ARCHIVE

Aviation materials and technologies №1, 2024

Contents

Heat-resistant alloys and steels

  • A.V. Sviridov, A.G. Evgenov, A.N. Afanаsiev-Khodykin, I.A. Galushka

    HARDENING OF NICKEL SUPERALLOY PARTS BY THE COMPOSITE BRAZING METHOD USING COBALT BASED STELLITE V5K

    3-13
    https://journal.viam.ru/sites/default/files/uploads/contents/2024/2024_1_content.pdf
  • N.A. Nochovnaya, V.I. Ivanov, S.A. Yakimova, R.S. Islamov

    INTERMETALLIC COMPOUND Ti2AlNb – PROMISING MATERIAL FOR AVIATION AND SPACE TECHNOLOGY Part 2. Short-term strength and сreep resistance of Ti2AlNb alloys

    14-32
    https://journal.viam.ru/sites/default/files/uploads/contents/2024/2024_1_content.pdf

Light-metal alloys

  • O.S. Kashapov, T.V. Pavlova, V.S. Kalashnikov, A.V. Zavodov

    PREREQUISITES FOR THE DEVELOPMENT OF NEW LOW-ALLOYED TECHNOLOGICAL MEDIUM STRENGTH TITANIUM ALLOY WITH OPERATING TEMPERATURE UP TO 400–450 °С, CAPABLE OF STRENGTHENING

    33-50
    https://journal.viam.ru/sites/default/files/uploads/contents/2024/2024_1_content.pdf
  • E.F. Volkova, I.V. Mostyaev, M.V. Akinina, A.A. Alikhanyan

    FEATURES OF THE FORMATION OF THE STRUCTURE IN A THIN SHEET OF MAGNESIUM ALLOY MA2-1 IN THE PROCESS OF DEFORMATION

    51-62
    https://journal.viam.ru/sites/default/files/uploads/contents/2024/2024_1_content.pdf
  • Yu.V. Reshetnikov, A.V. Trapeznikov, K.A. Vlasova, A.A. Leonov

    DIFFERENT FACTORS INFLUENCE ON TECHNOLOGICAL PROPERTIES OF SELF-HARDENING PHENOL FORMALDEHYDE RESIN SANDS. Part 1

    63-77
    https://journal.viam.ru/sites/default/files/uploads/contents/2024/2024_1_content.pdf

Composite materials

  • A.V. Istomin

    STUDY OF THE DISTRIBUTION OF ALUMINUM OXIDE NANOPOWDER IN A POLYMER SOLUTION

    78-88
    https://journal.viam.ru/sites/default/files/uploads/contents/2024/2024_1_content.pdf
  • G.F. Zhelezina, G.S. Kulagina, A.I. Sidorina, N.A. Soloveva

    FATIGUE OF CONSTRUCTIONAL ORGANOPLASTICS

    89-100
    https://journal.viam.ru/sites/default/files/uploads/contents/2024/2024_1_content.pdf

Protective and functional coatings

  • S.A. Budinovskiy, D.S. Gorlov, A.S. Benklyan

    DEPOSITION OF PROTECTIVE ION-PLASMA COATINGS ON LARGE-SCALE PARTS ON MAP TYPE INSTALLATIONS

    101-110
    https://journal.viam.ru/sites/default/files/uploads/contents/2024/2024_1_content.pdf

Material tests

  • I.S. Lednev

    MAGNETIC METHODS OF NON-DESTRUCTIVE TESTING OF AIRCRAFT PARTS

    111-120
    https://journal.viam.ru/sites/default/files/uploads/contents/2024/2024_1_content.pdf
  • A.I. Sutubalov, N.Yu. Podzhivotov, P.V. Shershak, N.O. Yakovlev

    EVALUATION OF HOMOGENEITY OF PHYSICAL AND MECHANICAL PROPERTIES OF SEMI-FINISHED PRODUCTS FOR AVIATION PURPOSE

    121-135
    https://journal.viam.ru/sites/default/files/uploads/contents/2024/2024_1_content.pdf
  • V.O. Startsev, O.V. Startsev, T.O. Zeleneva, A.M. Vardanyan

    INFLUENCE OF PRECIPITATION ON CHANGES IN THE MASS OF SAMPLES OF POLYMERIC COMPOSITE MATERIALS IN OPEN CLIMATIC CONDITIONS

    136-154
    https://journal.viam.ru/sites/default/files/uploads/contents/2024/2024_1_content.pdf
  • A.A. Krivushina, A.B. Laptev

    FUNGICIDES: APPLICATION, PROPERTIES AND PRINCIPLES OF ACTION 

    155-168
    https://journal.viam.ru/sites/default/files/uploads/contents/2024/2024_1_content.pdf
Содержание номера
1.

DOI: 10.18577/2713-0193-2024-0-1-3-13

UDC: 621.791

Pages:: 3-13

A.V. Sviridov1, A.G. Evgenov1, A.N. Afanаsiev-Khodykin1, I.A. Galushka1

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

HARDENING OF NICKEL SUPERALLOY PARTS BY THE COMPOSITE BRAZING METHOD USING COBALT BASED STELLITE V5K

The article presents the testing results of hardening by a method of the composite brazing the bandage shelves of turbine engine rotor blades by surfacing of cobalt-based stellite V5K as well as studies on the influence of technological parameters of brazing and the ratio of solder powder and stellite in a composite mixture on the quality of surfacing formation. The estimation of the heat resistance of the composite surfacing a powder stellite V5K at a temperature of 1050 °С using various brazing alloys and their contents was carried out. The alloy for brazing was chosen, optimum technological parameters of the brazing and the stellite content in the composite brazing alloy having the minimum porosity and the highest heat resistance of surfacing were determined.

Keywords: brazing, high-temperature brazing, surfacing, nickel heat-resistant brazing alloy, composite brazing alloy, stellite, cobalt alloy, nickel super alloys

Reference List

    1. Kablov E.N. What is innovation. Nauka i zhizn, 2011, no. 11, pp. 16–21.
    2. Kablov E.N. Additive technologies are the dominant feature of the national technology initiative. Intellekt i tekhnologii, 2015, no. 2 (11), pp. 52–55.
    3. Kablov E.N. At the crossroads of science, education and industry. Ekspert, 2015, no. 15 (941), pp. 49–53.
    4. Kablov E.N., Ospennikova O.G., Lomberg B.S., Sidorov V.V. Priority directions for the development of technologies for the production of heat-resistant materials for aircraft engine building. Problemy chernoy metallurgii i materialovedeniya, 2013, no. 3, pp. 47–54.
    5. Aslanian G.G., Sukhov D.I., Mazalov P.B., Sulyanova E.A. Fractographic study of Co–Cr–Ni–W–Ta alloy samples obtained by selective laser melting. Trudy VIAM, 2019, no. 4 (76), paper no. 01. Available at: http://www.viam-works.ru (accessed: April 10, 2023). DOI: 10.18577/2307-6046-2019-0-4-3-10.
    6. Bogachev I.A., Sulyanova E.A., Sukhov D.I., Mazalov P.B. Microstructure and properties investigations of Fe–Cr–Ni stainless steel obtained by selective laser melting. Trudy VIAM, 2019, no. 3 (75), paper no. 01. Available at: http://www.viam-works.ru (accessed: April 10, 2023). DOI: 10.18577/2307-6046-2019-0-3-3-13.
    7. Sukhov D.I., Mazalov P.B., Nerush S.V., Khodirev N.A. The influence of SLS parameters on pores formation in stainless steel material. Trudy VIAM, 2017, no. 8 (56), paper no. 04. Available at: http://www.viam-works.ru (accessed: April 10, 2023). DOI: 10.18577/2307-6046-2017-0-8-4-4.
    8. Marchese G., Basila G., Bassini E. et al. Study of the Microstructure and Cracking Mechanism of Hastelloy X Produced by Laser Powder Bed Fusion. Materials, 2018, vol. 11, pp. 106–118. DOI: 10.3390/ma11010106.
    9. Wang F., Wu X., Clark D. On direct laser deposited Hastelloy X: Dimension, surface finish, microstructure and mechanical properties. Materials Science and Technology, 2011, vol. 27, pp. 344–356. DOI: 10.1179/026708309X12578491814591.
    10. Gu D., Meiners W., Wissenbach K., Poprawe R. Laser additive manufacturing of metallic components: Materials, processes and mechanisms. International Materials Reviews, 2012, vol. 57, pp. 133–164. DOI: 10.1179/1743280411Y.0000000014.
    11. Coykendall J., Cotteleer M., Holdowsky J., Mahto M. 3D opportunity in aerospace and defense. Additive manufacturing takes flight. 2014. Available at: https://www2.deloitte.com/content/dam/insights/us/articles/additive-manu... (accessed: April 10, 2023).
    12. Mazalov P.B., Suhov D.I., Sulyanova E.A., Mazalov I.S. Heat-resistant cobalt-based alloys. Aviation materials and technologies, 2021, no. 3 (64), paper no. 01. Available at: http://www.journal.viam.ru (accessed: April 10, 2023). DOI: 10.18577/2713-0193-2021-0-3-3-10.
    13. 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.
    14. Lukin V.I., Rylnikov V.S., Afanasyev-Khodykin A.N. Nickel-based solders for soldering heat-resistant alloys and steels. Svarochnoe proizvodstvo, 2014, no. 7, pp. 36–42.
    15. Afanasev-Hodykin A.N., Lukin V.I., Rylnikov V.S. High-tech semi-finished high-temperature solders (tape and paste on an organic binder). Trudy VIAM, 2013, no. 9, paper no. 02. Available at: http://viam-works.ru (accessed: April 10, 2023).

Full version
2.

DOI: 10.18577/2713-0193-2024-0-1-14-32

UDC: 669.017.165

Pages:: 14-32

N.A. Nochovnaya1, V.I. Ivanov1, S.A. Yakimova1, R.S. Islamov1

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

INTERMETALLIC COMPOUND Ti2AlNb – PROMISING MATERIAL FOR AVIATION AND SPACE TECHNOLOGY Part 2. Short-term strength and сreep resistance of Ti2AlNb alloys

Intermetallic Ti2AlNb alloys are promising materials for structures of aviation and space technology with operating temperatures up to 750 °C. The work used foreign materials on the study of alloy compositions, the effect of thermomechanical and thermal processing operations on the microstructure and mechanical properties of alloys (strength, plastic, heat-resistant) at 20 °C and elevated temperatures. The analysis of the works showed that only bimodal lamellar microstructures provide an increased level of alloys properties.

Keywords: Ti2AlNb intermetallic compound, thermomechanical and heat treatment, microstructures, mechanical properties

