-Al2O3. It was found that the introduction of an additive in the amount of 3–5 wt. % intensifies the sintering process by a liquid-phase mechanism. In order to obtain dense ceramics, it is possible to reduce the firing temperature to 1500 °C. The achieved level of properties meets the requirements for the bushing materials that are promising for use in gas turbine engines of aviation equipment. 

Keywords: corundum ceramics, α-Al2O3, CaO–ZnO–Al2O3–SiO2, liquid-phase sintering, bushings

Reference List

    1. Lukin E.S., Makarov N.A., Kozlov A.I. et al. Modern oxide ceramics and their applications. Konstruktsii iz kompozitsionnykh materialov, 2007, no. 1, pp. 3–13.
    2. Lukin E.S., Andrianov N.T., Mamaeva N.B. et al. On the problems of producing oxide ceramics with controlled structure. Ogneupory, 1993, no. 5, pp. 11–15.
    3. Kablov E.N. The strategic directions of development of materials and technologies of their processing for the period to 2030. Aviacionnye materialy i tehnologii, 2012, no. S, pp. 7–17.
    4. Antonov D.A., Pavlov S.S., Makarov N.A. Wear-resistant ceramics based on aluminum oxide with a modifying additive of eutectic composition. Uspekhi v khimii i khimicheskoy tekhnologii, 2018, vol. 32, no. 2 (198), pp. 13–15.
    5. Varrik N.M., Ivahnenko Yu.A., Maksimov V.G. Oxide-oxide composites for gas-turbine engines (review). Trudy VIAM, 2014, no. 8, pp. 17–25. Available at: http://www.viam-works.ru (accessed: July 17, 2025). DOI: 10.18577/2307-6046-2014-0-8-17-25.
    6. Evteev A.A. Some aspects of development of optimal firing conditions for ceramic compositions containing eutectic additives. Trudy VIAM, 2016, no. 2 (38), pp. 101–106. Available at: http://www.viam-works.ru (accessed: July 17, 2025). DOI: 10.18577/2307-6046-2016-0-2-12-12.
    7. Matrenin S.V., Ilyin A.P., Kulyavtseva S.V. Low-temperature sintering of corundum powders. Izvestiya Tomskogo politekhnicheskogo universiteta. Inzhiniring georesursov, 2018, vol. 329, no. 2, pp. 127–135.
    8. Dyatlova Ya.G., Kovelenov N.Yu., Rumyantsev V.I., Ordanyan S.S. New cutting ceramics in the Al2O3‒ZrO2(Y2O3)‒Ti(C, N) system. Novye materialy i tekhnologii proizvodstva, 2014, no. 1 (79), pp. 32–36.
    9. Popov R.Yu., Panteleenko F.I., Shimanskaya A.N. et al. The influence of mineralizing additives on the processes occurring during the synthesis of corundum ceramics. Trudy BGTU. Ser. 2: Khimicheskiye tekhnologii, biotekhnologii, geoekologiya, 2021, no. 2 (247), pp. 72–79.
    10. Golubeva I.E., Sitbikob A.I., Gordienko A.N. Study of forming technologies in manufacturing parts from electrovacuum ceramic VK 94-1. Inorganic materials: applied research, 2025, vol. 16, no. 4, pp. 1203–1207.
    11. Kharitonov D.V., Anashkina A.A., Kulikova G.I. et al. High-purity corundum grinding balls obtained by quasi-isostatic pressing. Novye ogneupory, 2023, no. 9, pp. 47–51.
    12. Voronov V.A., Chainikova A.S., Lebedeva Yu.E., Tkalenko D.M. Influence of morphology, phase composition and content of aluminum oxide particles on rheological properties of aqueous suspensions based on them. Aviation materials and technologies, 2021, no. 4 (65), pp. 14–25. Available at: http://www.journal.viam.ru (accessed: July 17, 2025). DOI: 10.18577/2713-0193-2021-0-4-14-25.
    13. Khrustalev A.N., Smirnov A.V., Arbanas L.A., Bazarova V.E., Simonov-Emelyanov I.D. Dielectric properties of polymer composite materials with ceramic fillers for microwave devices and equipment. Aviation materials and technologies, 2024, no. 4 (77), pp. 95–116. Available at: http://www.journal.viam.ru (accessed: July 17, 2025). DOI: 10.18577/2713-0193-2024-0-4-95-116.
    14. Sudzhanskaya I.V., Lebedeva Yu.E., Vaganova M.L., Shchegoleva N.E. Effect of co-doped of CeO2, Y2O3 on microstructure and mechanical properties of ceramic spinel MgAl2O4. Aviation materials and technologies, 2025, no. 2 (79), pp. 91–102. Available at: http://www.journal.viam.ru (accessed: July 17, 2025). DOI: 10.18577/2713-0193-2025-0-2-91-102.
    15. Lebedeva Yu.E., Shchegoleva N.E., Voronov V.A., Solntcev S.S. Al2O3 and ZrO2 ceramic materials obtained by sol-gel method. Trudy VIAM, 2021, no. 4 (98), pp. 61–73. Available at: http://www.viam-works.ru (accessed: July 17, 2025). DOI: 10.18577/2307-6046-2021-0-4-61-73.
    16. Evteev A.A., Lemeshev D.O., Zhitnyuk S.V., Makarov N.A. Ceramics in the ZrO2‒Al2O3 system with additives of eutectic compositions. Steklo i keramika, 2011, no. 8, pp. 23–27.
    17. Moe A.Ch., Popova N.A., Lukin E.S. Physicomechanical properties of corundum composite ceramics with the addition of ZrO2 and Al2O3‒MnO‒TiO2. Uspekhi v khimii i khimicheskoy tekhnologii, 2018, vol. 32, no. 2, pp. 28–30.
    18. Ahmad I., Unwin M., Cao H. et al. Multi-walled carbon nanotubes reinforced Al2O3 nanocomposites: Mechanical properties and interfacial investigations. Composites Science and Technology, 2010, no. 70, pp. 1199–1206.
    19. Zhang T., Kumari L., Du G.H. et al. Mechanical properties of carbon nanotube–alumina nanocomposites synthesized by chemical vapor deposition and spark plasma sintering. Composites, Part A. 2009, no. 40, pp. 86–93.
    20. Shchetanov B.V., Balinova Yu.A., Lyulyukina G.Yu., Soloveva E.P. Structure and properties of continuous polycrystalline fibers α-Al2O3. Aviacionnye materialy i tehnologii, 2012, no. 1, pp. 13–17.
    21. Grashchenkov D.V., Balinova Yu.A., Tinyakova E.V. Aluminum Oxide Ceramic Fibers and Materials Based on them. Glass and Ceramics, 2012, vol. 69, no. 3–4, pp. 130–133.
    22. Lukin E.S. On the influence of synthesis methods and powder preparation conditions in the technology of high-density and transparent ceramics. Trudy instituta MKhTI im. D.I. Mendeleyeva, 1987, is. 146, pp. 5–18.
    23. Lukin E.S., Makarov N.A., Popova N.A. et al. New types of corundum ceramics with additives of eutectic compositions. Konstruktsii iz kompozitsionnykh materialov, 2001, no. 3, pp. 28–37.
    24. Lukin E.S. Modern high-density oxide ceramics with controlled microstructure. Part II. Justification of the principles of selecting additives influencing the degree of sintering of oxide ceramics (continued). Ogneupory i tekhnicheskaya keramika, 1996, no. 5, pp. 2–9.
    25. Svancarek P.A., Galusek D., Calvert C. et al. Comparison of the Microstructure and Mechanical Properties of Two Liquid Phase Sintered Aluminas Containing Different Molar Ratios of Calcia – Silica Sintering Additives. Journal of European Ceramic Society, 2004, vol. 24, no. 12, pp. 3453–3463.
    26. Weimin D., Himanshu J., Harmer M.P. Liquid Sintering of Alumina. Part II. Penetration of Liquid Phase into Model Microstructures. Journal of American Ceramic Society, 2005, vol. 88, no. 7, pp. 1708–1713.
    27. Brydson R., Twigg P.C., Loughran F., Riley F.L. Influence of CaO – SiO2 Ratio on the Chemistry of Intergranular Films in Liquid – Phase Sintering Alumina and Implications for Rate of Erosive Wear. Journal of Materials Research, 2001, vol. 16, no. 3, pp. 652–665.
    28. Shevchenko V.Ya., Barinov S.M. Technical ceramics. Moscow: Nauka, 1993, 187 p.

Full version (rus)
12.

DOI: 10.18577/2713-0193-2026-0-2-145-159

UDC: 666.3:621.822

Pages:: 145-159

N.E. Shchegoleva1, S.A. Evdokimov1, D.I. Vershinin1, V.V. Kholodova1, M.L. Vaganova1, A.S. Chaynikova1

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

SILICON NITRIDE BASED CERAMICS AS A PROMISING MATERIAL FOR HYBRID BEARINGS

This article presents the results of a literature review on the development and application of silicon nitride ceramics. The advantages of silicon nitride ceramics for use in friction assemblies in hybrid bearings compared to metals are demonstrated. Test results, including bench tests, of silicon nitride ceramic balls in hybrid bearings are presented. Methods for molding and machining ceramic balls for hybrid rolling bearings are discussed.