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. VIAM: new generation materials for PD-14. Krylya Rodiny, 2019, no. 7–8, pp. 54–58.
    3. Kablov E.N., Bondarenko Yu.A., Kolodyazhny M.Yu., Surova V.A., Narsky A.R. Prospects for the creation of high-temperature heat-resistant alloys based on refractory matrices and natural composites. Voprosy materialovedeniya, 2020, no. 4 (104), pp. 64–78.
    4. 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: 10.18577/2107-9140-2017-0-S-186-194.
    5. Nochovnaya N.A., Ivanov V.I. Prospects for the use of heat-resistant materials based on titanium aluminides. Proc. Int. conf. «Ti-2006 in the CIS». Verkhnyaya Salda, 2006, pp. 39–43.
    6. Ward-Close C.M., Minor R., Doorbar P.J. Intermetallics-Matrix Composites – a review. Journal of Intermetallics, 1996, vol. 4, no. 3, pp. 217–229.
    7. Leyens C., Hausmann J., Kumfert J. Continuous Fiber Reinforced Titanium Matrix Composites Fabrication, Properties and Applcation. Titanium and Titanium Alloys. Fundamental and Application. Ed. C. Leyens, M. Peters. Weinheim: Wiley-VCH VerlagGnbH& Co. KGaA, 2003, pp. 305–331.
    8. Metals Matrix Composites. Castom-made Materials for Automotive and Aerospace Engineering. Ed. R.U. Kainer. Wiemheim: Wiley-VCH Verlag GmbH & Co. KGaA, 2006, pp. 51–62.
    9. Kumpfert J. Intermetallic alloys based on orthorhombic titanium aluminide // Journal of Advinced Engineering Materials, 2001, vol. 3, no. 11, pp. 851‒864.
    10. Kumpfert J., Kaysser W.A. Orthorhombic titanium aluminides – phases, phase transformation and microstructure evolution. Journal of Zeitschrift fur Metallkunde, 2001, vol. 92, no. 2, pp. 128–134.
    11. Li S., Chen Y., Liang X., Zhang J. Recent work on alloy and processes development of Ti2AlNb based alloys // Journal of Materials Science Forum, 2005, vol. 475–479, pp. 795–800.
    12. Zhang H., Yan N., Liang H., Liu Y. Phase transformation and microstructure control of Ti2AlNb-based alloys: A review. Journal of Materials Science and Technology, 2021, vol. 80, pp. 203–221. DOI: 10/1016/j.jmst.2020.11.022.
    13. Alexeev Е.B., Nochovnaya N.A., Novak A.V., Panin P.V. Wrought intermetallic titanium ortho alloy doped with yttrium. Part 2. Research on heat treatment effect on rolled slab microstructure and mechanical properties. Trudy VIAM, 2018, no. 12 (72), paper no. 04. Available at: http://www.viam-works.ru (accessed: January 14, 2023). DOI: 10.18577/2307-6046-2018-0-12-37-45.
    14. Novak A.V., Alekseev E.B., Ivanov V.I., Dzunovich D.A. The study of the quenching parameters influence on structure and hardness of orthorhombic titanium aluminide alloy VТI-4. Trudy VIAM, 2018, no. 2, paper no. 05. Available at: http://www.viam-works.ru (accessed: January 14, 2023). DOI: 10.18577/2307-6046-2018-0-2-5-5.
    15. Duyunova V.A., Putyrskiy S.V., Arislanov A.A., Krokhina V.A., Shiryaev A.A. Analysis of the effect of heat treatment on the structure and mechanical properties of bars made of VT47 titanium alloy. Aviation materials and technologies, 2021, no. 4 (65), paper no. 03. Available at: http://www.journal.viam.ru (accessed: April 09, 2023). DOI: 10.18577/2713-0193-2021-0-4-26-34.
    16. Boehlert C.J., Majumdar B., Seetharan B.V., Miracle D. Part I. The microstructural evolution in Ti–Al–Nb O+BCC orthorhombic alloys. Journal Metallurgical Materials Transaction A, 1999, vol. 30, no. 9, pp. 2305–2323.
    17. Dey S.R., Roy S., Suwas S. et al. Annealing response of the intermetallic alloy T–22Al–25Nb. Journal of Intermetallics, 2010, vol. 18, nо. 6, pp. 1122–1131.
    18. Boehlert C.J. Part III. The tensile behavior of Ti–Al–Nb O+BCC orthorhombic alloys. Journal of Metallurgical Materials Transactions A, 2001, vol. 32, pp. 1977–1988.
    19. Kazantseva N.V., Lepikhin S.V. Study of the Ti–Al–Nb phase diagram. Journal of the Physics of Metal and Metallography, 2006, vol. 102, no. 2, pp. 169–180.
    20. Popille F., Douin J. Comparison of the deformation microstructures at room temperature in O and B2 phases of a Ti2AlNb alloy // Journal de Physique IV. Collogue 2. Supplement au Journal de Physique III. Mars, 1996, no. C2, pp. 211–216.
    21. Shao B., Shan D., Guo B., Zong Y. Plastic deformation mechanism and interaction of B2, α2 and O phases in Ti‒22Al‒25Nb alloy at room temperature. International Journal of Plasticity, 2019, vol. 113, pp. 18–34. DOI: 10.1016/J iJplas.2018.09.004.
    22. Benerjee D. The intermetallic Ti2AlNb. Journal of Progress in Materials Science, 1997, vol. 42, pp. 135–158.
    23. Gogia A.K., Banerjee D., Nanady T.K. Structure, tensile deformation, and fracture of a Ti3Al‒Nb. Journal of Metallurgical Transactions A, 1990, vol. 21, pp. 609–625.
    24. Muraleedharan K., Nandy T.K., Banerjee D., Lele S. Phase stability and ordering behavior of the O phase in Ti2AlNb alloys // Journal of Intermetallics, 1995, vol. 3, pp. 187–199.
    25. Smith P.R., Graves J.A., Rhodes C.G. Comparison of orthorhombic and alpha-two titanium aluminides as matrices for continuous SiC-Reinforced composites. Journal of Metallurgical Materials Transections A, 1994, vol. 25A, pp. 1266–1283.
    26. Boehlert C.J., Majumdar B.S., Krishnamurtthy S., Miracle D.B. Role of matrix microstructure on room-temperature tensile properties and fiber-strength utilization of an orthorhombic Ti-Alloy-Based Composite. Journal of Metallurgical Transactions A, 1997, vol. 28, pp. 309–323.
    27. Boehlert C.J. The phase evolution and microstructural stability of an orthorhombic Ti‒23Al‒27Nb alloy. Journal of Phase Equibria, 1999, vol. 20, no. 2, pp. 101–108.
    28. Rowe R.G., Konitzer D.G., Woodfield A.P., Chesnutt J.C. Tensile and creep behavior of ordered orthorhombic Ti–Al–Nb-based alloys. Proceedings «High Temperature Ordered Intermetallic Alloys. IV». Ed. L.A. Jonson, D.P. Pope, J.O. Stiglrer. Pittburg. PA.: Materials Research Society, 1992, pp. 703–708.
    29. Dary F.C., Woodard S.R., Pollock T.M. Effect of environment on the tensile and creep behavior of a low-oxygen orthorhombic-based titanium aluminide Ti‒22Al‒23Nb. Titanium’95 – Science and Technology: Proceedings of the Eighth World Conference on Titanium. University Press Cambridge. UK, 1996, vol. 1, pp. 396–403.
    30. Dey S.R., Roy S., Suwas S. et al. Annealing response of the intermetallic alloy Ti–22Al–25Nb. Journal of Intermetallics, 2010, vol. 18, no. 2, pp. 1122–1131. DOI: 10.4028/www.scientific.net/MSF.475-479.795.
    31. Li S., Yunjun Cheng Y., Liang X., Zhang J. Recent Work on Alloy and Process Development of Ti2AlNb based Alloys. Journal of Materials Science Forum, 2005, vol. 475–479, pp. 795–800. DOI: 10.4028/www.scientific.net/MSF.475-479.795.
    32. Liang X., Li S., Cheng Y., Zhang J. Study on Thermal Stability of Ti–22Al–25Nb Alloy. Rare Metal. Materials and Engineering, 2005, vol. 34, suppl. 3, рр.100‒103.
    33. Xue C., Zeng W., Wang W., Liang X., Zhang J. Quantitative analysis on microstructure evolution and tensile property for the isothermally forged Ti2AlNb based alloy during heat treatment. Journal of Materials Science & Engineering A, 2013, vol. 573, pp. 183–189. DOI: 10.1016/msea2013.03.003.
    34. Xue C., Zeng W., Wang W. et al. The enhanced tensile property by introducing bimodal size distribution of lamellar O for O+B2 Ti2AlNb based alloy. Journal of Materials Science and Engineering A, 2013, vol. 587, pp. 54–60. DOI:10.1016/msea2013.07.047.
    35. Xue C., Zeng W., Wang W. et al. Coarsening behavior of lamellar orthorhombic phase and its effect on tensile properties for the Ti–22Al–25Nb alloy. Journal of Materials Science and Engineering A, 2014, vol. 611, pp. 320–325. DOI:10.1016/msea.2014.05.076.
    36. Wang W., Zeng W., Xue C. et al. Designed bimodal size lamellar O microstructures in Ti2AlNb based alloy: Microstructural evolution, tensile and creep properties. Journal of Materials Science and Engineering A, 2014, vol. 618, pp. 288–294. DOI: 10.1016/msea.2014.09.035.
    37. Wang W., Zeng W., Xue C. et al. Microstructure control and mechanical properties from isothermal forging and heat treatment of Ti–22Al–25Nb (at. %) orthorhombic alloy. Journal of Intermetallics, 2015, vol. 56, pp. 79–86. DOI: 10.1016/j.intermet.2015.07.011.
    38. Zhao H., Lua B., Tonga M., Yanga R. Tensile behavior of Ti‒22Al‒24Nb‒0.5Mo in the range 25–650 °C. Materials Science and Engineering A, 2017, vol. 679, pp. 455–464. DOI: msea.2016.10.047.
    39. Wang W., Zeng W., Liu Y. et al. Microstructural evolution and mechanical properties of Ti–22Al–25Nb (at. %) orthorhombic alloy with three typical. Journal of Materials Engineering and Performance, 2018, vol. 27, no. 1, pp. 293–303. DOI: 101007/s11665-017-3040-9.
    40. Nochovnaya N.A., Ivanov V.I., Alekseyev E.B., Islamov R.S. Intermetallic compound Ti2AlNb – promising material for aviation and space technology. Part 1. Crystal structure and phase transformations. Aviation materials and technologies, 2023, no. 3 (72), paper no. 04. Available at: http://www.journal.viam.ru (accessed: August 07, 2023). DOI: 10.18577/2713-0193-2023-0-3-42-61.
    41. Nochovnaya N.A., Ivanov V.I., Avilochev L.Yu. Intermetallic compound AlxTi – are promising material for high elevated temperatures (review). Part 1. The crystaline structure and properties of the intermetallic compound Al2Ti. Trudy VIAM, 2021, no. 3 (97), paper no. 03. Available at: http://viam-works.ru (accessed: May 17, 2023). DOI: 10.18577/2307-6046-2021-0-3-28-43.
    42. Oglodkov M.S., Duyunova V.A., Nochovnaya N.A., Ivanov V.I., Avilochev L.Yu. Features of the technology manufacturing of deformed blanks from intermetallic alloys VIT1 for parts of the gas turbine engine. Trudy VIAM, 2021, no. 12 (106), paper no. 01. Available at: http://www.viam-works.ru (accessed: May 17, 2023). DOI: 10.18577/2307-6046-2021-0-12-3-13.

Full version
3.

DOI: 10.18577/2713-0193-2024-0-1-33-50

UDC: 669.295

Pages:: 33-50

O.S. Kashapov1, T.V. Pavlova1, V.S. Kalashnikov1, A.V. Zavodov1

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

PREREQUISITES FOR THE DEVELOPMENT OF NEW LOW-ALLOYED TECHNOLOGICAL MEDIUM STRENGTH TITANIUM ALLOY WITH OPERATING TEMPERATURE UP TO 400–450 °С, CAPABLE OF STRENGTHENING

The paper presents the results of studying of low-alloyed Ti–Al–Zr(Sn)–V–Mo–Nb–Fe–Si–O–C titanium alloys. The ingots of alloys were prepared in NRC «Kurchatov institute» All-Russian scientific research institute of aviation materials in form of forgings and cold-deformed sheets. It was shown that alloy on the base of above-mentioned alloying system with 4 % Al and summary concentration of β-stabilizing elements about 3 % after quenching and «high aging» demonstrate ultimate strength at room temperature 1040–1050 MPa at a RA 58,5–65,0 %.

Keywords: titanium alloys, α-phase, heat treatment, ultimate tensile strength, microstructure

Reference List

    1. Glazunov S.G., Moiseev V.N. Structural titanium alloys. Moscow: Metallurgy, 1974, 367 p.
    2. 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.
    3. Moiseyev V.N. Titanium Alloys: Russian Aircraft and Aerospace Applications. 1st ed. CRC Press, 2005. DOI: 10.1201/9781420037678.
    4. Kablov E.N., Kashapov O.S., Pavlova T.V., Nochovnaya N.A. Development of pilot industrial technology for manufacturing semi-finished products from pseudo-alpha titanium alloy VT41. Titan, 2016, no. 2 (52), pp. 33–42.
    5. Illarionov A.G., Kosmatsky Ya.I., Gornostaeva E.A., Vodolazsky F.V. Deformation and heat treatment of pipes made of titanium alloys: textbook. Ekaterinburg: Publ. House of Ural. Univ., 2019, 144 p.
    6. Ilyin A.A., Kolachev B.A., Polkin I.S. Titanium alloys. Composition, structure, properties: reference book. Moscow: VILS – MATI, 2009, 520 p.
    7. Ezhov A.O. Establishment of production of titanium sheets at plant No. 519 in the conditions of modernization of the metallurgical complex of the Urals. Vestnik Severnogo (Arkticheskogo) federal'nogo universiteta. Ser.: Gumanitarnyye i sotsialnye nauki, 2015, no. 5, pp. 15–22.
    8. Kolomensky A.B., Nochovnaya N.A., Zubarev V.Yu. Low-temperature annealing of welded structures made of titanium alloys. Aviacionnye materialy i tehnologii, 2007, no. 1, pp. 43–45.
    9. Petukhov A.N. Some structural strength problems associated with the use of titanium alloys in gas turbine engines. Titanium alloys in the design of passenger aircraft. Titan, 1998, no. 1 (10), pp. 46–49.
    10. Nikhamkin M.Sh., Voronov L.V., Konev I.P. The influence of operational damage and volumetric residual stresses on fatigue strength and resistance to crack development in compressor blades. Vestnik Dvigatelestroeniya, 2006, no. 3, pp. 93–97.
    11. Belousov G.G., Nikitin A.D., Shanyavsky A.A. Model of fatigue failure in operation of a titanium disk of a TA12-60 engine fan. Scientific Bulletin of MSTUGA, 2013, no. 187, pp. 103–107.
    12. James S., Kosaka Y., Thomas R., Garratt P. Timetal® 407: a titanium alloy to enable cost reduction. Proceedings of the 13th World Conference on Titanium. The Minerals, Metals & Materials Society, 2016, рр. 721–725.
    13. Moiseev V.N., Gribkov Yu.A., Zakharov Yu.I. High-strength titanium alloys in aircraft structures. Aviacionnye materialy i tehnologii, 2007, no. 1, pp. 46–51.
    14. Buzyurkin A.E., Gladky I.L., Kraus E.I. Numerical modeling of emergency breakage of a gas turbine engine fan blade. Obrabotka metallov, 2014, no. 4 (65), pp. 52–60.
    15. Gladky I.L., Berezin R.I. Experimental determination of the impact resistance of materials used in fan housings of gas turbine engines. Izvestiya Samarskogo nauchnogo tsentra Rossiyskoy akademii nauk, 2012, vol. 14, no. 4 (5), pp. 1359–1362.
    16. Kurteev V.A., Mozerov B.G., Sokolovsky M.I., Inozemtsev A.A. Assessment of the protective capacity of a turbojet engine fan housing. Vestnik PNIPU. Ser.: Aerokosmicheskaya tekhnika, 2015, no. 40, pp. 22–43. DOI: 10.15593/2224-9982/2015.40.02.
    17. Molod M.V., Maksimenkov V.I., Fedoseev V.I. Form-forming technologies for the manufacture of noise-attenuating casings for turbojet engines. Vestnik Samarskogo universiteta. Ser.: Aerokosmicheskaya tekhnika, tekhnologii i mashinostroenie, 2018, vol. 17, vol. 3, pp. 167–174. DOI: 10.18287/2541-7533-2018-17-3-167-174.
    18. Sheremetyev A.V., Petrov A.V. Taking into account the influence of material properties, design, technological and operational factors when determining the service life of aircraft gas turbine engine parts. Vestnik Dvigatelestroeniya, 2006, no. 1, pp. 91–94.
    19. Birger I.A., Iosilevich G.B. Threaded and flanged connections. Moscow: Mashinostroyenie, 1990, 368 p.
    20. Chernyaev A.V., Charin A.V., Gladkov V.A. Study of power modes of radial extrusion of internal thickenings on pipe blanks. Izvestiya TulGU. Ser.: Tekhnicheskiye nauki, 2020, is. 10, pp. 440–445.
    21. Popov I.P., Maslov V.D., Nikolenko Kir.A., Nikolenko Kon.A. Determination of the limiting parameters for stamping pipeline elements from titanium alloy OT4 and steel 12Х18Н10Т. Izvestiya Samarskogo nauchnogo tsentra Rossiyskoy akademii nauk, 2017, vol. 19, no. 1(3), pp. 477‒482.
    22. Inozemtsev A.A., Bashkatov I.G., Koryakovtsev A.S. Application of titanium-based alloys in products developed by Aviadvigatel OJSC. Aviacionnye materialy i tehnologii, 2007, no. 1, pp. 13–16.
    23. Klimov V.T., Sadkov V.V. Titanium alloys in the design of passenger aircraft. Titan, 1998, no. 1 (10), pp. 10–15.
    24. Balabuev P.V. Titanium alloys in products of ASTC named after. O.K. Antonov. Titanium alloys in the design of passenger aircraft. Titan, 1998, no. 1 (10), pp. 15–19.
    25. Mikheev S.V., Akinshin V.I., Baev A.S., Litvinov V.B., Kiryushin M.S. Experience of using titanium alloys in Kamov helicopters. Titan. 1998, no. 1 (10), pp. 20–23.
    26. Sviridov A.V., Gribkov М.S. Features of repair of welded structures of large thicknesses from titanium alloy VT6ch. Trudy VIAM, 2021, no. 11 (105), paper no. 04. Available at: http://www.viam-works.ru (accessed: July 13, 222). DOI: 10.18577/2307-6046-2021-0-11-34-43.
    27. Korovin G.I., Filippov A.V., Proskokov A.V., Gorbatenko V.V. The influence of the geometric parameters of the cutting blade on the formation of the area of plastic deformation when cutting titanium alloy OT4. Izvestiya vysshikh uchebnykh zavedeniy. Ser.: Mashinostroyeniye, 2016, no. 3 (672), pp. 56–64. DOI: 10.18698/0536-1044-2016-3-56-64.
    28. Evdokimov D.V., Skuratov D.L. The influence of tool wear on the density of heat flow distribution in the cutting zone during end milling of titanium alloy OT4. Vestnik Samarskogo gosudarstvennogo aerokosmicheskogo universiteta, 2015, vol. 14, no. 3, part 2, pp. 409–417.
    29. Sazonov M.B., Zhidyaev A.N. Study of vibrations of end mills when processing titanium alloy VT9. Vestnik Samarskogo universiteta. Ser.: Aerokosmicheskaya tekhnika, tekhnologii i mashinostroyenie, 2021, vol. 20, no. 4, pp. 89–99. DOI: 10.18287/2541-7533-2021-20-4-89-99.
    30. Popov A.Yu., Rechenko D.S., Kisel A.G., Leontyeva E.V., Matveeva M.G. Study of the formation of a lubricating film of cutting fluid during processing of heat-resistant and titanium alloys. Omskiy nauchnyy vestnik, 2015, no. 1 (137), pp. 41–43.
    31. 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: 10.18577/2107-9140-2017-0-S-186-194.
    32. Ponomarenko D.A., Skugorev A.V., Sidorov S.A., Shpagin A.S. Influence of heat exchange between workpiece and die on forming process of aerospace parts by special isothermal presses. Trudy VIAM, 2016, no. 10, paper no. 3. Available at: http://www.viam-works.ru (accessed: June 30, 2023). DOI: 10.18577/2307-6046-2016-0-10-3-3.
    33. Putyrsky S.V., Arislanov A.A., Yakovlev A.L., Nochovna N.A. Studing of mechanical properties of deformed semi-finished products of VT23M and VT43 alloys, assessment of their climatic stability in the Arctic climate. Trudy VIAM, 2018, no. 4 (64), paper no. 12. Available at: http://www.viam-works.ru (accessed: June 30, 2023). DOI: 10.18577/2307-6046-2018-0-4-101-110.
    34. Polkin I.S., Egorova Yu.B., Davydenko L.V. Modeling the composition and properties of titanium alloys at room and elevated temperatures. Tekhnologiya legkikh splavov, 2021, no. 2, pp. 63–75. DOI: 10/24412/0321-4664-2021-2-63-75.
    35. Kashapov O.S., Pavlova T.V., Kalashnikov V.S., Zavodov A.V. The phenomenon of formation and low-temperature diffusion transformation of metastable solid solutions with the release of dispersed particles of intragranular Widmanstatten alpha phase in heat-resistant titanium. Trudy VIAM, 2018, no. 8 (68), paper no. 01. Available at: http://www.viam-works.ru (accessed: June 30, 2023). DOI: 10.18577/2307-6046-2018-0-8-3-22.
    36. Titov A.B. The influence of heat treatment modes on the microstructure of critical springs made of 60S2A steel and VT16 titanium alloy. Metalloobrabotka, 2015, no. 5 (89), pp. 43–49.
    37. Duyunova V.A., Pavlova T.V., Kashapov O.S., Chuchman O.V. Fatigue strength of forgings from VT6 alloy for parts of gas turbine engines and aircrafts. Aviation materials and technologies, 2023, no. 2 (71), paper no. 02. Available at: http://www.journal.viam.ru (accessed: June 30, 2023). DOI: 10.18577/2713-0193-2023-0-2-23-35.
    38. Salenkov V.A., Zenina M.V., Mochalova O.N. Research on the possibilities of increasing the endurance characteristics of VT6 and VT16 alloys. Tekhnologiya legkikh splavov, 2012, no. 3, pp. 30–34.
    39. Shanyavsky A.A., Nikitin A.L., Palin-Luc T., Bathias C. Scale hierarchy of processes of low-cycle, high-cycle and ultra-high-cycle fatigue fracture of titanium alloy VT3-1. Fizicheskaya mezomekhanika, 2014, no. 4, pp. 59–68.

Full version
4.

DOI: 10.18577/2713-0193-2024-0-1-51-62

UDC: 669.721.5

Pages:: 51-62

E.F. Volkova1, I.V. Mostyaev1, M.V. Akinina1, A.A. Alikhanyan1

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

FEATURES OF THE FORMATION OF THE STRUCTURE IN A THIN SHEET OF MAGNESIUM ALLOY MA2-1 IN THE PROCESS OF DEFORMATION

The article presents the results of a comparative study of the structure and mechanical properties of sheets with a thickness of 2 and 1,2 mm made of the serial magnesium alloy MA2-1, manufactured in the rolling process according to the adopted technology. It was found that the structure of the sheets is fine–grained (4,0–7,2 microns), the phase composition may contain intermetallic phases with an impurity iron in some phases. It is shown that the main geometric parameters of the grains of sheets with a thickness of 2 and 1,2 mm are different. This is a consequence of partial surface hardening of thin sheets with a thickness of 1,2 mm and serves as one of the reasons for a significant increase in the level of their strength properties (σb = 335–420 MPa, σ0,2 ≥ 305 MPa) in a non-heat-treated state.

Keywords: structure, phase composition, magnesium alloy MA2-1, rolled sheets, geometric parameters of grains, partial surface hardening

Reference List

    1. Kablov E.N. New generation materials – the basis of innovation, technological leadership and national security of Russia. Intellekt i tekhnologii, 2016, no. 2 (14), pp. 16–21.
    2. Kablov E.N., Ospennikova O.G., Vershkov A.V. Rare metals and rare-earth elements are materials for modern and future high technologies. Aviacionnye materialy i tehnologii, 2013, no. S2, pp. 3–10.
    3. Petrov A.A., Speransky K.A. Magnesium alloys: prospective industries of application, advantages and disadvantages (review). Part 2. Mechanism of deformation and anisotropy of mechanical properties of magnesium alloys. Trudy VIAM, 2021, no. 11 (105), paper no. 02. Available at: http://www.viam-works.ru (accessed: February 21, 2023). DOI: 10.18577/2307-6046-2021-0-11-12-24.
    4. 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), paper no. 01. Available at: http://www.viam-works.ru (accessed: February 21, 2023). DOI: 10.18577/2307-6046-2021-0-2-3-9.
    5. Magnesium alloys: reference book: in 2 vols. Ed. I.I.Guryev, M.V. Chukhrov. Moscow: Metallurgiya, 1978, vol. 1, 231 p.
    6. Emli E.F. Fundamentals of technology for the production and processing of magnesium alloys. Мoscow: Metallurgiya, 1972, 488 p.
    7. Volkova E.F., Rokhlin L.L., Ovsyannikov B.V. Modern deformable magnesium alloys: state and prospects for use in high-tech industries: textbook. Ed. E.N. Kablov. Moscow: VIAM, 2021, 392 p.
    8. Volkova E.F., Antipov V.V. Magnesium wrought alloys. Vse materialy. Entsiklopedicheskiy spravochnik, 2012, no. 5, pp. 20–26.
    9. Song J., She J., Chen D., Pan F. Latest Research Advances on Magnesium and Magnesium Alloys Worldwide. Journal of Magnesium and Alloys, 2020, vol. 8 (1), pp. 1–41.
    10. Serebryany V.N., Dyakonov G.S., Kharkova M.A., Kopylov V.I., Dobatkin S.V. Study of the Texture and Structure of MA2-1pch Magnesium Alloy Subjected to Equal Channel Angular Pressing and Annealing using X-Ray Quantitative Texture Analysis and Electron Back-Scattered Diffraction ethods. Zavodskaya labiratoriya. Diagnostika matеrialov, 2016, vol. 82 (3), pp. 36–41.
    11. Estrin Y.Z., Zabrodin P.A., Braude I.S., Grigorova T.V., Isaev N.V., Pustovalov V.V., Fomenko V.S., Shumilin S.E. Low-temperature Plastic Deformation of AZ31 Magnesium Alloy with Different Microstructures. Low Temperature Physics, 2010, vol. 36 (12), pp. 1100–1106.
    12. Li Y., Zhang D., Shen W. Microstructure Evolution of AZ31 Magnesium Alloy During Equal Channel Angular Extrusion. Material Science, 2004, vol. 39 (11), pp. 3759–3761.
    13. Kim W.J., Hong S.I., Kim Y.S. Texture Development and its Effect on Mechanical Properties of an AZ61 Mg alloy Fabricated by Equal Channel Angular Pressing. Acta Materialia, 2003, vol. 51, pp. 3293–3307.
    14. Xia K., Wang J.T., Wu X. Equal channel angular pressing of magnesium alloy AZ31. Materials Science and Engineering A, 2005, vol. 410, pp. 324–327.
    15. Kochubey A.Ya., Zhuravleva P.L. X-rays diffractometry application at plotting of structure conditions diagrams of deformable alloys of aviation assignment. Trudy VIAM, 2022, no. 2 (108), paper no. 12. Available at: http://www.viam-works.ru (accessed: February 19, 2023). DOI: 10.18577/2307-6046-2022-0-2-142-152.
    16. An Z., Yan D., Qie J., Lu Z. Effect of Parameters on Formability of a AZ31 Magnesium Alloy Thin-Walled Cylindrical Part Formed by Multistage Warm Single-Point Incremental Forming. Frontiers in Materials, 2020, vol. 7. Available at: http://www.frontiersin.org (accessed: February 21, 2023). DOI: 10.3389/fmats.2020.00151.
    17. Lee Y., Kim S., Yoon E. et al. Productivity on Multi-Stage Forming of Mg Alloy Sheet. Proceedings of the 10th International Conference on Magnesium Alloys and Their Applications Mg 2015, 2015, pp. 750–755.
    18. Gorelova S., Ullmann M., Oswald M., Kawalla R. Effect of Different Finish-Rollig Parameters on the Microstructure and Mechanical Properties of Twin-Roll-Cast (TRC) AZ31 Strips. Key Engineering Materials, 2013, vol. 554–557, pp. 274–279.
    19. Nam A., Prüfert U., Eiermann M., Kawalla R. Numerical Modelling of Thermal Evolution in Hot Strip Rolling of Magnesium Alloy. Key Engineering Materials, 2015, vol. 651–653, pp. 207–212.
    20. Petrov A.A., Speransky K.A. Magnesium alloys: prospective industries of application, advantages and disadvantages (review). Part 1. Application in medicine. Crystallographic factors affecting the corrosion resistance of magnesium alloys. Trudy VIAM, 2021, no. 10 (104), paper no. 02. Available at: http://www.viam-works.ru (accessed: February 19, 2023). DOI: 10.18577/2307-6046-2021-0-10-12-27.
    21. 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.
    22. Volkova E.F. The influence of iron impurities on the phase composition, structure and properties of magnesium alloys containing manganese and aluminum. Metallovedenie i termicheskaya obrabotka metallov, 2017, no. 3, pp. 23–29.
    23. Gulyaev A.P. Metallurgy. 6th ed., rev. and add. Moscow: Metallurgiya, 1986, 544 p.