Keywords: ceramics, silicon nitride, rolling bearings, pressing, non-destructive testing, hybrid bearings

Reference List

    1. Kablov E.N. 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, no. 1 (34), pp. 3–33. DOI: 10.18577/2071-9140-2015-0-1-3-33.
    2. Kablov E.N., Karachevtsev F.N., Shilov A.L. et al. Thermodynamics and vaporization of ceramics based on the Gd2O3–ZrO2 and Gd2O3–HfO2 systems studied by kems. Journal of Alloys and Compounds, 2022, vol. 908, p. 164575.
    3. Voronov V.A., Chainikova A.S., Lebedeva Yu.E., Zhitnyuk S.V. Production, physico-mechanical and tribotechnical properties of hot-pressed carbon-ceramic composite material on the basis of silicon carbide. Aviation materials and technologies, 2022, no. 2 (67), pp. 74–84. Available at: http://www.journal.viam.ru (accessed: October 23, 2025). DOI: 10.18577/2713-0193-2022-0-2-74-84.
    4. Lebedeva Yu.E., Chainikova A.S., Shchegoleva N.E., Belyachenkov I.O., Turchenko M.V. Synthesis and study of the properties of yttrium oxide sols. Trudy VIAM, 2023, no. 2 (120), pp. 32–41. Available at: http://www.viam-works.ru (accessed: October 23, 2025). DOI: 10.18577/2307-6046-2023-0-2-32-41.
    5. Lebedeva Yu.E., Shchegoleva N.E., Voronov V.A., Solntcev S.S. Al2O3 and ZrO2 ceramic materials obtained by sol-gel method. Trudy VIAM, 2021, no. 4 (98), pp. 61–73. Available at: http://www.viam-works.ru (accessed: October 23, 2025). DOI: 10.18577/2307-6046-2021-0-4-61-73.
    6. Garshin A.P., Nilov A.S., Galinskaya O.O., Krasnov V.I. Prospects for development and ways to improve aircraft braking systems on the base ceramic matrix composite materials (review). Aviation materials and technologies, 2023, no. 2 (71), pp. 104–121. Available at: http://www.journal.viam.ru (accessed: October 23, 2025). DOI: 10.18577/2713-0193-2023-0-2-104-121.
    7. Gricenko V.A. Electronic Structure of Silicon Nitride. Physics – Uspekhi, 2012, no. 55, pp. 498–507.
    8. Semenov A.A., Lizunov A.V., Glebov A.V., Makarov F.V., Karpyuk L.A. Prospects for the use of silicon nitride modified with highly enriched nitrogen-15 isotope in the manufacture of fuel rod claddings. Analiticheskie metody i pribory, 2021, vol. 11, no. 3, pp. 208–217.
    9. Brosler P., Silva R.F., Tedim J., Oliveira F.J. Electroconductive silicon nitride-titanium nitride ceramic substrates for CVD diamond electrode deposition. Ceramics International, 2023, vol. 49, pp. 36436–36445.
    10. Sitnikov S.A. Development of materials resistant to an ionic erosion on the basis of silicon nitride for digit chambers electrorocket engines: thesis, Cand. Sc. (Tech.). Мoscow, 2017, 151 р.
    11. Pakhomova S.A., Povalyaev A.I., Shebeshev K.I. Ceramic composite materials based on silicon nitride for corrosion-resistant rolling bearings. Collection of materials of the Int. Conf. on Composites «Key trends in composites: science and technology». Moscow, 2019, pp. 556–561.
    12. Kulichkov S.V. Application of ceramic materials to improve the reliability of friction units of process equipment. Abstract of the Third Int. Sci. and Tech. Conf. «Technical operation of water transport: problems and ways of development». Petropavlovsk-Kamchatsky, 2021, pp. 93–95.
    13. Pedroso M.P.G., Purquerio B.M., Fortulan C.A. Manufacturing of Green Ceramic Balls: Machine and Process. Materials Science Forum, 2017, vol. 881, pp. 200–205.
    14. Mathias H. Ceramic Bearings and Seals. Handbook of Advanced Ceramics, 2nd ed. Elsevier, 2013, pp. 301–328.
    15. Komeyaa K., Tatami J. Seeds Innovation and Bearing Applications of Silicon Nitride Ceramics. Key Engineering Materials, 2007, vol. 352, pp. 147–152.
    16. Grinkevych K., Zgalat-Lozynskyi O., Konih-Ettel N. et al. A preliminary study on the tribological compliance of ball and race materials for application in unlubricated hybrid bearings. Tribology International, 2025, vol. 212, pp. 110913–110923.
    17. O’Brien M.J., Presser N., Robinson E.Y. Failure analysis of three Si3N4 balls used in hybrid bearings. Engineering Failure Analysis, 2003, vol. 10, pp. 453–473.
    18. Thoma K., Rohr L., Rehmann H. et al. Materials failure mechanisms of hybrid ball bearings with silicon nitride balls. Tribology International, 2004, vol. 37, pp. 463–471.
    19. Wang L., Snidle R.W., Gu L. Rolling contact silicon nitride bearing technology: a review of recent research. Wear, 2000, no. 246, pp. 159–173.
    20. Huang L., Yuan J., Li C. et al. Influence of annealing temperature on thermal stabilities of hydrogenated amorphous carbon on silicon nitride balls. Vaccum, 2016, vol. 127, рр. 96–116.
    21. Nozhnitskiy Yu.A., Petrov N.I., Lavrentyev Yu.L. Hybrid rolling bearings for aircraft engines (review). Aviatsionnye dvigateli, 2019, vol. 3, pp. 63–76.
    22. Timokhova M.I. Method of quasi-isostatic pressing of ceramic and refractory products. Novye ogneupory, 2018, no. 11, pp. 18–22.
    23. Timokhova M.I. Some features of the method of quasi-isostatic pressing of ceramic and refractory products. Novye ogneupory, 2019, no. 3, pp. 17–20.
    24. Kuznetsov P.A., Kuznetsov R.V., Lepetan K.V. Press molds and equipment for elastostatic pressing of powder products. Abstract of the 12th Int. Sci. Conf. «Modern Mechanical Engineering. Science and Education». St. Petersburg, 2023, pp. 451–463.
    25. Method for manufacturing ceramic blanks based on silicon nitride: pat. 2803087 Rus Federation; appl. 29.11.22; publ. 06.09.23.
    26. Gal C.W., Song G.W., Baek W.H. et al. Fabrication of pressureless sintered Si3N4 ceramic balls by powder injection molding. Ceramics International, 2019, no. 45 (5), pp. 6418–6424.
    27. Umeharab N., Kirtanea T., Gerlicka R. et al. A new apparatus for finishing large size/large batch silicon nitride (Si3N4) balls for hybrid bearing applications by magnetic float polishing (MFP). International Journal of Machine Tools & Manufacture, 2006, vol. 46, pp. 151–169.
    28. Xu W., Cui D., Wu Y. Sphere forming mechanisms in vibration-assisted ball centreless grinding. International Journal of Machine Tools and Manufacture, 2016, no. 108, pp. 83–94.
    29. Deneuville F., Duquennoy M., Ouaftouh M. et al. High frequency ultrasonic detection of C-crack defects in silicon nitride bearing balls. Ultrasonics, 2009, vol. 49, pp. 89–93.

Full version (rus)
13.

DOI: 10.18577/2713-0193-2026-0-2-160-170

UDC: 621.9.06

Pages:: 160-170

Yu.G. Yushkov1, A.A. Andronov1, I.Yu. Bakeev1, D.B. Zolotukhin1, A.A. Zenin1, E.M. Oks1, A.V. Tyunkov1

[1] Federal State Autonomous Educationfl Institution of Higher Education – Tomsk State University of Control Systems and Radioelectronics

PILOT TECHNOLOGICAL INSTALLATION OF ELECTRON BEAM SPRAYING OF HEAT-SHIELDING CERAMIC COATINGS ON TURBINE BLADES

A description of a pilot technological installation for the electron beam spraying of heat-protective coatings on the blades of a hot path of gas turbine engines is presented. The installation is equipped with pre-vacuum plasma electron sources operating in the high-pressure region. The use of electron sources of this type ensures a high rate of deposition of coatings while significantly reducing the energy consumption of the technological process.

Keywords: heat-protective coatings, pre-vacuum plasma electron sources, technological installation, electron beam, electron beam spraying

Reference List

    1. Heydari P. A review on functionally graded-thermal barrier coatings (FG-TBC) fabrication methods in gas turbines. American Journal of Mechanical and Materials Engineering, 2022, vol. 6, no. 2, pp. 18–26. DOI: 10.11648/j.ajmme.20220602.12.
    2. Budinovsky S.A., Muboyadzhyan S.A., Gaymov A.M. et al. Current status and main development trends of high-temperature heat-protective coatings for working blades of aircraft gas turbine engines. Aviatsionnaya promyshlennost, 2008, no. 4, pp. 33–37.
    3. Lokachari S., Leng K., Rincon Romero A. et al. Processing–microstructure–properties of columns in thermal barrier coatings: a study of thermo-chemico-mechanical durability. ACS Applied Materials & Interfaces, 2024, vol. 16, no. 8, pp. 10646–10660.
    4. Krämer S., Yang J., Levi C.G. et al. Thermochemical interaction of thermal barrier coatings with molten CaO–MgO–Al2O3–SiO2 (CMAS) deposits. Journal of the American Ceramic Society, 2006, vol. 89, no. 10, pp. 3167–3175.
    5. Krämer S., Yang J., Levi C.G. Infiltration-inhibiting reaction of gadolinium zirconate thermal barrier coatings with CMAS melts. Journal of the American Ceramic Society, 2008, vol. 91, no. 2, pp. 576–583.
    6. Lee K.S., Lee D.H., Kim T.W. Microstructure controls in Gadolinium Zirconate/YSZ double layers and their properties. Journal of the Ceramic Society of Japan, 2014, vol. 122, no. 1428, pp. 668–673. DOI: 10.2109/jcersj2.122.668.
    7. Tambovtsev A.S., Tyryshkin P.A., Kuzmin V.I. et al. Application of protective coatings for the fuel and energy complex by plasma spraying. Vestnik Permskogo natsionalnogo issledovatelskogo politekhnicheskogo universiteta, 2022, no. 71, pp. 156–166.
    8. Choy K.L. Chemical vapour deposition of coatings. Progress in materials science, 2003, vol. 48, no. 2, pp. 57–170. DOI: 10.1016/S0079-6425(01)00009-3.
    9. Lin J., Thomas C.S. Development of thermal barrier coatings using reactive pulsed DC magnetron sputtering for thermal protection of titanium alloys. Surface and Coatings Technology, 2020, vol. 403, pp. 126377. DOI: 10.1016/j.surfcoat.2020.126377.
    10. Muboyadzhyan S.A., Budinovskij S.A., Gayamov A.M., Matveev P.V. High-temperature heat resisting coverings and heat resisting layers for heat-protective coverings, Aviacionnye materialy i tehnologii, 2013, no. 1, pp. 17–20.
    11. Schulz U., Schmücker M. Microstructure of ZrO2 thermal barrier coatings applied by EB-PVD. Materials Science and Engineering, 2000, vol. A, is. 276, no. 1–2, pp. 1–8. DOI: 10.1016/S0921-5093(99)00576-6.
    12. Klimov A.S., Medovnik A.V., Yushkov Yu.G. et al. Application of forevacuum plasma electron sources for processing dielectrics. Tomsk: Tomsk State Univ. of Control Systems and Radioelectronics, 2017, 188 p.
    13. Yushkov Yu.G., Oks E.M., Tyunkov A.V. et al. Electron-beam synthesis of dielectric coatings using forevacuum plasma electron source. Coatings, 2022, vol. 12, no. 1, p. 82. DOI: 10.3390/COATINGS12010082.
    14. See Hiden Analytical website for additional information on Langmuir Probe. Available at: https://www.hidenanalytical.com/products/thin-films-plasma-and-surface-e... (accessed: May 05, 2025).
    15. Tyunkov A.V., Oks E.M., Yushkov Y.G. et al. Ion composition of the beam plasma generated by electron-beam evaporation of metals and ceramic in the forevacuum range of pressure. Catalysts, 2022, vol. 12, no. 5, p. 574. DOI: 10.3390/catal12050574.

Full version (rus)
14.

DOI: 10.18577/2713-0193-2026-0-2-171-182

UDC: 620.178.6

Pages:: 171-182

A.D. Monakhov1, N.O. Yakovlev1

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

STUDY OF CRACK RESISTANCE CHARACTERISTICS OF ALUMINUM ALLOY USING MULTIPARAMETRIC CRITERIA OF FRACTURE MECHANICS

The paper presents the determination of cyclic crack resistance characteristics on an aluminum alloy specimen. Using the digital image correlation method and Williams’ expansion functions, the stress intensity factors KI, KII and T-stress were determined during fatigue crack growth rate tests. The obtained T-stress distributions demonstrate changes in the specimen’s stress state as the fatigue crack grows. The effective stress intensity factor was calculated based on the maximum tangential stress criterion. The results showed that accounting for T-stresses leads to a slight increase in the fracture toughness characteristic for an eccentrically loaded specimen made of an Al–Zn–Cu–Mg system aluminum alloy.

Keywords: cyclic crack resistance, stress intensity factor, T-stress, digital image correlation

Reference List

    1. Kablov E.N., Ospennikova O.G., Kudinov I.I. et al. Assessment of the probability of detecting operational defects in aircraft parts made of heat-resistant alloys using flaw detection fluids of domestic and foreign production. Defektoskopiya, 2021, no. 1, pp. 64–71. DOI: 10.31857/S0130308221010073.
    2. Kablov E.N. Quality control of materials ‒ a guarantee of safety of operation of aviation equipment. Aviatsionnye materialy i tekhnologii, 2001, no. 1, pp. 3–8.
    3. Erasov V.S., Oreshko E.I. Fatigue tests of metal materials (review). Part 1. Main definitions, loading parameters, representation of results of tests. Aviacionnye materialy i tehnologii, 2020, no. 4 (61), pp. 59–70. DOI: 10.18577/2071-9140-2020-0-4-59-70.
    4. Medvedev P.N., Gulyaev A.I. Analysis of the spatial distribution of cracks in a heat-resistant nickel alloy manufactured using SLM technology. Aviacionnye materialy i tehnologii, 2020, no. 1 (58), pp. 12–18. DOI: 10.18577/2071-9140-2020-0-1-12-18.
    5. Panin V.E., Kablov E.N., Pochivalov Yu.I. et al. Effect of nanostructuring of the surface layer of aluminum-lithium alloy 1424 on deformation mechanisms, technological characteristics and fatigue life. Improving plasticity and technological characteristics. Fizicheskaya mezomekhanika, 2012, vol. 15, no. 6, pp. 107–111.
    6. Gorbovets M.A., Khodinev I.A., Monin S.A. Tests of structural metallic materials for the fatigue crack growth rate in a corrosive environment (review). Trudy VIAM, 2022, no. 12 (118), pp. 135–144. Available at: http://www.viam-works.ru (accessed: December 18, 2024). DOI: 10.18577/2307-6046-2022-0-12-135-144.
    7. Kablov E.N., Chainikova A.S., Schegoleva N.E. et al. Synthesis, structure and properties of aluminosilicate glass ceramics modified with zirconium oxide. Neorganicheskiye materialy, 2020, vol. 56, no. 10, pp. 1123–1129. DOI: 10.31857/S0002337X20100061.
    8. Monakhov A.D., Yakovlev N.O. Application of the deep learning method in studying crack resistance characteristics. Trudy VIAM, 2024, no. 6 (136), pp. 80‒91. Available at: http://www.viam-works.ru (accessed: December 18, 2024). DOI: 10.18577/2307-6046-2024-0-6-80-91.
    9. Glagolev V.V., Glagolev L.V., Lutkhov A.I. On finding the j-integral for a crack-like defect of a solid in the form of a physical cut in the finite element representation. Matematicheskoe modelirovanie v estestvennykh naukakh, 2024, vol. 1, pp. 107–110.
    10. Knäsl Z., Bednar K., Radon J. Influence of T-stresses on the velocity of fatigue crack propagation. Fizicheskaya mekhanika, 2000, vol. 3, no. 5. pp. 5–9.
    11. Pokrovsky A.M., Matvienko Yu.G., Egranov M.P. Predicting the survivability of a plate with a through crack taking into account biaxial constraint of deformations along its front. Zavodskaya laboratoriya. Diagnostika materialov, 2023, vol. 89, no. 9, pp. 53–63. DOI: 10.26896/1028-6861-2023-89-9-53-63.
    12. Matvienko Yu.G. Two-parameter fracture mechanics in modern strength problems. Problemy mashinostroyeniya i nadezhnosti mashin, 2013, no. 5, pp. 37–46.
    13. Matvienko Yu.G. Two-parameter elastic-plastic fracture criterion and corrected fracture toughness. Zavodskaya laboratoriya. Diagnostika materialov, 2022, vol. 88, no. 8, pp. 59–69. DOI: 10.26896/1028-6861-2022-88-8-59-69.
    14. Usov S.M., Razumovsky I.A., Odintsev I.N. Study of residual stress fields using indicator cracks and the method of electronic speckle interferometry. Zavodskaya laboratoriya. Diagnostika materialov, 2021, vol. 87, no. 9, pp. 50–58. DOI: 10.26896/1028-6861-2021-87-9-50-58.
    15. Williams M.L. On the Stress Distribution at the Base of a Stationary Crack. Journal of Applied Mechanics, 1957, vol. 24 (1), pp. 109–114.
    16. Malíková L., Veselý V. Williams expansion terms and their importance for accurate stress field description in specimens with a crack. Transactions of the VŠB – Technical University of Ostrava Mechanical Series, 2013, no. 59 (2), pp. 109–114. DOI: 10.22223/tr.2013-2/1963.
    17. Stepanova L.V., Belova O.N., Turkova V.A. Determination of the coefficients of M. Williams expansion of the stress field at the crack tip using the digital photoelasticity method and the finite element method. Vestnik Samarskogo Universiteta. Estestvennonauchnaya seriya, 2019, vol. 25, no. 3, pp. 62–82. DOI: 10.18287/2541-7525-2019-25-3-62-82.
    18. Yates J.R., Zanganeh M., Tai Y.H. Quantifying crack tip displacement fields with DIC. Engineering Fracture Mechanics, 2010, vol. 77 (11), рр. 2063–2076. DOI: 10.1016/j.engfracmech.2010.03.025.
    19. Pokrovsky A.M., Egranov M.P. Two-parameter failure criterion for a normal tensile crack. Inzhenernyy zhurnal: nauka i innovatsii, 2022, no. 7 (127). Available at: http:// engjournal.bmstu.ru (accessed: December 18, 2024). DOI: 10.18698/2308-6033-2022-7-2191.
    20. Sutton M.A., Orteu J., Schreier H.W. Image correlation for shape, motion and deformation measurements: basic concepts, theory and applications. Springer, 2009, 321 p.
    21. Kobayashi A. Experimental mechanics: in 2 vols. Moscow: Mir, 1990, vol. 2, 551 p.
    22. Leevers P.S., Radon J.C. Inherent stress biaxiality in various fracture specimen geometries. International Journal of Fracture, 1983, vol. 19, pp. 311–325.
    23. Ayatollahi M.R., Moghaddam M.R., Berto F. T-stress effects on fatigue crack growth – Theory and experiment. Engineering Fracture Mechanics, 2018, vol. 187, pp. 103–114.

Full version (rus)
15.