Full version
5.

DOI: 10.18577/2713-0193-2024-0-1-63-77

UDC: 678.067.5

Pages:: 63-77

Yu.V. Reshetnikov1, A.V. Trapeznikov1, K.A. Vlasova1, A.A. Leonov1

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

DIFFERENT FACTORS INFLUENCE ON TECHNOLOGICAL PROPERTIES OF SELF-HARDENING PHENOL FORMALDEHYDE RESIN SANDS. Part 1

The first part of the article summarizes the research on the properties of sand fillers for molding sands. The mechanism of formation of the strength of self-hardening mixtures is described. The influence of the types of molding sands (quartz, chromite, zircon, bauxite and synthetic), as well as the shape and size of sand grains on the characteristics of the mixture, is shown. Common methods for determining the flowability of sands are given. The influence of surfactants on the viscosity of the binder, as well as small additions of micro- and nanosized particles on the kinematics of the sand, is described.

Keywords: alpha-set, sand, self-hardening sands, chemical bonded sands, cold hardening sands, phenol formaldehyde resins

Reference List

    1. Kablov E.N. The present and future of additive technologies. Metally Evrazii, 2017, no. 1, pp. 2–6.
    2. Kablov E.N. Dominant of the national technological initiative. Problems of accelerating the development of additive technologies in Russia. Metally Evrazii, 2017, no. 3. pp. 2–6.
    3. Tokarev M.S., Trofimov N.V., Leonov A.A., Alikhanyan A.A. Methods additive manufacturing of magnesium alloys (review). Trudy VIAM, 2021, no. 6 (100), paper no. 01. Available at: http://www.viam-works.ru (accessed: May 05, 2023). DOI: 10.18577/2307-6046-2021-0-6-3-16.
    4. Uridiya Z.P., Tokarev M.S., Leonov A.A., Trofimov N.V. Trends in the development of modern manufacturing technologies and methods for improving the surface properties of magnesium alloys (review). Trudy VIAM, 2022, no. 11 (117), paper no. 04. Available at: http://www.viam-works.ru (accessed: May 05, 2023). DOI: 10.18577/2307-6046-2022-0-11-37-47.
    5. Lopatin A.N., Zverkov I.D. Shaping molding tools production for composite parts by means of additive technologies. Aviacionnye materialy i tehnologii, 2019, no. 2 (55), pp. 53–59. DOI: 10.18577/2071-9140-2019-0-2-53-59.
    6. Shchetinina N.D., Kuznetsova P.E., Dynin N.V., Selivanov A.A. Aluminum alloys with additions of Sc and Zr in additive manufacturing (review) Aviation materials and technologies, 2021, no. 3 (64), paper no. 03. Available at: http://www.journal.viam.ru (accessed: May 05, 2023). DOI: 10.18577/2713-0193-2021-0-3-19-34.
    7. Hasbrouck C.R., Fisher J.W., Villalpando M.R., Lynch P.C. A Comparative Study of Dimensional Tolerancing Capabilities and Microstructure Formation between Binder Jet Additively Manufactured Sand Molds and Olivine Green Sand Molds for Metalcasting of A356.0. Procedia Manufacturing, 2020, vol. 48, pp. 338–348. DOI: 10.1016/j.promfg.2020.05.056.
    8. Foundry technology: molding and core mixtures: textbook. manual for universities. Ed. S.S. Zhukovsky, A.N. Boldina, A.I. Yakovleva et al. Bryansk: BSTU Publ. House, 2002, 470 p.
    9. Holtzer M., Kmita А. Mold and Core Sands in Metalcasting: Chemistry and Ecology. Springer Nature Switzerland AG, 2020, 359 p. DOI: 10.1007/978-3-030-53210-9.
    10. Brown J.R. Foseco ferrous foundryman’s handbook. 11th ed. Woburn: Foseco International, 2000, 360 р. DOI: 10.1016/B978-0-7506-4284-2.X5000-5.
    11. Campbell J. Complete casting handbook. Elsevier, 2011, 1054 р.
    12. Bargaoui H., Azzouz F., Thibault D., Cailletaud G. Thermomechanical behavior of resin bonded foundry sand cores during casting. Journal of Materials Processing Tech., 2017, vol. 246, pp. 1–26. DOI: 10.1016/j.jmatprotec.2017.03.002.
    13. Giese S.R., Roorda S.C., Patersson M.A. Thermal analysis of phenolic urethane binder and correlated properties. American Foundry Society Transactions, 2009, vol. 102, pp. 355–366.
    14. Thiel J. Thermal expansion of chemically bonded silica sand. American Foundry Society Transactions, 2011, vol. 116, pp. 369–378.
    15. Khandelwal H., Ravi B. Effect of binder composition on the shrinkage of chemically bonded sand cores. Journal of Materials and Manufacturing Processes, 2015, vol. 30, рр. 1465–1470.
    16. Resin Systems Overview. Available at: www.ha-international.com/products/resins (accessed: May 05, 2023).
    17. Trinowski D.M. Comparing molding and core making trends in the U.S. and EU casting industries. Hüttenes-Albertus Chemische Werke GmbH, 2016, pp. 1–13.
    18. Mansour M. Develop A Strategic Forecast of Silica Sand Based on Supply Chain Decomposition. International Journal of Engineering, 2015, vol. 9, is. 1, pp. 9–27.
    19. Lewandowski J.L. Materials for foundry molds. Cracow: AKAPIT, 1997, 598 p.
    20. Haanappel V. Methods to Determine, Influence and Improve the Flowability of Sand Mixtures. Casting Processes. IntechOpen, 2022, 20 р. DOI: 10.5772/intechopen.102017.
    21. Scott W.D., Thomas E.M., Strohmayer L.L. Quality issues in the selection of chromite sand for steel foundry use. American Foundry Society Transactions, 2003, vol. 111, pp. 517–527.
    22. Anwar N., Sappinen T., Jalava K., Orkas J. Comparative experimental study of sand and binder for flowability and casting mold quality. Advanced Powder Technology, 2021 vol. 32, pp. 1902–1910. DOI: 10.1016/j.apt.2021.03.040.
    23. Prescott J.K., Barnum R.A. On powder flowability. Pharmaceutical Technology, 2000, vol. 24 (10), pp. 60–84.
    24. Schulze D. Flow properties of powders and bulk solids: Behavior, Characterization, Storage and Flow. Springer Nature Switzerland AG, 2021, 625 р. DOI: 10.1007/978-3-030-76720-4.
    25. Hausner H.H. Friction Conditions in a Mass of Metal Powder. International Journal of Powder Metallurgy, 1967, vol. 3, pp. 7–13.
    26. Beakawi Al-Hashemi H.M., Baghabra Al-Amoudi O.S. A review on the angle of repose of granular materials. Powder Technology, 2018, vol. 330, pp. 397–417. DOI: 10.1016/j.powtec.2018.02.003.
    27. Vock S., Klöden B., Kirchner A. et al. Powders for powder bed fusion: a review. Progress in Additive Manufacturing, 2019, vol. 4, pp. 383–397. DOI: 10.1007/s40964-019-00078-6.
    28. Sutton A.T., Kriewall C.S., Leu M.C., Newkirk J.W. Powder characterisation techniques and effects of powder characteristics on part properties in powder-bed fusion processes. Virtual and Physical Prototyping, 2017, vol. 12 (1), pp. 1–27. DOI: 10.1080/17452759.2016.1250605.

Full version
6.

DOI: 10.18577/2713-0193-2024-0-1-

UDC: 541.182

Pages:: 78-88

A.V. Istomin1

[1] Federal State Unitary Enterprise «All-Russian Scientific Research Institute of Aviation Materials»

STUDY OF THE DISTRIBUTION OF ALUMINUM OXIDE NANOPOWDER IN A POLYMER SOLUTION

In this work, aluminum oxide nanopowder was studied. The phase composition of the studied powder was determined, the only phase being tetragonal alumina. The morphology of the particles has been studied. A method for ultrasonic treatment of aqueous suspensions of aluminum oxide has been developed. The hydrodynamic radius of the particles after sonication was less than 80 nm. Sterically stabilized aluminum oxide nanoparticles have been obtained and studied. It is shown that with an increase in the content of the stabilizer, the particle size increases to 500 nm. The particle size was estimated by the method of static and dynamic scattering.

Keywords: aluminum oxide, corundum, suspension, colloidal solution, sol, nanoparticle, ultrasonic treatment