DOI: 10.18577/2713-0193-2026-0-2-183-193

UDC: 620.179.111.3

Pages:: 183-193

D.S. Skorobogatko1, A.N. Golovkov1, I.I. Kudinov1, S.I. Kulichkova1

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

COMPARISON OF THE EFFICIENCY OF THE KITS OF DEFECTOSCOPIC MATERIALS LUM1-OV AND LUM33-OV IN DETECTING LOW-CYCLE FATIGUE CRACKS

The work was carried out to compare the detection ability of luminescent sets of flaw detection materials of domestic production LUM1-OV and LUM33-OV in combination with liquid types of developers, capable of detecting surface defects, with an opening width of less than a micron. For a quantitative assessment of the detection ability of the studied sets, a statistical probabilistic approach was used. Samples were made of heat-resistant nickel alloy with artificially grown low-cycle fatigue (LCF) cracks. It was found that the LUM1-OV set detects LCF cracks more effectively than the LUM33-OV set.

Keywords: non-destructive testing, penetrant testing, quality of defectoscopic materials, penetrant testing technology, detection ability

Reference List

    1. Kablov E.N. 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, no. 1 (34), pp. 3–33. DOI: 10.18577/2071-9140-2015-0-1-3-33.
    2. Kablov E.N. The Role of Chemistry in the Creation of Next-Generation Materials for Complex Technical Systems. Reports of the XX Mendeleev Congress on General and Applied Chemistry. Ekaterinburg: Ural Branch of the RAS, 2016, pp. 25–26.
    3. Kablov E.N. Materials and Chemical Technologies for Aviation Equipment. Vestnik Rossiyskoy akademii nauk, 2012, vol. 82, no. 6, pp. 520–530.
    4. State Standard 18442‒80. Non-destructive Testing. Penetrant Methods. Moscow: Publ. House of Standards, 1987, 24 p.
    5. Filinov M.V., Prokhorenko P.P. Physical Principles and Means of Penetrant Defectoscopy. Moscow: Fizmatlit, 2008, 306 p.
    6. Skorobogatko D.S., Golovkov A.N., Kudinov I.I., Kulichkova S.I. Revisiting the ecotoxicity and efficiency of different classes of industrial nonionic surfaces used for cleaning metal surfaces in the process of capillary control of details of the aviation technology (review). Aviation materials and technologies, 2021, no. 4 (65), pp. 98–106. Available at: http://www.journal.viam.ru (accessed: April 17, 2025). DOI: 10.18577/2713-0193-2021-0-4-98-106.
    7. Glazkov Yu.A. Penetrant Testing. Moscow: Spektr, 2013, 144 p.
    8. Industry Standard 1 90282–79. Product Quality. Non-Destructive Testing. Penetrant Methods. Moscow: VIAM, 1979, 50 p.
    9. Industry Standard 1 90243–83. Penetrant Methods of Non-Destructive Testing. Marking. Moscow: VIAM, 1983, 39 p.
    10. Karyakin A.V., Borovikov A.S. Luminescent and Color Defectoscopy. Moscow: Mashinostroenie, 1972, 23 p.
    11. Migun N.P. Model of film flow in a dead-end conic capillary. Inzhenerno-fizicheskii zhurnal, 2002, vol. 75, is. 6, pp. 145–150.
    12. Migun N.P., Volovich I.V. Absorption of polar indicator liquids into dead-end microcracks. Izvestiya Natsionalnoy akademii nauk Belarusi. Seriya fiziko-tekhnicheskikh nauk, 2011, no. 2, pp. 116–122.
    13. Prokhorenko P.P., Migoun N.P., Grebenshchikov S.V. Experimental studies of polar indicator liquids used in capillary penetrant testing. International Journal of Engineering Science, 1987, vol. 25, no. 7, pp. 769–773.
    14. Glazkov Yu.A. Assessment of the quality of materials for capillary flaw detection by the visibility of indicator patterns of defects. Defektoskopiya, 2021, no. 1, pp. 17–29.
    15. Kulichkova S.I., Golovkov A.N., Kudinov I.I., Skorobogatko D.S. Evaluation of the effectiveness of various methods of applying powder developers during capillary control. Trudy VIAM, 2022, no. 10 (116), pp. 116–127. Available at: http://www.viam-works.ru (accessed: May 04, 2025). DOI: 10.18577/2307-6046-2022-0-10-116-127.
    16. Parker B.H. A Comparison of the Capability of Sensitivity Level 3 and Sensitivity Level 4 Fluorescent Penetrants to Detect Fatigue Cracks in Aluminum: Technical memorandum. Greenbelt, MD: NASA Goddard Space Flight Center, 2009, pp. 12–22.
    17. Kablov E.N., Ospennikova O.G., Kudinov I.I., Golovkov A.N., Generalov A.S., Knyazev A.V. Assessment of the probability of detecting operational defects in aircraft parts made of heat-resistant alloys using flaw detection fluids of domestic and foreign production. Defektoskopiya, 2021, no. 1, pp. 64–71. DOI: 10.31857/S0130308221010073.
    18. Simona K., Pulkkinen U. Models for non-destructive inspection data. Reliability Engineering & System Safety, 1998, vol. 60, is. 1, pp. 1–12.
    19. State Standard R 58989–2020. Aircraft gas turbine engines. Non-destructive testing of main components. General requirements. Мoscow: Standartinform, 2020, p. 10.
    20. Gorbovets M.A., Khodinev I.A., Monin S.A. Tests of structural metallic materials for the fatigue crack growth rate in a corrosive environment (review). Trudy VIAM, 2022, no. 12 (118), pp. 135–144. Available at: http://www.viam-works.ru (accessed: May 04, 2025). DOI: 10.18577/2307-6046-2022-0-12-135-144.
    21. Ryzhkov P.V., Gorbovets M.A., Hodinev I.A. Energy criteria for fatigue fracture of a heat-resistant nickel alloy. Trudy VIAM, 2023, no. 11 (129), pp. 111–122. Available at: http://www.viam-works.ru (accessed: May 04, 2025). DOI: 10.18577/2307-6046-2023-0-11-111-122.
    22. Inozemtsev A.A. Low-cycle fatigue and cyclic crack resistance of nickel alloy under loading typical for turbine disks. Tyazheloe mashinostroenie, 2011, no. 4, pp. 30–33.
    23. Skorobogatko D.S., Golovkov A.N., Kudinov I.I., Kulichkova S.I. Comparison of the basic physical parameters of penetrating liquids used in penetrant testing defectoscopy. Aviation materials and technologies, 2025, no. 2 (79), pp. 137–146. Available at: http://www.journal.viam.ru (accessed: May 04, 2025). DOI: 10.18577/2713-0193-2025-0-2-137-146.

Full version (rus)
16.

DOI: 10.18577/2713-0193-2026-0-2-194-208

UDC: 678.742.21:524.3-74

Pages:: 194-208

A.G. Argunova1, E.S. Petukhova1, A.L. Fedorov1

[1] Federal Research Centre «The Yakut Scientific Centre of the Siberian Branch of the Russian Academy of Sciences» Institute of Oil and Gas Problems of the Siberian Branch of the Russian Academy of Sciences

STUDY OF THE ULTRAVIOLET RADIATION INFLUENCE ON THE PROPERTIES OF LOW-DENSITY POLYETHYLENE CONTAINING STERICALLY HINDERED PHENOLIC STABILIZERS

The article presents the results of a study of the stabilized low-density polyethylene resistance to ultraviolet radiation. It has been established that stabilizers based on sterically hindered phenols reduce the intensity of radical chain reactions and the depth of ultraviolet radiation penetration into the material volume, and also allow preserving the rheological properties of low-density polyethylene.

Keywords: low-density polyethylene, stabilizer, accelerated climatic aging, physical and mechanical characteristics, infrared spectroscopic studies, melt flow index