Reference List

    1. Rassokhina L.I., Bityutskaya O.N., Gamazina M.V., Kochetkov A.S. Features of the manufacturing technology of highly refractory ceramic molds for castings from γ-TiAl alloys. Trudy VIAM, 2020, no. 2 (86), paper no. 04. Available at: http://www.viam-works.ru (accessed: February 08, 2023). DOI: 10.18577/2307-6046-2020-0-2-31-40.
    2. Bauxites. Mining Encyclopedia: in 5 vols. Ed. E.A. Kozlovsky. Moscow: Bolshaya sovetskaya entsiklopediya, 1984, vol. 1, pp. 254–256.
    3. Bobkova N.M. Physical chemistry of refractory nonmetallic and silicate materials. Minsk: Nauka i tekhnika, 2007, 301 p.
    4. Istomin A.V., Kolyshev S.G. Electrostatic method of forming ultrathin fibers of refractory oxides. Aviacionnye materialy i tehnologii, 2019, no. 2 (55), pp. 40–46. DOI: 10.18577/2071-9140-2019-0-2-40-46.
    5. Kotov Yu.A. Electric Explosion of Wires as a Method for Preparation of Nanopowders. Journal Nanoparticle Research, 2003, vol. 5, no. 5–6, pp. 539–550.
    6. Method for producing aluminum oxide powder: pat. RU 2113318 C1; appl. 06.01.97; publ. 20.06.98.
    7. Method for producing nanodispersed aluminum oxide powder: pat. RU 2353584 С2; appl. 19.02.07; publ. 27.04.09.
    8. Matveev A.T., Afanasov I.M. Preparation of nanofibers by electrospinning: textbook. Moscow: Lomonosov Moscow State University, 2010, 83 p.
    9. Vityaz P.A. Functional materials based on nanostructured aluminum hydroxide powders. Minsk: Belorusskaya nauka, 2010, 184 p.
    10. Berti D., Palazzo G. Colloidal Foundations of Nanoscience. Amsterdam: Elsevier, 2014. 288 p.
    11. Shabanova N.A., Popov V.V., Sarkisov P.D. Chemistry and technology of nanodispersed oxides: textbook. Moscow: Akademkniga, 2006, 309 p.
    12. Guozhong C., Wang Y. Nanostructures and nanomaterials. Synthesis, properties and application. Moscow: Nauchnyy mir, 2012, 520 p.
    13. Chukin G.D. Structure of aluminum oxide and hydrodesulfurization catalysts. Mechanisms of reactions. Moscow: Tipografiya Paladin; Printa, 2010, 288 p.
    14. Boguslavsky L.I. Methods for producing nanoparticles and their size-sensitive physical parameters. Bulletin of MITKhT, 2010, vol. 5, no. 5, pp. 3–12
    15. Petrova E.V., Dresvyannikov A.F., Tsyganova M.A. Nano-sized particles of aluminum hydroxides and oxides obtained by electrochemical and chemical methods. Vestnik Kazanskogo tekhnologicheskogo universiteta, 2008, no. 5, pp. 301–310.
    16. Maksimov A.I., Moshnikov V.A., Tairov Yu.M., Shilova O.A. Fundamentals of sol-gel technology of nanocomposites. St. Petersburg: LETI, 2007, 273 p.
    17. Saruhan B. Oxide-Based Fiber-Reinforced Ceramic-Matrix Composites. New-York: Springer, 2003, 199 p.
    18. Balinova Yu.A., Kirienko T.A. Continuous high-temperature oxide fibers for heat-shielding, heat-insulating and composite materials. Vse materialy. Entsiklopedicheskiy spravochnik, 2012, no. 4, pp. 24–29.
    19. Wang B., Yanc R., Lee D.H. et al. Characterization and evaluation of Fe2O3/Al2O3 oxygen carrier prepared by sol–gel combustion synthesis. Journal of Analytical and Applied Pyrolysis, 2011, vol. 91, pp. 105–113.
    20. Mei D., Abad A., Zhao H. et al. On a Highly Reactive Fe2O3/Al2O3 Oxygen Carrier for in Situ Gasification Chemical Looping Combustion. Energy Fuels, 2014, vol. 28, no. 11, pp. 7043–7052.
    21. Baca L., Lipka J., Toth I., Pach L. Study of crystallisation of Al2O3‒Fe2O3 gels by Mossbauer spectroscopy. Ceramics-Silikaty, 2001, vol. 45, no. 1, pp. 9–14.
    22. Kakos J., Baca L., Veis P., Pach L. Photoluminescence Spectra and Crystallization of ζ-Al2O3 and α-Al2O3 from AlOOHFe(NO3)3 Gels. Journal of Sol-Gel Science and Technology, 2001, vol. 21, pp. 167–172.
    23. Kosmulski M. Chemical properties of material surfaces. New-York: Marcel Dekker, 2001, 576 р.
    24. Liang Y., Hilal N., Langston P., Starov V. Interaction forces between colloidal particles in liquid: Theory and experiment. Advances in colloid and interface science, 2007, vol. 134–135, no. 31, pp. 151–166.
    25. 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.
    26. Kablov E.N., Shchetanov B.V., Ivakhnenko Yu.A. Preparation, structure and strength of Al2O3 fibers. Works Int. conf. «Theory and practice of technologies for the production of products from composite materials and new metal alloys». Moscow: Znanie, 2004, pp. 258–260.
    27. Voronov V.A., Chaynikova A.S., Tkalenko D.M. Aspects of usage of organic or aqueous binders based on III or IV group elements oxides in the production of ceramic molds for chemically active alloys casting (review). Aviation materials and technologies, 2021, no. 2 (63), paper no. 08. Available at: http://www.journal.viam.ru (accessed: February 20, 2023). DOI: 10.18577/2713-0193-2021-0-2-73-84.
    28. 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), paper no. 05. Available at: http://www.viam-works.ru (accessed: February 20, 2023). DOI: 10.18577/2307-6046-2021-0-4-61-73.
    29. 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), paper no. 02. Available at: http://www.journal.viam.ru (accessed: February 20, 2023). DOI: 10.18577/2713-0193-2021-0-4-14-25.
    30. Shklyar T.F., Toropova O.A., Safronov A.P. et al. Acoustic properties of aqueous suspensions of metal oxides. Rossiyskie nanotekhnologii, 2010, vol. 5, no. 3–4, pp. 24–30.
    31. Luzgin V.I., Shestovskikh A.E., Kandalintsev B.A. Ultrasonic equipment and methods for producing nanodispersed emulsions and suspensions. Promyshlennaya energetika, 2015, no. 7, pp. 21–26.
    32. Istomin A.V., Demina T.S., Subcheva E.N. et al. Nanocrystalline cellulose from flax trust: preparation, structure and application. Khimicheskiye volokna, 2016, no. 2, pp. 22.

Full version
7.

DOI: 10.18577/2713-0193-2024-0-1-89-100

UDC: 678/83

Pages:: 89-100

G.F. Zhelezina1, G.S. Kulagina1, A.I. Sidorina1, N.A. Soloveva1

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

FATIGUE OF CONSTRUCTIONAL ORGANOPLASTICS

An analysis of experimental studies of the fatigue strength of structural organoplastics for aviation purposes has been carried out. The relationship between the fatigue and static strength of organoplastics has been studied. It has been established that with an increase in the tensile strength, a significant increase in the resistance of organoplastics to dynamic loads is observed. The influence of the reinforcement scheme, the type of polymer matrix, and the chemical nature of aramid fiber on the fatigue strength of organoplastics is shown. In terms of tensile fatigue strength, structural aramid organoplastics occupy an intermediate position between carbon and fiberglass plastics.

Keywords: fatigue durability, polymeric composite material, aramide organoplasty, polymeric matrix, reinforcing scheme

Reference List

    1. Kablov E.N. New generation materials and digital technologies for their processing. Vestnik Rossiyskoy akademii nauk, 2020, vol. 90, no. 4, pp. 331–334.
    2. Strizhius V.E. Methods and procedures for fatigue calculations of aircraft structural elements. Moscow: MAI-PRINT, 2008, 58 p.
    3. Fatigue of aircraft structures. Ed. I.I. Eskin. Moscow: Oborongiz, 1961, 501 p.
    4. Terentyev V.F. Fatigue of metal materials. Moscow: Nauka, 2003, 254 p.
    5. Serpova V.M., Sidorov D.V., Kurbatkina E.I., Shavnev A.A. The destruction of the fibrous metal matrix composites system Ti–SiC under cyclic loads (review). Trudy VIAM, 2020, no. 4–5 (88), paper no. 12. Available at: http://www.viam-works.ru (accessed: November 28, 2022). DOI: 10.18577/2307-6046-2020-0-45-108-118.
    6. Kalashnikov V.S., Reshetilo L.P., Chuchman O.V., Naprienko S.A. Strength and reliability of rods and rotor blade stamps made of heat-resistant industrial titanium alloys and modern pseudo-α-titanium alloy. Trudy VIAM, 2022, no. 2 (108), paper no. 02. Available at: http://www.viam-works.ru (accessed: November 28, 2022). DOI: 10.18577/2307-6046-2022-0-2-13-31.
    7. Erasov V.S., Nuzhnyj G.A., Grinevich A.V., Terehin A.L. Crack growth resistance of aviation materials in fatigue testing. Trudy VIAM, 2013, no. 10, paper no. 06. Available at: http://www.viam-works.ru (accessed: November 28, 2022).
    8. Panin V.E., Kablov E.N., Pochivalov Yu.I., Panin S.V., Kolobnev N.I. The influence of nanostructuring of the surface layer of aluminum-lithium alloy 1424 on deformation mechanisms, technological characteristics and fatigue life. Increasing plasticity and technological characteristics. Fizicheskaya mezomekhanika, 2012, vol. 15, no. 6, pp. 107–111.
    9. Grinevich A.V., Rumyancev Yu.S., Morozova L.V., Terehin A.L. Study of fatigue life of 1163-T and V95o.ch.-T2 aluminum alloys after surface hardening. Aviacionnye materialy i tehnologii, 2014, no. S4, pp. 93–102. DOI: 10.18577/2071-9140-2014-s4-93-102.
    10. Mashinskaya G.P., Zhelezina G.F., Senatorova O.G. Laminated Fibrous Metal – Polymer Composites. Metal Matrix Composites. Soviet Advanced Composites Technology Series, 1995, vol. 3, pp. 487–570.
    11. Podzhivotov N.Y., Kablov E.N., Antipov V.V. et al. Laminated Metal-Polymeric Materials in Structural Elements of Aircraft. Inorganic Materials: Applied Research, 2017, vol. 8, no. 2, pp. 211–221.
    12. Kablov E.N., Antipov V.V., Klochkova Yu.Yu. New generation aluminum-lithium alloys and layered aluminum-fiberglass plastics based on them. Tsvetnye metally, 2016, no. 8 (884), pp. 86–91. DOI: 10.17580/tsm.2016.08.13.
    13. Podzhivotov N.Yu., Kablov E.N., Antipov V.V. et al. Layered metal-polymer materials in aircraft design elements. Perspektivnyye materialy, 2016, no. 10, pp. 5–19.
    14. Antipov V.V., Kotova E.V., Serebrennikova N.Yu., Petrova A.P. Glue binders and glue prepregs for alumopolymeric composite materials. Trudy VIAM, 2018, no. 5 (65), paper no. 06. Available at: http://www.viam-works.ru (accessed: November 28, 2022). DOI: 10.18577/2307-6046-2018-0-5-44-54.
    15. Antipov V.V., Serebrennikova N.Yu., Shestov V.V., Sidelnikov V.V. Laminated hybrid materials on basis of Al–Li alloy sheets. Aviacionnye materialy i tehnologii, 2017, no. S, pp. 212–224. DOI: 10.18577/2071-9140-2017-0-S-212-224.
    16. Grinevich D.V., Yakovlev N.O., Slavin A.V. The criteria of the failure of polymer matrix composites (review). Trudy VIAM, 2019, no. 7 (79), paper no. 11. Available at: http://viam-works.ru (accessed: November 28, 2022). DOI: 10.18577/2307-6046-2019-0-7-92-111.
    17. Harutyunyan A.R. Criterion for fatigue strength of composite materials. Doklady akademii nauk, 2019, vol. 488, no. 5, pp. 488–492.
    18. Fujii T., Dzako M. Fracture mechanics of composite materials. Moscow: Mir, 1982, 232 p.
    19. Mukhametov R.R., Petrova A.P. Thermosetting binders for polymer composite materials. Ed. E.N. Kablov. Moscow: National Research Center «Kurchatov Institute» – VIAM, 2021, 528 p.
    20. Romanov A.N. The problem of materials science in the mechanics of deformation and fracture at the stage of crack formation. Part 5. Energy of static and cyclic destruction of structural metal materials. Vestnik nauchno-tekhnicheskogo razvitiya, 2014, no. 9, pp. 10–30.
    21. Ratner S.I. Failure under repeated loads. Moscow: Oborongiz, 1959, 352 p.
    22. Deev I.S., Zhelezina G.F. Fractographic analysis of the layered metal-polymer composite Alor after testing for crack resistance. Kompozity i nanostruktury, 2015, vol. 7, no. 3, pp. 162–176.
    23. Petrova A.P., Mukhametov R.R., Shishimirov M.V., Pavlyuk B.Ph., Starostina I.V. Test methods and researches thermosetting binding for polymeric composite materials (review). Trudy VIAM, 2018, no. 12 (72), paper no. 07. Available at: http://viam-works.ru (accessed: November 28, 2022). DOI: 10.18577/2307-6046-2018-0-12-62-70.
    24. Zhelezina G.F., Kulagina G.S., Kolobkov A.S., Shuldeshova P.M. Aramid organoplastics with increased resistance to climatic factors. Voprosy materialovedeniya, 2022, no. 3 (111), pp. 67–78. DOI: 10.22349/1994-6716-2022-111-3-67-78.
    25. Zhelezina G.F., Tikhonov I.V., Chernykh T.E., Bova V.G., Voinov S.I. Third generation aramid fibers Rusar NT for reinforcing organotextolites for aviation purposes. Plasticheskiye massy, 2019, no. 3–4, pp. 43–47.

Full version
8.

DOI: 10.18577/2713-0193-2024-0-1-101-110

UDC: 620.197

Pages:: 101-110

S.A. Budinovskiy1, D.S. Gorlov1, A.S. Benklyan1

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

DEPOSITION OF PROTECTIVE ION-PLASMA COATINGS ON LARGE-SCALE PARTS ON MAP TYPE INSTALLATIONS

The results of studies on the possibility of applying ion-plasma coatings to large-sized parts using commercially produced cylindrical cathodes for MAP-type installations are presented. It has been shown that the application of coatings to parts up to 250 mm high on a modernized MAP-2 installation using a cathode made of SDP-2 alloy can be implemented by replacing the cylindrical cathode spot retainer with an elliptical shaped retainer. The maximum rate of deposition of coatings from the SDP-2 alloy was more than 10 µm/h.