Reference List

    1. Aleksandrov V.G., Vyrzhikovsky B.V., Meshcheryakov A.M., Yankovsky F.G. Handbook on current repairs of aviation equipment. Moscow: Voenizdat, 1975, 368 p.
    2. Polymers in aircraft construction. MPlast.by: inform. and analytical. portal. Availabe at: https://mplast.by/encyklopedia/polimeryi-v-aviastroenii (accessed: October 20, 2025).
    3. Balo F., Sua L.S. Green Composites in Aviation: Optimizing Natural Fiber and Polymer Selection for Sustainable Aircraft Cabin Materials. Textiles, 2024, vol. 4, pp. 561–581. DOI: 10.3390/textiles4040033.
    4. Encyclopedia of Polymers. Ed. V.A. Kargin. Moscow: Nauchny Mir, 1972, 1224 p.
    5. Chechin D.E., Petrachkov D.N., Shatalin V.A. et al. Manufacturing Technology of Complex-Profile Aviation Glazing Products with High Optical Characteristics Based on Monolithic Polycarbonate. Proceedings of the All-Rus. Sci. and Tech. Conf. «Functional and Polymer Materials for Aviation Glazing». Moscow: NRC «Kurchatov Institute» – VIAM, 2021, pp.105–113.
    6. Laurenzi S., de Zanet G., Santonicola M.G. Numerical investigation of radiation shielding properties of polyethylene-based nanocomposite materials in different space environments. Acta Astronautica, 2020, vol. 170, pp. 530–538. DOI: 10.1016/j.actaastro.2020.02.027.
    7. Petukhova E.S., Fedorov A.L., Argunova A.G. Study of the mechanisms of polyethylene degradation under prolonged exposure to natural climatic factors. Vysokomolekulyarnye soyedineniya. Ser. B, 2023, no. 5 (65), pp. 392–402. DOI: 10.31857/S2308113923700572.
    8. Petukhova E.S., Fedorov A.L., Argunova A.G. Study of the climatic resistance of polyethylene conductive materials for fuel canisters in the conditions of the North and Arctic. Materialovedenie, 2023, no. 2, pp. 12–17. DOI: 10.31044/1684-579X-2023-0-2-12-17.
    9. Petukhova E.S., Fedorov A.L. Investigation of the climate resistance of stabilized polyethylene composite materials. Procedia Structural Integrity. Part of special issue: 1st International Conference on Integrity and Lifetime in Extreme Environment (ILEE–2019), 2019, vol. 20, pp. 75–80. DOI: 10.1016/j.prostr.2019.12.118.
    10. Muravleva E.A. Assessment of the potential for using solar radiation energy in Russia. Vestnik agrarnoy nauki Dona, 2015, vol. 1 (29), pp. 38–44.
    11. Andrady A.L., Heikkilä A.M., Pandey K.K. et al. Effects of UV radiation on natural and synthetic materials. Photochemical & Photobiological Sciences, 2023, vol. 22, pp. 1177–1202. DOI: 10.1007/s43630-023-00377-6.
    12. Jiang T., Qi Ya., Wu Yu., Zhang J. Application of antioxidant and ultraviolet absorber into HDPE: Enhanced resistance to UV irradiation. e-Polymers, 2019, vol. 19 (1), pp. 499–510. DOI: 10.1515/epoly-2019-0053.
    13. Ivanov V.B., Solina E.V., Samoryadov A.V. Analysis of the stability of polymeric materials under extreme conditions by the colorimetry method. Rossiyskiy khimicheskiy zhurnal, 2020, no. 4 (LXIV), pp. 30–38. DOI: 10.6060/rcj.2020644.3.
    14. Wypych G. Handbook UV degradation and stabilization. Toronto: ChemTec Publishing, 2020, 465 p.
    15. Brostow W., Lu X., Gencel O., Osmanson A.T. Effects of UV Stabilizers on Polypropylene Outdoors. Materials, 2020, vol. 13, p. 1626. DOI: 10.3390/ma13071626.
    16. El-Hiti G.A., Ahmed D.S., Yousif E. et al. Modifications of Polymers through the Addition of Ultraviolet Absorbers to Reduce the Aging Effect of Accelerated and Natural Irradiation. Polymers, 2022, vol. 14, p. 20. DOI: 10.3390/polym14010020.
    17. Mohamed R.R. Photostabilization of Polymers. Polymers and Polymeric Composites: A Reference Series. Berlin: Springer, 2015, 10 p. DOI: 10.1007/978-3-642-37179-0_74-1.
    18. Mankar V.H., Chhavi. Sterically Hindered Phenols as Antioxidant. European Journal of Molecular & Clinical Medicine, 2020, vol. 7 (7), pp. 3481–3491.
    19. Kolchina G.Yu., Tukhvatullin R.F., Babayev E.R., Movsumzade E.M. Sterically hindered phenols as antioxidant, anticorrosive and antimicrobial additives to mineral lubricating oils. Neftegazokhimiya, 2017, no. 1, pp. 10–13.
    20. Benítez A., Sánchez J.J., Arnal M.L. et al. Abiotic degradation of LDPE and LLDPE formulated with a pro-oxidant additive. Polymer Degradation and Stability, 2013, vol. 98 (2), pp. 490–501. DOI: 10.1016/j.polymdegradstab.2012.12.011.
    21. Antunes M.C., Agnelli J.A.M., Babetto A.S. et al. Abiotic thermo-oxidative degradation of high density polyethylene: effect of manganese stearate concentration. Polymer Degradation and Stability, 2017, vol. 143, pp. 95–103. DOI: 10.1016/j.polymdegradstab.2017.06.012.
    22. Ali S.S., Qazi I.A., Arshad M. et al. Photocatalytic degradation of low density polyethylene (LDPE) films using titania nanotubes. Environmental Nanotechnology, Monitoring and Management, 2016, vol. 5, pp. 44–53. DOI: 10.1016/j.enmm.2016.01.001.
    23. Yeh C.L., Nikolić M.A.L., Gomes B. et al. The effect of common agrichemicals on the environmental stability of polyethylene films. Polymer Degradation and Stability, 2015, vol. 120, pp. 53–60. DOI: 10.1016/j.polymdegradstab.2015.06.007.
    24. Maalihan R.D., Pajarito B.B. Effect of colorant, thickness, and pro-oxidant loading on degradation of low-density polyethylene films during thermal aging. Journal of Plastic Film & Sheeting, 2016, vol. 32, pp. 124–139. DOI: 10.1177/8756087915590276.
    25. Elanmugilan M., Sreekumar P., Singha N. et al. Natural weather aging of low density polyethylene: effect of prodegradant additive. Plastic Rubber and Composites, 2014, vol. 43 (10), pp. 347–353. DOI: 10.1179/1743289814Y.0000000104.
    26. Gulmine J.V., Janissek P.R., Heise H.M., Akcelrud L. Degradation profile of polyethylene after artificial accelerated weathering. Polymer Degradation and Stability, 2003, vol. 79, pp. 385–397. DOI: 10.1016/S0141-3910(02)00338-5.
    27. Jakubowicz I., Enebro J. Effects of reprocessing of oxobiodegradable and non-degradable polyethylene on the durability of recycled materials. Polymer Degradation and Stability, 2012, vol. 97, pp. 316–321. DOI: 10.1016/j.polymdegradstab.2011.12.011.
    28. Roy P.K., Surekha P., Rajagopal C. et al. Effect of benzil and cobalt stearate on the aging of low-density polyethylene films. Polymer Degradation and Stability, 2005, vol. 90, pp. 577–585. DOI: 10.1016/j.polymdegradstab.2005.01.017.
    29. Jeffries W.L. Color and structure in organic compounds. Journal of the Elisha Mitchell Scientific Society, 1914, vol. 29 (3), pp. 81–88.
    30. Fedorov A.L., Petukhova E.S., Argunova A.G. Study of the influence of UV radiation on the structure of the stabilizer CO-4 by IR spectroscopy. Proc. All-Rus. conf. «Climate–2022: Modern Approaches to Assessing the Impact of External Factors on Materials and Complex Technical Systems». Moscow: NRC «Kurchatov Institute» – VIAM, 2022, pp. 109–118.
    31. Terakh E.I., Prosenko A.E., Nikulina V.V., Zaitseva O.V. Study of synergistic effects of the antioxidant CO-3 and its structural analogs in comparison with compositions of trialkylphenols and dialkyl sulfide. Zhurnal prikladnoy khimii, 2003, vol. 76 (2), pp. 261–265.
    32. Allen N., Edge M., Hussain S. Perspectives on Yellowing in the Degradation of Polymer Materials: Inter-relationship of Structure, Mechanisms and Modes of Stabilisation. Polymer Degradation and Stability, 2022, vol. 201, p. 109977. DOI: 10.1016/j.polymdegradstab.2022.109977.
    33. Gardette M., Perthue A., Gardette J.L. et al. Photo- and thermal-oxidation of polyethylene: Comparison of mechanisms and influence of unsaturation content. Polymer Degradation and Stability, 2013, vol. 98 (11), pp. 2383–2390. DOI: 10.1016/j.polymdegradstab.2013.07.017.
    34. Prasada Rao T., Biju V.M. Spectrophotometry. Organic Compounds. Encyclopedia of Analytical Science, 2nd ed. Elsevier, 2005, pp. 358–366.
    35. Myalenko D.M., Mikhailenko P.G. Study of the contact angle of a polyethylene film modified with organic and inorganic components. Mezhdunarodnyy nauchno-issledovatelskiy zhurnal, 2020, no. 12 (102), pp. 49–53. DOI: 10.23670/IRJ.2020.102.12.009.
    36. Kiselev M.G., Savich V.V., Pavich T.P. Determination of the contact angle on flat surfaces. Nauka i tekhnika, 2006, no. 1, pp. 38–41.
    37. Nakhaev M.I., Ananyev L.B., Ivanova N.S. et al. Ultraviolet irradiance, UV index and their forecasting. Trudy Gidrometeorologicheskogo nauchno-issledovatelskogo tsentra Rossiyskoy Federatsii, 2014, no. 351, pp. 173–187.
    38. Experimental forecast of the UV index. Hydrometeorological Center of Russia. Available at: https://meteoinfo.ru/categ-articles/117-forecast-cat/drugie-vidy-prognoz... (accessed: September 17, 2025).

Full version (rus)
17.

DOI: 10.18577/2713-0193-2026-0-2-209-219

UDC: 669.715:681.8

Pages:: 209-219

A.A. Igolkin1, P.A. Popov1, A.I. Safin1, М.V. Hardin1

[1] Samara National Research University

THE INVESTIGATION OF VIBROACOUSTIC PROPERTIES AND THE POSSIBILITY OF USING COMPOSITE MATERIAL OF SYSTEM «ALUMINUM–POLYMER–ALUMINUM» 

The problem basics of obtaining and using layered composite materials in various products and structures are considered. For the developed composite material of system «aluminum–polymer–aluminum», which has high formability and other technological properties, the coefficient of mechanical losses was chosen as a criterion for evaluating vibroacoustic properties. To determine this coefficient, methods have been proposed and three installations have been developed that operate efficiently in their frequency range. The conducted experiments show a significant superiority of the composite material vibroacoustic properties in comparison with the monomaterial and open up the possibility of using the new material in various products and structures.