Keywords: ion plasma technology, protective coatings, vacuum arc discharge, cathode spot, large parts, MAP type installation, tube cathode

Reference List

    1. Kablov E.N. Science as a branch of the economy. Nauka i zhizn, 2009, no. 10, pp. 6–10.
    2. Kablov E.N., Muboyadzhyan S.A. Erosion-resistant coatings for compressor blades of gas turbine engines. Electrometallurgiya, 2016, no. 10, pp. 23–38.
    3. Kablov E.N., Muboyadzhyan S.A. Heat-protective coatings with a ceramic layer of reduced thermal conductivity based on zirconium oxide for high-pressure turbine blades of advanced gas turbine engines. Collection of articles. report conf. «Modern achievements in the field of creating promising non-metallic composite materials and coatings for aviation and space technology». Moscow: VIAM, 2015, p. 3.
    4. Aleksandrov D.A., Muboyadzhyan S.A., Zhuravleva P.L., Gorlov D.S. Investigation of the effect of surface preparation and ion-assisted deposition on the structure and properties of erosion-resistant ion-plasma coating. Trudy VIAM, 2018, no. 10 (70), paper no. 08. Available at: http://www.viam-works.ru (accessed: January 20, 2023). DOI: 10.18577/2307-6046-2018-0-10-62-73.
    5. Dobrynin D.A., Pavlova T.V., Afanasyev-Khodykin A.N., Alekseeva M.S. The use of electrolytic-plasma treatment for repair of GTE blades. Trudy VIAM, 2019, no. 8 (80), paper no. 03. Available at: http://www.viam-works.ru (accessed: January 19, 2023). DOI: 10.18577/2307-6046-2019-0-8-18-26.
    6. Muboyadzhyan S.A. Protective coatings for parts of the hot path of gas turbine engines. Vse materialy. Entsiklopedicheskiy spravochnik, 2011, no. 3, pp. 26–30.
    7. Muboyadzhyan S.A., Budinovskij S.A. Ion-plasma technology: prospective processes, coatings, equipment. Aviacionnye materialy i tehnologii, 2017, no. S, pp. 39–54. DOI: 10.18577/2071-9140-2017-0-S-39-54.
    8. Muboyadzhyan S.A., Lutsenko A.N., Aleksandrov D.A., Gorlov D.S. Research of possibility of increase of office characteristics of compressor blades of GTE by method of ionic modifying of surface. Trudy VIAM, 2013, no. 1, paper no. 02. Available at: http://viam-works.ru (accessed: January 20, 2023).
    9. Aleksandrov D.A., Artemenko N.I. Wear-resistant coatings to protect friction parts of modern gas turbine engines. Trudy VIAM, 2016, no. 10, paper no. 6. Available at: http://www.viam-works.ru (accessed: January 11, 2023). DOI: 10.18577/2307-6046-2016-0-10-6-6.
    10. Method of applying protective coatings and a device for its implementation: pat. 2625698 Rus. Federation. No. 2016135082; appl. 29.08.16; publ. 18.07.17.
    11. Muboyadzhyan S.A. Industrial ion-plasma equipment for applying protective coatings. Entsiklopediya inzhenera-khimika, 2012, no. 5, pp. 34–41
    12. Iatsyuk I.V., Doronin O.N., Kuko I.S. Secondary processing of cast tube cathodes when obtaining a metal powder composition for the gas-thermal spray of coatings. Trudy VIAM, 2021, no. 2 (96), paper no. 09. Available at: http://www.viam-works.ru (accessed: January 19, 2023). DOI: 10.18577/2307-6046-2021-0-2-81-87.
    13. Dobrynin D.A., Alekseeva M.S., Afanasyev-Khodykin A.N. Repair of nozzle blades made of heat-resistant nickel alloy ZhS6U. Trudy VIAM, 2021, no. 5 (99), paper no. 01. Available at: http://www.viam-works.ru (accessed: January 19, 2023). DOI: 10.18577/2307-6046-2021-0-5-3-13.
    14. Madaeva A.D., Umarova M.Kh., Dzhamalueva A.A. Prospects for gas turbines in Russian energy. Zametki uchenogo, 2020, no. 3, pp. 84–86.
    15. Demchishin A.V., Demchishin A.A., Michenko V.A. Vacuum-arc installation for applying functional coatings. Sovremennaya elektrometallurgiya, 2019, no. 3, pp. 23–27.
    16. Smyslov A.M., Mingazhev A.D., Selivanov K.S. et al. Ion-plasma technology for forming coatings on gas turbine engine blades from heat-resistant nickel alloys. Vestnik UGATU, 2012, vol. 16, no. 1 (46), pp. 77–80.
    17. Budinovsky S.A., Muboyadzhyan S.A., Lyapin A.A., Benklyan A.S. Development of a magnetic system for stabilizing an extended evaporation zone on the cathode of a vacuum arc discharge of ion-plasma installations of the MAP type. Electrometallurgiya. 2021, no. 4, pp. 21–29.

Full version
9.

DOI: 10.18577/2713-0193-2024-0-1-111-120

UDC: 620.179.119

Pages:: 111-120

I.S. Lednev1

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

MAGNETIC METHODS OF NON-DESTRUCTIVE TESTING OF AIRCRAFT PARTS

The main methods of magnetic non-destructive testing of semi-finished products, parts and samples of aircraft materials are considered. The possibilities of magnetic methods and the discontinuities sought with their help, depending on the purpose of testing, are presented. The main problems of magnetic particle testing are presented and ways to solve them are proposed. The prospects for the development of non-destructive testing methods are analyzed. In conclusion, the implemented works of the NRC “Kurchatov institute” – VIAM in the direction of the development of magnetic methods of non-destructive testing is presented.

Keywords: magnetic non-destructive testing, magnetic particle testing, discontinuities, aviation production, testing equipment

Reference List

    1. Kablov E.N. Main directions of development of materials for aerospace technology of the XXI century. Perspektivnye materialy, 2000, no. 3, pp. 27–36.
    2. Kablov E.N. VIAM: new generation materials for PD-14. Krylya Rodiny, 2019, no. 7–8, pp. 54–58.
    3. Kablov E.N. Formation of domestic space materials science. Vestnik RFFI, 2017, no. 3, pp. 97–105.
    4. Kablov E.N. Materials for all times. Nauka i zhizn, 2010, no. 10, pp. 12–19.
    5. Kosarina E.I., Mikhailova N.A., Demidov A.A., Smirnov A.V. Image quality indicators in radiation monitoring according to ISO regulations. Trudy VIAM, 2019, no. 6 (78), paper no. 12. Available at: http://viam-works.ru (accessed: December 13, 2022). DOI: 10.18577/2307-6046-2019-0-6-114-127.
    6. Demidov A.A., Krupnina O.A., Mikhaylova N.A., Kosarina E.I. Investigation of polymer composite material samples by x-ray computed tomography and processing of tomograms with the image of the volume fraction of porosity. Trudy VIAM, 2021, no. 5 (99), paper no. 11. Available at: http://www.viam-works.ru (accessed: December 13, 2022). DOI: 10.18577/2307-6046-2021-0-5-105-113.
    7. Slavin A.V., Demidov A.A., Kosarina E.I., Suvorov P.V. Definition of factors of weakening of x-ray emission with the broad range of energy polymeric composite material. Trudy VIAM, 2022, no. 5 (111), paper no. 05. Available at: http://www.viam-works.ru (accessed: December 13, 2022). DOI: 10.18577/2307-6046-2022-0-5-53-63.
    8. Boychuk A.S., Dikov I.A., Generalov A.S., Yakovleva S.I. The features of non-destructive inspection of carbon fiber rein-forced plastic solid laminate samples during low-cyclic fatigue testing. Trudy VIAM, 2020, no. 12 (94), paper no. 12. Available at: http://www.viam-works.ru (accessed: December 13, 2022). DOI: 10.18577/2307-6046-2020-0-12-108-115.
    9. Boychuk A.S., Dikov I.A., Generalov A.S. Estimation of impact damages area in FRP by various ultrasonic techniques. Trudy VIAM, 2022, no. 7 (113), paper no. 11. Available at: http://www.viam-works.ru (accessed: December 13, 2022). DOI: 10.18577/2307-6046-2022-0-7-125-133.
    10. SDANK-01-2020. Certification rules and basic requirements for non-destructive testing laboratories. Available at: https://ntcexpert.ru/documents/sdank-01-2020.pdf ru (accessed: December 13, 2022).
    11. Kozlov V.V. Verification of non-destructive testing means. Moscow: Publ. house of standards, 1989, 215 p.
    12. State Standard 21105–87. Non-destructive testing. Magnetic particle method. Moscow: Publ. house of standards, 2003, 14 p.
    13. ISO 9934-1. Non-destructive testing. Magnetic particle testing. Part 1: General principles. Geneva: ISO, 2001, 14 p.
    14. DIN EN 1369–2013. Founding – Magnetic particle testing. Deutsches Institut für Normung e.V., 2013, 26 р.
    15. ASTM E1444/E1444M. Standard Practice for Magnetic Particle Testing for Aerospace. ASTM International (ASTM), 2022, 16 р.
    16. ASTM E709-21. Standard Guide for Magnetic Particle Testing. ASTM International (ASTM), 2021, 48 р.
    17. Mariani S., Rendu Q., Urbani M., Sbarufatti C. Causal dilated convolutional neural networks for automatic inspection of ultrasonic signals in non-destructive evaluation and structural health monitoring. Mechanical Systems and Signal Processing. Elsevier, 2021, 21 р. DOI: 10.1016/j.ymssp.2021.107748.
    18. Rawat W., Wang Z. Deep Convolutional Neural Networks for Image Classification: A Comprehensive Review. Neural Computation, 2017, vol. 29, no. 9, pp. 2352–2449. DOI: 10.1162/neco_a_00990.
    19. Tout K., Meguenani A., Urban J.P. et al. Automated vision system for magnetic particle inspection of crankshafts using convolutional neural networks. The International Journal of Advanced Manufacturing Technology, 2021, vol. 112, pp. 3307–3326. DOI: 10.1007/s00170-020-06467-4.
    20. Link R., Riess N. NDT 4.0-significance and implications to NDT-automated magnetic particle testing as an example. 12th European Conference on Non-Destructive Testing (ECNDT 2018). 2018, vol. 15, p. 6.
    21. Antonio S., Fulginei F., Faba A. et al. Vector Hysteresis Processes for Innovative Fe-Si Magnetic Powder Cores: Experiments and Neural Network Modeling. Magnetochemistry, 2021, vol. 7, no. 2, p. 18. DOI: 10.3390/magnetochemistry7020018.
    22. Ferguson M., Ak R., Lee Y.-T.T., Law K.H. Automatic localization of casting defects with convolutional neural networks. IEEE international conference on big data (big data), 2017, pp. 1726–1735.
    23. Chen Y., Feng B., Kang Y. A novel thermography-based dry magnetic particle testing method. IEEE Transactions on Instrumentation and Measurement, 2022, vol. 71, pp. 1–9. DOI: 10.1109/TIM.2022.3165742.
    24. Wong B.S., Low Y.G., Wang X. et al. 3D finite element simulation of magnetic particle inspection. IEEE Conference on Sustainable Utilization and Development in Engineering and Technology, 2010, pp. 50–55.
    25. Zolfaghari A., Zolfaghari A., Kolahan F. Reliability and sensitivity of magnetic particle nondestructive testing in detecting the surface cracks of welded components. Nondestructive Testing and Evaluation, 2018, vol. 33, no. 3, pp. 290–300. DOI: 10.1080/10589759.2018.1428322.
    26. Apostol E.S., Nedelcu A., Tănase N. et al. Mathematical modeling of eddy current non-destructive testing. 10th International Symposium on Advanced Topics in Electrical Engineering (ATEE), 2017, pp. 469–474. DOI: 10.1109/ATEE.2017.7905088.

Full version
10.

DOI: 10.18577/2713-0193-2024-0-1-121-135

UDC: 66.017

Pages:: 121-135

A.I. Sutubalov1, N.Yu. Podzhivotov1, P.V. Shershak1, N.O. Yakovlev1

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

EVALUATION OF HOMOGENEITY OF PHYSICAL AND MECHANICAL PROPERTIES OF SEMI-FINISHED PRODUCTS FOR AVIATION PURPOSE

The application of statistical criteria for evaluating the homogeneity of mechanical properties over the area of material semi-finished product is considered. The advantages and disadvantages of using the considered criteria and their impact on the evaluating of homogeneity are shown. The evaluating of the material homogeneity of the property levels was carried out based on the results of mechanical tests of standard samples made of aluminum alloy sheet 1163 and fiberglass plate of the VPS-36 brand. An algorithm of stratified sampling is proposed to evaluate the homogeneity of mechanical properties over the area of the semi-finished product.