Keywords: vibroacoustic properties, mechanical loss coefficient, layered composite material, formability, vibration response spectrum

Reference List

    1. Hayashi H., Nakagawa T. Recent trends in sheet metals and their formability in manufacturing automotive panels. Journal of Materials Processing Technology, 1994, vol. 46, pp. 455–487.
    2. Composite layered material and method for producing it: pat. 2565186 Rus. Federation; appl. 28.05.14; publ. 20.10.15.
    3. Senatorova O.G. High-strength, crack-resistant, lightweight laminated aluminum-glass plastics of the SIAL class – a promising material for aircraft structures. Tekhnologiya legkikh splavov, 2009, no. 2, pp. 28–31.
    4. Johnson W., Cobb T., Lowther S., St. Clair T. Hybrid titanium composite laminates: a new aerospace material: Report no. 20040105645. NASA Technical Reports Server (NTRS), 1998, pp. 1–3.
    5. Antipov V.V., Somov A.V., Sidelnikov V.V., Nefedova Yu.N., Ogurtsov P.S., Soloviev V.A. Technological features of shaping fire-resistant light laminated material for helicopter engine hood manufacturing. Aviation materials and technologies, 2023, no. 3 (72), pp. 90–100. Available at: http://www.journal.viam.ru (accessed: June 05, 2025). DOI: 10.18577/2713-0193-2023-0-3-90-100.
    6. Kiseleva T.Yu., Zholudev S.I., Ilinykh I.A., Novakova A.A. Anisotropic magnetostrictive metal-polymer composites for functional devices. Pisma v ZhTF, 2013, vol. 39, no. 24, pp. 71–80.
    7. Mohottia D., Ngo T., Raman S.N. et al. Plastic Deformation of Polyurea Coated Composite Aluminium plate Subjected to Low velocity Impact. Materials and Desing, 2014, vol. 56, pp. 696–713.
    8. Duyunova V.A., Kutyrev A.E., Serebrennikova N.Yu., Vdovin A.I., Somov A.V. Examination of the impact of aggressive environmental factors on the development of corrosion damage on samples of laminated glass-reinforced plastic of SIAL class. Aviation materials and technologies, 2021, no. 4 (65), pp. 81–90. Available at: http://www.journal.viam.ru (accessed: 05.06.2025). DOI: 10.18577/2713-0193-2021-0-4-81-90.
    9. Golovashchenko S. Sharp flanging and flat hemming of aluminum exterior body panels. Journal of materials engineering and performance, 2005, vol. 14, pp. 508–515.
    10. Colombo C., Carradó A., Palkowski H., Vergani L. Impact behaviour of 3-layered metal-polymer-metal sandwich panels. Composite Structures, 2015, vol. 133, pp. 140–147.
    11. Tekkaya A., Hahn M., Hiegemann L. et al. Umformen faserverstärkter thermoplastischer Kunststoff-Halbzeuge mit metallischen Deckblechen für den Leichtbau. EFB T40-Intermezzo der hybriden Werkstofflösungen: Hat Blech eine Zukunft. Hannover: EFB, 2015, pp. 185–199.
    12. Burchitz I., Boesenkool R., Zwaag S., Tassoul M. Highlight of designing with Hylite a new material concept. Materials and Design, 2005, vol. 26, pp. 271–279.
    13. Gower H. Welding of a metal-polymer laminate: Thesis, PhD. Netherlands: Delft University of Technology, 2007, 186 p.
    14. ThyssenKrupp Steel Europe AG: Leichtbau bei Tür-Aussenhaut. ATZ extra, 2014, vol. 19, pp. 115–118.
    15. Grobmann K., Cherif C., Staiger E. et al. 3D-Bauteile aus Blech und Textil durch umformende Verbundherstellung: EFB Forschungsbericht Nо. 383. Hannover, 2013, 192 p.
    16. Hälsig A., Podlesak F., Mayr P. et al. Dissimilar joints between metal and fibre-reinforced plastics. 19 Symposium Verbundwerkstoffe und Werkstoffverbunde. Jena, Germany: Conventus Congressmanagement & Marketing, 2013, pp. 343–349.
    17. Nestler D. Beitrag zum Thema Verbundwerkstoffe – Werkstoffverbunde. Status quo und Forschungsansätze. Chemnitz, 2014, 474 р.
    18. Wielage B., Nestler D., Steger H. et al. CAPAAL and CAPET – New Materials of High-Strength, High-Stiff Hybrid Laminates. Integrated Systems, Design and Technology 2010. Springer Berlin Heidelberg, 2011, pp. 23–35.
    19. Frantz M., Lauter C., Troester T. Advanced Manufacturing Technologies for Automotive Structures in Multi-Material Design Consisting of High-Strength Steels and CFRP. 56th International Scientific Colloquium. Ilmenau, Deutschland, 2011, pp. 12–16.
    20. Schulze K., Hausmann J., Wielage B. The Stability of Different Titanium-PEEK Interfaces against Water. Procedia Materials Science, 2013, vol. 2, pp. 92–102.
    21. Velthuis R., Mitschang P., Schlarb A. Prozessführung zur Herstellung und Eigenschaften von Metall. Kaiserslautern: Institut für Verbundwerkstoffe GmbH, 2005, 193 р.
    22. Sokolova O., Carradó A., Palkowski H. Adhesion and Formability of Thin Steel/Polymer/Steel Hybrid Sandwich Composites. Steel research international, 2011. Special ed., pp. 435–440.
    23. Bergmann J., Stambke M. Potential of Laser-manufactured Polymer-metal hybrid Joints. Physics Procedia, 2012, vol. 39, pp. 84–91.
    24. Harhash M., Carradò A., Palkowski H. Forming Limit Diagram of Steel/Polymer/Steel Sandwich Systems for the Automotive Industry. Advanced Composites for Aerospace, Marine, and Land Applications. John Wiley & Sons, Inc., 2014, pp. 243–254.
    25. Bolay C. Beitrag zur Umformung von ebenen und versteiften Schichtverbundwerkstoffen: Dissertation. Frankfurt [am Main], Deutschland, 2014. 213 р.
    26. Harhash M., Gilbert R., Hartmann S., Palkowski H. Experimental characterization, analytical and numerical investigations of metal/polymer/metal sandwich composites – Part 2: free bending. Composite Structures, 2020, vol. 232, pp. 1–15.
    27. Kim J., Thomson P. Forming behaviour of sheet steel laminate. Journal of Materials Processing Technology, 1990, vol. 22, pp. 45–64.
    28. Nosova E.A., Lukonina N.V., Khramova M.I. et al. Stampability of three- and five-layer aluminum-polymer composites. Konstruktsii iz kompozitsionnykh materialov, 2016, no. 3, pp. 30–37.
    29. Khardin M., Harhash M., Chernikov D. et al. Preliminary studies on electromagnetic forming of aluminum/polymer/aluminum sandwich sheets. Composite Structures, 2020, vol. 252, p. 24.
    30. Glushchenkov V.A., Palkowski H., Yusupov R.Y. et al. A non-destructive method for evaluating the adhesion between the layers of metal-polymer-metal composite materials. Materiali in Tehnologije, 2024, vol. 58, is. 1, no. 1, pp. 3–8.
    31. Method for determining the mechanical loss coefficient of an object, primarily a vibration isolator: a. s. SU 1 555 623 A1; appl. 22.05.86; publ. 07.04.90.
    32. State Standard R ISO 10846-1–2010. Vibration. Laboratory measurements of vibroacoustic transfer characteristics of elastic structural elements. Part 1. General principles of measurement. Moscow: Standartinform, 2011, 28 p.
    33. State Standard 31368.4–2008 (ISO 10846-4:2003). Vibration. Laboratory measurements of vibroacoustic transfer characteristics of elastic structural elements. Part 4. Dynamic stiffness of unsupported elastic structural elements for translational vibration. Moscow: Standartinform, 2009, 35 p.
    34. Ivanov N.I. Engineering Acoustics. Theory and Practice of Noise Control. Moscow: Logos, 2008, 424 p.
    35. Bogolepov I.I. Industrial Soundproofing. Leningrad: Sudostroenie, 1986, 367 p.
    36. E756-04. Standard Test Method for Measuring Vibration-Damping Properties of Materials. ASTM International, 2004, 13 р.

Full version (rus)
18.

DOI: 10.18577/2713-0193-2026-0-2-220-229

UDC: 620.179.1

Pages:: 220-229

V.S. Shitikov1, S.S. Pichugin1

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

FEATURES OF SIGNAL FILTERING APPLICATION IN NON-DESTRUCTIVE TESTING BY THE EDDY CURRENT METHOD

The article examines the influence of the scanning speed of an eddy current probe during manual control on the signals from defects received after filtering. The analysis of the signals obtained by scanning a sample with an artificial defect, which is a fatigue crack, was carried out. The relationship between the signal from a defect in the time domain and the response after a high-pass filter is shown. Using finite element modeling, eddy current probe signals were obtained when passing through a defect for various values of the probe diameter, and the dependence of the signal pulse duration on the probe diameter was constructed.

Keywords: eddy current testing, non-destructive testing, digital signal processing, filtering, surface eddy current probe, scanning speed, mathematical modeling

Reference List

    1. Kablov E.N., Evgenov A.G., Bakradze M.M., Nerush S.V., Krupnina O.A. New generation materials and digital additive technologies for the production of resource parts of FSUE VIAM. Part 2. Compensation and control of deviations, GIP and heat treatment. Elektrometallurgiya, 2022, no. 2, pp. 2–12.
    2. Krasnov I.S., Dalin M.A., Zarodova A.A., Yakovleva S.I., Verhodanova A.A. Automated ultrasonic inspection of titanium alloy gas turbine disc forgings using conical acoustic mirror. Trudy VIAM, 2024, no. 5 (135), pp. 37–49. Available at: http://www.viam-works.ru (accessed: May 17, 2025). DOI: 10.18577/2307-6046-2024-0-5-37-49.
    3. Antipov V.V., Boichuk A.S., Chertishchev V.Yu., Yakovleva S.I., Barannikov A.A. Identification of operational damage from blades of rotors and tail rotors made of PCM in operating conditions. Trudy VIAM, 2023, no. 7 (125), pp. 93–103. Available at: http://www.viam-works.ru (accessed: May 17, 2025). DOI: 10.18577/2307-6046-2023-0-7-93-103.
    4. Shitikov V.S., Kodak N.P. The ability to assess the degree of corrosion damage by eddy current testing. Trudy VIAM, 2021, no. 5 (99), pp. 96–104. Available at: http://www.viam-works.ru (accessed: May 17, 2025). DOI: 10.18577/2307-6046-2021-0-5-96-104.
    5. Shitikov V.S., Pichugin S.S. Estimation of electrical properties distribution under elastic deformation of the control object by eddy current method. Trudy VIAM, 2024, no. 11 (141), pp. 89–99. Available at: http://www.viam-works.ru (accessed: May 17, 2025). DOI: 10.18577/2307-6046-2024-0-11-89-99.
    6. Gerasimov V.G., Klyuev V.V., Shaternikov V.E. Methods and devices for electromagnetic testing. Moscow: Spektr, 2010, 256 p.
    7. Gerasimov V.G., Pokrovsky A.D., Sukhorukov V.V. Non-destructive testing: a practical guide: in 5 books. Moscow: Vysshaya shkola, 1992, book 3: Electromagnetic testing, 312 p.
    8. Bowler J.R., Theodoulidis T.P., Poulakis N. Eddy current probe signals due to a crack at a right-angled corner. IEEE Transactions on magnetics, 2012, vol. 45, pp. 4735–4746.
    9. Koshelnikov V.S., Pokrovsky A.D. Study of Eddy Current Transducer Signals in Higher Harmonics Testing. Vestnik MEI, 2016, no. 3, pp. 50–53.
    10. Slavinskaya E.A., Terekhin I.V. Study of Eddy Current Transducer Signals in Pulse Flaw Detection. Vestnik MEI, 2015, no. 4, pp. 39–42.
    11. Shitikov V.S. Application of Signal Processing Methods to Improve the Efficiency of Measuring Geometric Dimensions by the Eddy Current Method. Tekhnologiya mashinostroeniya, 2012, no. 2, pp. 50–52.
    12. Zhang H., Xie F., Li Q. Study on the signal processing methods of the eddy current testing on the steel ball surface defects. Advanced Materials Research, 2012, vol. 538–541, pp. 397–401.
    13. Zhdanov A.G., Shchukis E.G., Lunin V.P., Stolyarov A.A. Algorithms for preliminary assessment of eddy current signal processing during testing of heat exchange tubes of NPP steam generators. Defektoskopiya, 2018, no. 4, pp. 54–64.
    14. Das M., Ramuhalli P., Udpa L., Udpa S. An adaptive Wiener filter based technique for automated detection of defect locations from bobbin coil eddy current data. AIP Conference Proceedings, 2002, vol. 615, is. 1, pp. 639–646.
    15. Slesarev D.A., Barat V.A. Use of Wavelet Transformation for Signal Analysis in the Testing of Steel Cables. Measurement Techniques, 2001, vol. 44, no. 1, pp. 66–70.
    16. Efimov A.G. Development of adaptive eddy current means. Defektoskopiya, 2010, no. 10, pp. 89–99.
    17. Huang S., Hong M., Lin G. et al. A Discrete Fourier Transform-Based Signal Processing Method for an Eddy Current Detection Sensor. Sensors, 2025, no. 25, pp. 14.
    18. Yakimov E.V., Urazbekov E.I., Goldstein A.E., Bulgakov V.F. Computational transformation of signals of measurement information of the eddy current flaw detection system. Defektoskopiya, 2013, no. 11, pp. 59–66.
    19. Sergienko A.B. Digital signal processing: textbook. St. Petersburg, 2011, 768 p.
    20. Kartashev V.G. Fundamentals of the theory of discrete signals and digital filters: textbook. Moscow: Vysshaya shkola, 1982, 109 p.
    21. Oppenheim A., Shafer R. Digital signal processing: trans. from Engl. by S.A. Kuleshov. Moscow: Tekhnosfera, 2006, 856 p.

Full version (rus)
19.

DOI: 10.18577/2713-0193-2026-0-2-230-240

UDC: 66.045.3

Pages:: 230-240

P.S. Marakhovskii1, M.G. Razmakhov1, N.S. Skuridina1, A.N. Savritsky1

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

INFLUENCE OF TECHNOLOGICAL PARAMETERS OF MATERIALS PROCESSING ON THE MEASUREMENT OF THEIR THERMOPHYSICAL PROPERTIES

In the study of thermophysical properties, a phenomenological model is often used, representing the object of study in the form of a homogeneous body. However, during the manufacture of the material, heterogeneities or defects may occur that affect its final properties. The paper shows the effect of technological parameters on the thermal conductivity of thermal insulation materials made of basalt fiber, carbon fiber based on a fabric preform, intermetallic titanium γ-alloy, layered hybrid material based on aluminum alloy and fiberglass, and cured adhesive prepreg.

Keywords:  thermophysical properties, temperature coefficient of linear expansion, thermal stresses, thermal insulation material, technology, thermal resistance, differential scanning calorimetry

Reference List

    1. Vertrogradsky V.A. Effective methods for studying thermophysical properties of materials. Vestnik TGTU, 2008, vol. 14, no. 2, pp. 282–286.
    2. Rundans M., Sedmale G., Krumina A., Ivdre A. Influence of Technological Parameters on Thermal Properties of Cordierite Ceramics. Key Engineering Materials, 2018, vol. 762, pp. 300–305.
    3. Zuev A.V., Razmakhov M.G., Barinov D.Ya., Marakhovskii P.S. Calculation and experimental investigation into the thermal conductivity of materials of ceramic casting molds. I. Experiment. Journal of engineering physics and thermophysics, 2019, vol. 92 (3), pp. 805–811.
    4. Bakradze M.M., Doronin O.N., Artemenko N.I., Stekhov P.A., Marakhovskii P.S., Stolyarova V.L. Physicochemical properties of Sm2O3–ZrO2–HfO2 ceramics for the development of promising thermal barrier coatings. Russian Journal of Inorganic Chemistry, 2021, vol. 66, no. 5, pp. 789–797.
    5. Kablov E.N., Doronin O.N., Artemenko N.I., Stekhov P.A., Marakhovskii P.S., Stolyarova V.L. Investigation of the physicochemical properties of ceramics in the SM2O3–Y2O3–HfO2 system for developing promising thermal barrier coatings. Russian Journal of Inorganic Chemistry, 2020, vol. 65, no. 6, pp. 914–923.
    6. Dulnev G.N., Zarichnyak Yu.P. Thermal conductivity of mixtures and composite materials. Leningrad: Energiya, 1974, 264 p.
    7. Vorobev N.N., Barinov D.Ya., Zuev A.V., Pakhomkin S.I. Computational and experimental study of the effective thermal conductivity of fibrous materials. Trudy VIAM, 2021, no. 7 (101), pp. 95–102. Available at: http://www.viam-works.ru (accessed: September 29, 2025). DOI: 10.18577/2307-6046-2021-0-7-95-102.
    8. Pavlova O.V., Kireeva S.M., Romantseva I.I., Sivergin Yu.M. Intramolecular cyclization during radical polymerization of diallyl monomers. Vysokomolekulyarnye soedineniya, 1990, vol. 32, no. 6, pp. 1256–1260.
    9. Irzhak V.I. Architecture of polymers. Moscow: Nauka, 2012, 368 p.
    10. Irzhak V.I., Mezhikovskii S.M. Kinetics of oligomer curing. Russian Chemical Reviews, 2008, vol. 77, no. 1, pp. 77–103.
    11. Berlin A.A., Deberdeev R.Ya., Perukhin Yu.V., Garipov R.M. Influence of thermodynamic conditions of polymerization on the supramolecular and molecular structure of polymers. Klei. Germetiki. Tekhnologii, 2009, no. 2, pp. 2–7.
    12. Petrova A.P., Mukhametov R.R., Akhmadieva K.R. Internal stresses in cured polyester binders for polymer composites. Trudy VIAM, 2019, no. 5 (77), pp. 12–21. Available at: http://www.viam-works.ru (accessed: September 29, 2025). DOI: 10.18577/2307-6046-2019-0-5-12-21.
    13. Startsev V.O., Slavin A.V. Carbon and glass reinforced polymer based on solvent free binders resistance to the impact of a moderate cold and moderate warm climate. Trudy VIAM, 2021, no. 5 (99), pp. 114–126. Available at: http://www.viam-works.ru (accessed: September 29, 2025). DOI: 10.18577/2307-6046-2021-0-5-114-126.
    14. Startsev V.O., Nikolaev E.V., Vardanyan A.M., Nechaev A.A. The influence of climatic factors on residual stresses in nanomodified cyanate ester-based CFRP. Trudy VIAM, 2021, no. 8 (102), pp. 104–112. Available at: http://www.viam-works.ru (accessed: September 29, 2025). DOI: 10.18577/2307-6046-2021-0-8-104-112.
    15. Kablov E.N., Chibirkin V.V., Vdovin S.M. Manufacturing, properties and application of the heat-removing bases from Al–SiC MMK in power electronics and converting equipment. Aviacionnye materialy i tehnologii, 2012, no. 2, pp. 20–22.
    16. Kablov E.N., Nechaikina T.A., Somov A.V., Ivanov A.L., Murzabaeva O.Yu. Effect of heat treatment on the structure and properties of pressed semi-finished products made of promising super-strong aluminum alloy B-1977. Metallovedenie i termicheskaya obrabotka metallov, 2023, no. 1 (811), pp. 28–33.
    17. Krotov D.M. Structures of two-component titanium powder of α- and β-phases in MIM technology. Vestnik PNIPU. Aerokosmicheskaya tekhnika, 2022, no. 71, pp. 74–82.
    18. Agapovichev A.V., Sotov A.V., Kokareva V.V. et al. Study of the structure and mechanical characteristics of samples obtained by selective laser melting technology from VT6 alloy metal powder. Nanoscience and Technology, 2017, vol. 8 (4), pp. 323–330. DOI: 10.1615/NanoSciTechnolIntJ.v8.i4.30.
    19. Wimler D., Kindemann J., Reith M. et al. Designing advanced intermetallic titanium aluminide alloys for additive manufacturing. Intermetallics, 2021, no. 131, pp. 1–10. DOI: 10.1016/j.intermet.2021.107109.
    20. Kochubey A.Ya., Medvedev P.N., Zhuravleva P.L. Application of X-ray diffractometry for researching structural formation processes during the hot pressure working and heat treatment of deformed metals and alloys. Trudy VIAM, 2024, no. 5 (135), pp. 50–60. Available at: http://www.viam-works.ru (accessed: September 29, 2025). DOI: 10.18577/2307-6046-2024-0-5-50-60.
    21. Antipov V.V., Senatorova O.G., Sidelnikov V.V., Shestov V.V. Structural layered materials SIAL. Klei. Germetiki. Tekhnologii, 2012, no. 6, pp. 13–17.
    22. Donetskiy K.I., Karavayev R.Yu., Raskutin A.Ye., Dun V.A. Carbon fibers composite material on the basis of volume reinforcing triax braiding preformes. Trudy VIAM, 2019, no. 1 (73), pp. 55–63. Available at: http://www.viam-works.ru (accessed: September 29, 2025). DOI: 10.18577/2307-6046-2019-0-1-55-63.
    23. State Standard R 56754–2015. Plastics. Differential scanning calorimetry (DSC). Part 4. Determination of specific heat capacity. Moscow: Standartinform, 2015, 13 p.
    24. ASTM 1269–2018. Standard Test Method for Determining Specific Heat Capacity by Differential Scanning Calorimetry. West Conshohocken: ASTM International, 2018, 6 р.
    25. Organization Standard 1-595-36-438–2014. Methodology for Determining the Heat Capacity and Glass Transition Temperature of Polymeric Composites Using Differential Scanning Calorimetry. Moscow: VIAM, 2014, 19 p.
    26. State Standard R 32618.2–2014. Plastics. Thermomechanical Analysis (TMA). Part 2. Determination of the Coefficient of Linear Thermal Expansion and Glass Transition Temperature. Moscow: Standartinform, 2014, 11 p.