Keywords: material, semi-finished product, homogeneity, physical and mechanical properties, homogeneity assessment criteria, parametric criterion, non-parametric criterion, stratified sampling

Reference List

    1. Kablov E.N. Quality control of materials is a guarantee of safe operation of aviation equipment. Aviaсionnye materialy i tehnologii, 2001, no. 1, pp. 3–8.
    2. Kablov E.N. Materials for aerospace technology. Vse materialy. Entsiklopedicheskiy spravochnik, 2007, no. 5, pp. 7–27.
    3. Erasov V.S. Modern methods for assessing the physical and mechanical properties of materials. Collection of articles All-Rus conf. on testing and research of materials properties «TestMat-2012». Moscow, 2012, p. 13.
    4. Karachevtsev F.N., Eroshkin S.G., Gorbovets M.A. Development of the production of standard samples of the composition of alloys at the National Research Center «Kurchatov Institute» – VIAM. Trudy VIAM, 2022, no. 10 (116), paper no. 12. Available at: http://www.viam-works.ru (accessed: January 17, 2023). DOI: 10.18577/2307-6046-2022-0-10-140-148.
    5. Shershak P.V., Yakovlev N.O., Gulina I.V., Demchenko A.S. Features of conducting interlaboratory comparative physical and mechanical tests. Collection of report XIV All-Rus. conf. on testing and research of material properties «TestMat-2022». Moscow, 2022, pp. 333–348.
    6. Orlov A.I. Applied statistics. Moscow: Ekzamen, 2004, 656 p.
    7. Kobzar A.I. Applied mathematical statistics. For engineers and scientists. Moscow: Fizmatlit, 2006, 816 p.
    8. Podzhivotov N.Yu. Assessment of results by means of the analysis of variance method. Trudy VIAM, 2022, no. 8 (114), paper no. 12. Available at: http://www.viam-works.ru (accessed: February 03, 2023). DOI: 10.18577/2307-6046-2022-0-8-141-152.
    9. Podzhivotov N.Yu. Express method of a comparative assessment properties levels of materials. Trudy VIAM, 2019, no. 10 (82), paper no. 11. Available at: http://www.viam-works.ru (accessed: February 03, 2023). DOI: 10.18577/2307-6046-2019-0-10-111-124.
    10. 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.
    11. Dragova A.M. Lecture notes on probability theory and mathematical statistics. Moscow: Iris-press, 2004, 256 p.
    12. Vislobokova D.D., Evseenkova V.V., Fayustov A.A. Estimation of parameters of general populations by the method of small samples using the Student’s t-test using Excel templates. Molodoy uchenyy, 2008, no. 43, pp. 23–31.
    13. Gaskarov D.V., Shapovalov V.I. Small sample. Moscow: Statistics, 1978, 248 p.
    14. Lemeshko B.Yu. Criteria for checking the deviation of the distribution from the normal law. Instructions for use. Novosibirsk: Publ. House of Novosibirsk State Tech. Univ., 2014, 192 p.
    15. Pustylnik E.I. Statistical methods for analyzing and processing observations. Moscow: Nauka, 1968, 185 p.
    16. Lemeshko B.Yu., Lemeshko S.B., Gorbunova A.A. On the application and power of criteria for testing the homogeneity of variances. Part I. Parametric criteria. Izmeritelnaya tekhnika, 2010, no. 3, pp. 10–16.
    17. Lemeshko B.Yu. Criteria for testing hypotheses about homogeneity. Instructions for use. Novosibirsk: Publ. House of Novosibirsk State Tech. Univ., 2018, 249 p.
    18. Lemeshko B.Yu., Lemeshko S.B., Gorbunova A.A. On the application and power of criteria for testing the homogeneity of variances. Part II. Nonparametric criteria. Izmeritelnaya tekhnika, 2010, no. 5, pp. 11–18.
    19. Melnikov D.A., Petrova A.P., Gromova A.A., Sokolov I.I., Raskutin A.E. The calculation of the ratio of the components of the prepreg stamps VPS-53/120, determination of physico-mechanical and operational characteristics of GRP. Trudy VIAM, 2019, no. 1 (73), paper no. 10. Available at: http://viam-works.ru (accessed: March 11, 2023). DOI: 10.18577/2307-6046-2019-0-1-92-104.
    20. Khan G., Shapiro S. Statistical models in engineering problems. Moscow: Mir, 1969, 395 p.
    21. Lemeshko B.Yu., Mirkin E.P. Bartlett and Cochran criteria in measurement problems with probabilistic laws different from normal. Izmeritelnaya tekhnika, 2004, no. 10, pp. 10–16.

Full version
11.

DOI: 10.18577/2713-0193-2024-0-1-136-154

UDC: 669.017.165

Pages:: 136-154

V.O. Startsev1, O.V. Startsev1, T.O. Zeleneva1, A.M. Vardanyan1

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

INFLUENCE OF PRECIPITATION ON CHANGES IN THE MASS OF SAMPLES OF POLYMERIC COMPOSITE MATERIALS IN OPEN CLIMATIC CONDITIONS

The effect of weather conditions on the moisture content of 14 grades of aviation fiberglass and carbon fiber reinforced plastics was studied when samples were exposed on open stands in a moderately warm climate. On the time dependences of the mass, local minima were found corresponding to the summer months, during which moisture desorption from the volume of the samples dominates. In the winter months, the mass increases. These seasonal changes in mass are superimposed by diurnal jumps due to dews and rains, and mass drops caused by desorption of moisture under the influence of solar heating. The influence of reinforcing fillers, chemical structure and nanomodification of polymeric binders, application of a protective paint and varnish coating, on the moisture content and the average value of the jumps of the studied materials is considered.

Keywords: GFRP, CFRP, climatic aging, moisture content, seasonality, sorption, paint coating, nanomodifier

Reference List

    1. Mukhametov R.R., Petrova A.P. Thermosetting binders for polymer composite materials. Moscow: VIAM, 2021, 528 p.
    2. Maxwell A.S., Broughton W.R., Dean G., Sims G.M. Review of accelerated ageing methods and lifetime prediction techniques for polymeric materials. NPL Report DEPC MPR 016, 2005, p. 84.
    3. Gibbins M.N., Hoffman D.J. Environmental exposure effects on composite materials for commercial aircraft. NASA Contractor Report 3502, 1982, p. 87.
    4. Pride R.A. Environments effects of composites for aircraft. CTOL Transport Tech. Conf. Hampton, Virginia, 1978, pp. 239–258.
    5. Dexter H.B., Baker D.J. Flight service environmental effects on composite materials and structures. Advanced Performance Materials, 1994, vol. 1, vol. 1, pp. 51–85.
    6. Gulyev I.N., Zelenina I.V., Valevin E.O., Khaskov M.A. Influence of climatic ageing on the properties of high-temperature carbon fiber reinforced plastics. Trudy VIAM, 2021, no. 2 (96), paper no. 05. Available at: http://www.viam-works.ru (accessed: June 22, 2023). DOI: 10.18577/2307-6046-2021-0-2-39-51.
    7. Slavin A.V., Startsev O.V. Properties of aircraft glass- and carbonfibers reinforced plastics at the early stage of natural weathering. Trudy VIAM, 2018, no. 9 (69), paper no. 8. Available at: http://www.viam-works.ru (accessed: June 22, 2023). DOI: 10.18577/2307-6046-2018-0-9-71-82.
    8. Roylance D., Roylance M. Weathering of fiber-reinforced epoxy composites. Polymer Engineering & Science, 1978, vol. 18, no. 4, pp. 249–254.
    9. Startseva L.T. Climatic ageing of organic fiber reinforced plastics. Mechanics of Composite Materials, 1994, vol. 29, pp. 620–626.
    10. Collings T.A. The effect of observed climatic conditoins pn the moisture equilibrium level of fibre-reinforced plastics. Composites, 1986, vol. 17, no. 1, pp. 33–41.
    11. Kini U.A., Shettar M., Suresh S., Gowrishankar M.C. Effect of different types of water soaking and re-drying on mechanical properties of glass fiber-epoxy composites. Cogent Engineering, 2023, vol. 10. Art. 2165018.
    12. Chateauminois A., Chabert B., Soulier J.P., Vincent L. Dynamic mechanical analysis of epoxy composites plasticized by water: artifact and reality. Polymer Composites, 1995, vol. 16, pp. 288–296.
    13. Quino G., Pellegrino A., Tagarielli V.L., Petrinic N. Measurements of the effects of pure and salt water absorption on the rate-dependent response of an epoxy matrix. Composites. Part B: Engineering, 2018, vol. 146, pp. 213–221.
    14. Bian L., Xiao J., Zeng J., Xing S. Effects of seawater immersion on water absorption and mechanical properties of GFRP composites. Journal of Composite Materials, 2012, vol. 46, no. 25, pp. 3151–3162.
    15. Nizin D.R., Nizina T.A., Selyaev V.P., Kanaeva N.S. Reversible and irreversible changes in the properties of polymer materials during natural climatic aging. Umnye kompozity v stroitelstve, 2022, vol. 3, no. 1, pp. 18–29.
    16. Davies P., Le Gac P.Y., Le Gall M. Influence of Sea Water Aging on the Mechanical Behaviour of Acrylic Matrix Composites. Applied Composite Materials, 2017, vol. 24, no. 1, pp. 97–111.
    17. Mazor A., Broutman L.J., Eckstein B.H. Effect of long‐term water exposure on properties of carbon and graphite fiber reinforced epoxies. Polymer Engineering & Science, 1978, vol. 18, no. 5, pp. 341–349.
    18. Startsev V.O., Plotnikov V.I., Antipov Yu.V. Reversible influence of moisture on the mechanical properties of PCM after weathering. Trudy VIAM, 2018, no. 5 (65), paper no. 12. Available at: http://www.viam-works.ru (accessed: June 22, 2023). DOI: 10.18577/2307-6046-2018-0-5-110-118.
    19. Startsev V.O., Slavin A.V. Carbon and glass reinforced polymer based on solventfree binders resistance to the impact of a moderate cold and moderate warm climate. Trudy VIAM, 2021, no. 5 (99), paper no. 12. Available at: http://www.viam-works.ru (accessed: June 22, 2023). DOI: 10.18577/2307-6046-2021-0-5-114-126.
    20. Tomblin J.S., Salah L., Hoffman D., Miller M. Teardown Evaluation of a Decommissioned Boeing 737-200 Carbon Fiber-Reinforced Plastic Composite Right-Hand Horizontal Stabilizer. Final Report DOT/FAA/AR-12/1. 2013, p. 100.
    21. Kirillov V.N., Efimov V.A., Barbotko S.L., Nikolaev E.V. Methodological features of conducting and processing the results of climatic tests of polymer composite materials. Plasticheskiye massy, 2013, no. 1, pp. 37–41.
    22. Startsev O.V., Prokopenko K.O., Litvinov A.A., Krotov A.S., Anikhovskaya L.I., Dementeva L.A. Study of thermohumid aging of aircraft fiberglass plastic. Polymer Science. Series D, 2010, vol. 3, no. 1, pp. 58–61.
    23. Startsev V.O., Krotov A.S., Suranov A.Ya., Startsev O.V. Spectrometric processing of the results of dilatometric measurements of polymer composite materials. Materialovedenie, 2009, no. 11, pp. 11–15.
    24. Vodichka R., Nelson B., van der Berg J., Chester R. Long-term environmental durabillity of F/A-18 composite material. Melbourn, Australia: DSTO Aeronautical and Maritime Research Laboratory, 1999, p. 18.
    25. Vodichka R. Environmental exposure of boron-epoxy composite material. DSTO-TN-0309. Melbourn, Australia: DSTO Aeronautical and Maritime Research Lab., 2000, p. 23.
    26. Kablov E.N., Startsev V.O., Inozemtsev A.A. The moisture absorption of structurally similar samples from polymer composite materials in open climatic conditions with application of thermal spikes. Aviacionnye materialy i tehnologii, 2017, no. 2 (47), pp. 56–68. DOI: 10.18577/2071-9140-2017-0-2-56-68.
    27. Startsev V.O., Valevin E.O., Vardanyan A.M., Nechaev A.A. Assessing the stability of aircraft carbon fiber plastics to precipitation. Materials of the V All-Rus. scientific-technical conf. «Materials and technologies of a new generation for advanced products of aviation and space technology». Moscow, 2021, pp. 60–72.
    28. Zamula G.N., Kolesnik K.A. Thermal and humidity analogy in problems of strength of composite structures. Strength of aircraft structures: collection of articles. scientific-technical conf. Zhukovsky, 2017, pp. 275–281.
    29. Unnam J., Tenney D. Analytical prediction of moisture absorption/desorption in resin matrix composites exposed to aircraft environments. 18th Structural Dynamics and Materials Conference. Reston, Virigina: American Institute of Aeronautics and Astronautics, 1977, pp. 227–235.
    30. Bosen J.F. An approximation formula to compute relative humidity from dry bulb and dew point temperatures. Monthly Weather Review, 1958, vol. 86, no. 12, p. 486.
    31. Salnikov V.G. Study of moisture absorption of aircraft carbon fiber reinforced plastics in warm humid climates. Monitoring Systems of Environment, 2021, no. 2, pp. 46–53.
    32. Bijl P., Heikkilä A., Syrjälä S., Aarva A., Poikonen A. Modelling of sample surface temperature in an outdoor weathering test. Polymer Testing, 2011, vol. 30, pp. 485–492.
    33. Kolesnik K.A. Modeling of moisture saturation in polymer composites in real climatic environmental conditions. Aviacionnye materialy i tehnologii, 2017, no. 4 (49), pp. 77–86. DOI: 10.18577/2071-9140-2017-0-4-77-86.
    34. Petrova G.N., Bejder E.Ya. Development and research of finishing compositions for thermoplastic carbon plastics. Trudy VIAM, 2016, no. 12 (46), paper no. 09. Available at: http://www.viam-works.ru (accessed: June 22, 2023). DOI: 10.18577/2307-6046-2016-0-12-9-9.
    35. Koval T.V., Veligodsky I.M., Gromova A.A. Study of the plasticizing effect of moisture on the properties of VSE-34 binder based PCMS after 5 years exposure in the different climate zones. Trudy VIAM, 2021, no. 9 (103), paper no. 11. Available at: http://www.viam-works.ru (accessed: June 22, 2023). DOI: 10.18577/2307-6046-2021-0-9-105-116.
    36. Gusev Yu.A., Tverdaya O.N., Gromova A.A. Carbon plastic on the basis of binding curing with low temperature and carbon equally strong of the fabric. Trudy VIAM, 2017, no. 6 (54), paper no. 06. Available at: http:/www.viam-works.ru (accessed: June 22, 2023). DOI: 10.18577/2307-6046-2017-0-6-6-6.
    37. Timoshkov P.N., Kolobkov A.S., Kurnosov A.O., Goncharov A.A. Prepregs based on melt binders and new generation PCM based on them for aviation products. Materials V All-Rus. scientific-technical conf. «Polymer composite materials and production technologies of a new generation». Moscow, 2021, pp. 7–20.
    38. Timoshkov P.N., Khrulkov A.V., Yazvenko L.N. Composite materials in automotive industry (review). Trudy VIAM, 2017, no. 6 (54), paper no. 07. Available at: http://www.viam-works.ru (accessed: June 22, 2023). DOI: 10.18577/2307-6046-2017-0-6-7-7.
    39. Koval T.V., Veligodsky I.M., Gromova A.A. Changes in the properties of the VSR-3M binder in the composition of VKU-46 carbon fiber plastic after long-term climatic aging. Klei. Germetiki. Tekhnologii, 2022, no. 11, pp. 134–148.
    40. Kolobkov A.S. Polymer composite materials for various aircraft structures (review). Trudy VIAM, 2020, no. 6–7 (89), paper no. 05. Available at: http://www.viam-works.ru (accessed: June 22, 2023). DOI: 10.18577/2307-6046-2020-0-67-38-44.
    41. Veligodskiy I.M., Koval T.V., Kurnosov A.O., Marakhovskiy P.S. Study of resistance of glass fiber reinforced plastic to natural weathering in different climatic conditions. Trudy VIAM, 2022, no. 11 (117), paper no. 12. Available at: http://www.viam-works.ru (accessed: June 22, 2023). DOI: 10.18577/2307-6046-2022-0-11-134-148.
    42. Antipov V.V., Kotova E.V., Serebrennikova N.Yu., Petrova A.P. Glue binders and glue prepregs for alumopolymeric composite materials. Trudy VIAM, 2018, no. 5 (65), paper no. 06. Available at: http://www.viam-works.ru (accessed: June 22, 2023). DOI: 10.18577/2307-6046-2018-0-5-44-54.
    43. Gunyaev G.M., Chursova L.V., Komarova O.A., Gunyaeva A.G. Constructional carbon the plastics modified by nanoparticles. Aviacionnye materialy i tehnologii, 2012, no. S, pp. 277–286.
    44. Startsev V.O., Nechaev A.A. Moisture transfer in cyanester carbon fiber plastic during accelerated and full-scale climatic tests. Materials of the XIV All-Rus. conf. on testing and research of the properties of materials «TestMat». Moscow, 2022, pp. 214–226.
    45. Sarkissian E. The Levenberg-Marquardt Algorithm for Solving the Nonlinear Least Squares Problem: Theory, Implementation and Application. Los Angeles: California State University, 2001, 227 p.
    46. Cook R.D. Detection of influential observation in linear regression. Technometrics, 1977, vol. 19, no. 1, pp. 15–18.
    47. Springer G.S. Moisture content of composites under transient conditions. Journal of Composite Materials, 1977, vol. 11, no. 1, pp. 107–122.
    48. Kim Y.-H., Park J.-M., Yoon S.-W. et al. The Effect of Moisture Absorption and Gel-coating Process on the Mechanical Properties of the Basalt Fiber Reinforced Composite. International Journal of Ocean System Engineering, 2011, vol. 1, no. 3, pp. 148–154.
    49. Pavan R.M.V., Saravanan V., Dinesh A.R. et al. Hygrothermal effects on painted and unpainted glass/epoxy composites – Part A: Moisture absorption characteristics. Journal of Reinforced Plastics and Composites, 2001, vol. 20, no 12, pp. 1036–1047.
    50. Dexter H.B., Baker D.J. Worldwide flight and ground-based exposure of composite materials. NASA Conference Publication, 1984, pp. 17–49.
    51. Baker D.J. Ten-Year Ground Exposure of Composite Materials Used on the Bell Model 206L Helicopter Flight Service Program. NASA Technical Paper 3468, 1994, p. 54.
    52. Kondrashov E.K., Kuznetsova V.A., Lebedeva T.A., Semenova L.V. Main directions for improving the operational, technological and environmental characteristics of paint and varnish coatings for aircraft. Rossiyskiy khimicheskiy zhurnal, 2010, vol. 54, no. 1, pp. 96–102.
    53. Semenova L.V., Malova N.E., Kuznetsova V.A., Pozhoga A.A. Paint and varnish materials and coatings. Aviacionnye materialy i tehnologii, 2012, no. S, pp. 315–327.
    54. Andreeva N.P., Skirta A.A., Nikolaev E.V. Study of the preservation of the properties of paint and varnish coatings for aviation purposes under the influence of climatic factors in atmospheric conditions. Materials of the All-Rus. Sci.-tech. Conf. «Mnogofunktsionalnye lakokrasochnye pokrytiya», Moscow, 2018, pp. 29–38. Available at: http://conf.viam (accessed: June 22, 2023).
    55. 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.