Full version (rus)
20.

DOI: 10.18577/2713-0193-2026-0-2-241-252

UDC: 678.747.2

Pages:: 241-252

N.G. Pavlukovich1, M.S. Ivanov1, M.A. Guseva1, E.A. Borisova1, V.S. Morozova1, I.V. Mekalina1

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

THERMO-OXIDATIVE STABILITY OF PEEK AND CARBON FIBER-REINFORCED PEEK COMPOSITES

The research shows the effect of temperature on the properties of polyetheretherketone and layered composite material based on it. It was established that due to its high thermal stability without oxygen access, this polymer can be recycled at least five times without losing its fluidity. However, oxygen access to the surface layer of the melt leads to the formation of a non-fusible polymer with low oxygen diffusion. Heating the composite to the temperature exceeding the melting point of the matrix, leads to deconsolidation, however, its strength is maintained until melting.

Keywords: thermoplastic polymer composite material, polyetheretherketone, heat resistance, cross-linking, flexural temperature under load

Reference List

    1. Kablov E.N., Startsev V.O. The influence of internal stresses on the aging of polymer composite materials: a review. Mechanics of Composite Materials, 2021, vol. 57, no. 5, pp. 565–576.
    2. Shaov A.Kh., Kharaev A.M., Mikitaev A.K. et al. Polymer composite materials based on polyetheretherketones. Plasticheskie massy, 1992, no. 3, pp. 3–7.
    3. Mikitaev A.K., Salamov A.Kh., Beev A.A., Beeva D.A. Filling with polyetheretherketone (PEEK) as a method for obtaining composites with high performance properties. Plasticheskie massy, 2017, no. 5–6, pp. 6–9.
    4. Kablov E.N., Semenova L.V., Petrova G.N., Larionov S.A., Perfilova D.N. Polymer composite materials on a thermoplastic matrix. Izvestiya vysshikh uchebnykh zavedeniy. Ser.: Khimiya i khimicheskaya tekhnologiya, 2016, vol. 59, no. 10, pp. 61–71.
    5. Kharaev A.M., Bazheva R.Ch. Polyetheretherketones: synthesis, properties, application (review). Plasticheskie massy, 2018, no. 7–8, pp. 15–23.
    6. McLauchlin A.R., Ghita O.R., Savage L. Studies on the reprocessability of poly(ether ether ketone) (PEEK). Journal of Materials Processing Technology, 2014, vol. 214, is. 1, pp. 75–80. DOI: 10.1016/j.jmatprotec.2013.07.010.
    7. Jar P.-Y., Kausch H.H. Annealing effect on mechanical behavior of PEEK. Journal of Polymer Science. Part B: Polymer Physics, 1992, vol. 30, no. 7, pp. 775–778. DOI: 10.1002/polb.1992.090300715.
    8. Day M., Sally D., Wiles D.M. Thermal Degradation of Poly(aryl-ether-ether-ketone): Experimental Evaluation of Crosslinking Reactions. Journal of Applied Polymer Science, 1990, vol. 40, is. 9-10, pp. 1615–1625. DOI: 10.1002/app.1990.070400917.
    9. Ivanov M.S., Morozova V.S., Pavlukovich N.G. Influence of technological modes of manufacture on properties of consolidated plates of carbon fiber reinforced thermoplastic based on polyetheretherketone. Trudy VIAM, 2025, no. 3 (145), pp. 60–69. Available at: http://www.viam-works.ru (accessed: October 29, 2025). DOI: 10.18577/2307-6046-2025-0-3-60-69.
    10. Pascual A., Toma M., Tsotra P., Grob M.C. On the stability of PEEK for short processing cycles at high temperatures and oxygen-containing atmosphere. Polymer Degradation and Stability, 2019, vol. 165, pp. 161–169. DOI: 10.1016/j.polymdegradstab.2019.04.025.
    11. Zhang Z., Zeng H. Effects of thermal treatment on poly(ether ether ketone). Polymer, 1993, vol. 34, is. 17, pp. 3648–3652. DOI: 10.1016/0032-3861(93)90049-G.
    12. Petrova G.N., Beider E.Ya. Structural materials based on reinforced thermoplastics. Rossiyskiy khimicheskiy zhurnal, 2010, vol. 54, no. 1, pp. 34–40.
    13. Morozova V.S., Ivanov М.S., Shestakov A.M., Pavlukovich N.G. The influence of the melt flow of polyetheretherketone on the characteristics of carbon fiber plastic based on it. Trudy VIAM, 2024, no. 1 (131), pp. 44–51. Available at: http://www.viam-works.ru (accessed: November 05, 2025). DOI: 10.18577/2307-6046-2024-0-1-44-51.
    14. Sorokin A.E., Sagomonova V.A., Petrova A.P., Solovyanchik L.V. Manufacturing technologies of polymer composite materials on thermoplastics (review). Trudy VIAM, 2021, no. 3 (97), pp. 78–86. Available at: http://www.viam-works.ru (accessed: November 05, 2025). DOI: 10.18577/2307-6046-2021-0-3-78-86.
    15. Pavlukovich N.G., Ivanov М.S., Morozova V.S., Donskih I.N. Investigation of the thermal stability of the melt polyetheretherketone PEEK-50P and carbon fiber based on it. Aviation materials and technologies, 2024, no. 2 (75), pp. 90–98. Available at: http://www.journal.viam.ru (accessed: November 05, 2025). DOI: 10.18577/2713-0193-2024-0-2-99-108.
    16. Patel P., Hull T.R., McCabe R.W. et al. Mechanism of thermal decomposition of poly(ether ether ketone) (PEEK) from a review of decomposition studies. Polymer Degradation and Stability, 2010, vol. 95, is. 5, pp. 709–718. DOI: 10.1016/j.polymdegradstab.2010.01.024.
    17. Patel P., Hull T.R., Lyon R.E. et al. Investigation of the thermal decomposition and flammability of PEEK and its carbon and glass-fibre composites. Polymer Degradation and Stability, 2011, vol. 96, is. 1, pp. 12–22. DOI: 10.1016/j.polymdegradstab.2010.11.009.
    18. Vasconcelos G.C., Mazur R.L., Ribeiro B. et al. Evaluation of Decomposition Kinetics of Poly (Ether-Ether-Ketone) by Thermogravimetric Analysis. Materials Research, 2013, vol. 17, is. 1, pp. 227–235. DOI: 10.1590/S1516-14392013005000202.
    19. Thiruchitrambalam M., Bubesh Kumar D., Shanmugam D., Jawaid M. A review on PEEK composites – Manufacturing methods, properties and applications. Materials Today: Proceedings, 2020, vol. 33, pp. 1085–1092. DOI: 10.1016/j.matpr.2020.07.124.
    20. Francis J.N., Banerjee I., Chugh A., Singh J. Additive manufacturing of polyetheretherketone and its composites: A review. Polymer composite, 2022, no. 43 (9), pp. 1–18. DOI: 10.1002/pc.26961.

Full version (rus)