Full version
12.

DOI: 10.18577/2713-0193-2024-0-1-155-168

UDC: 632.952

Pages:: 155-168

A.A. Krivushina1, A.B. Laptev1

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

FUNGICIDES: APPLICATION, PROPERTIES AND PRINCIPLES OF ACTION 

Fungicides are substances that destroy or suppress the development of microscopic fungi, they are of great importance for the aviation industry, since they are the most effective means of combating microbiological damage. Fungicides can inhibit the metabolic reactions of fungi, destroy their cellular structures or disrupt processes. When choosing a fungicide, it is necessary to take into account its possible effectiveness at a minimum concentration. Among the risks of ineffectiveness of the fungicide is the appearance of resistance, or resistance, to these substances in microscopic fungi. Important issues include the possible toxicity of fungicides to humans and the environment, as well as the further disposal of fungicidal preparations.

Keywords: biodeterioration, biocides, microbiological damage, degrading microorganisms, fungicides

Reference List

    1. Valueva M.I., Zelenina I.V., Nacharkina A.V., Goryashnik Yu.S. Properties of high-temperature carbon fiber reinforced plastics after tests for fungus resistance. Trudy VIAM, 2022, no. 11 (117), paper no. 07. Available at: http://www.viam-works.ru (accessed: March 13, 2023). DOI: 10.18577/2307-6046-2022-0-11-69-80.
    2. Krivushina A.A., Startsev V.O. Micromycetes-destructors of polymeric materials among extremophilic microorganisms (review). Trudy VIAM, 2022, no. 1 (107), paper no. 12. Available at: http://www.viam-works.ru (accessed: March 13, 2023). DOI: 10.18557/2307-6046-2022-0-1-123-134.
    3. Krivushina A.A., Terekhov I.V., Moskvitina K.N., Malysheva S.F., Kuimov V.A. Efficiency of new fungicide compounds based on modified polysept for protection of polymer materials against biodeterioration. Trudy VIAM, 2021, no. 12 (106), paper no. 12. Available at: http://www.viam-works.ru (accessed: March 13, 2023). DOI: 10.18577/2307-6046-2021-0-12-107-116.
    4. Li H., Liu Z., Dong Y. et al. Design, Synthesis, and Fungicidal Evaluation of Novel N-Methoxy Pyrazole-4-Carboxamides as Potent Succinate Dehydrogenase Inhibitors. Journal of Agricultural and Food Chemistry, 2023, vol. 71, no. 5, pp. 2610–2615. DOI: 10.1021/acs.jafc.2c07031.
    5. Stierli D., Haas H.U., Rajan R., Bartlett D. Recent ADEPIDYN – the first N-methoxy-substituted carboxamide among the succinate dehydrogenase inhibitors. Highlights in the Discovery and Optimization of Crop Protection Products. Gente: Mangelinks, 2021, pp. 357–366. DOI: 10.1016/B978-0-12-821035-2.00024-3.
    6. Bolognesi C., Merlo F.D. Encyclopedia of Environmental Health. Second Ed. Oxford: Elsevier, 2019, p. 120.
    7. Robinson M.W., McFerran N., Trudgett A. et al. A possible model of benzimidazole binding to b-tubulin disclosed by invoking an inter-domain movement. Journal of Molecular Graphics and Modelling, 2004, no. 23, pp. 275–284.
    8. Schulz zur Wiesch P., Engelstädter J., Bonhoeffer S. Compensation of fitness costs and reversibility of antibiotic resistance mutations. Antimicrobial agents and chemotherapy, 2010, no. 54, pp. 2085–2095.
    9. Kablov E.N., Shchegoleva N.E., Lebedeva Yu.E., Zhuravleva P.L., Vaganova M.L., Chainikova A.S. Study of the processes of obtaining lanthanum hexaboride using the method of borothermal reduction. Steklo i keramika, 2023, vol. 96, no. 2 (1142), pp. 27–41. DOI: 10.14489/glc.2023.02.pp.027-041.
    10. Kuck K.H., Mehl A. Trifloxystrobin: Resistance risk and resistance management. Pflanzenschutz-Nachrichten Bayer, 2003, no. 2, pp. 313–325.
    11. Huang R., Levy Y. Characterization of iprodione-resistant isolates of Alternaria brassicicola. Plant Disease, 1995, no. 79, pp. 828–833.
    12. Köller W., Wilcox W.F. Evaluation of tactics for managing resistance of Venturia inaequalis to sterol demethylation inhibitors. Plant Disease, 1999, no. 83, pp. 857–863.
    13. Quello K.L., Chapman K.S., Beckerman J.L. In situ detection of benzimidazole resistance in field isolates of Venturia inaequalis in Indiana. Plant Disease, 2010, no. 94, pp. 744–750.
    14. Calabrese E.J., Baldwin L.A. Toxicology rethinks its central belief. Nature, 2003, no. 421, pp. 691–692.
    15. Gillespie S.H., Basu S., Dickens A.L. et al. Effect of subinhibitory concentrations of ciprofloxacin on Mycobacterium fortuitum mutation rates. Journal of Antimicrobial Chemotherapy, 2005, no. 56, pp. 344–348.
    16. Mavroeidi V.I., Shaw M.W. Effects of fungicide dose and mixtures on selection for triazole resistance in Mycosphaerella graminicola under field conditions. Plant Pathology, 2006, no. 55, pp. 715–725.
    17. McGrath M.T. Fungicide resistance in cucurbit powdery mildew: Experiences and challenges. Plant Disease, 2001, no. 85, pp. 236–245.
    18. Kablov E.N., Evgenov A.G., Bakradze M.M., Nerush S.V., Krupnina O.A. Next-generation materials and digital additive technologies for the production of resource parts in FGUP VIAM: I. Synthesis materials and technologies. Russian Metallurgy (Metally), 2022, vol. 2022, no. 6, pp. 611–618. DOI: 10.1134/S003602952206009X.
    19. Kablov E.N., Babashov V.G., Balinova Y.A., Maksimov V.G. Phase transformations in a composite material with an organic matrix filled with zirconium dioxide fibers. High Temperature, 2021, vol. 59, no. 1, pp. 55–61. DOI: 10.1134/S0018151X21010065.
    20. Zhonghua M., Michailides T.J. Advances in understanding molecular mechanisms of fungicide resistance and molecular detection of resistant genotypes in phytopathogenic fungi. Crop Protection, 2005, no. 24, pp. 853–863.
    21. Anisimov A.A., Aleksandrova I.F. On the biochemical mechanisms of action of fungicides. Biodamage in industry: interuniver. collection. Gorky: Publishing House Gorky Univ., 1983. pp. 7–17.
    22. Anisimov A.A., Smirnov V.F., Semicheva A.S. The effect of fungicides on some aspects of the metabolism of mold fungi. Chemical means of protection against biocorrosion: abstracts of reports. Ufa: Nauka, 1980, part 1, pp. 15–16.
    23. Smirnov V.F., Leontyeva A.N., Smirnova O.N., Zakharova E.A. On the effect of fungicides on the respiration and activity of catalase and SOD of the fungus Aspergillus niger. IV All-Union. conf. on biodamages: abstract. Nizhny Novgorod, 1991, pp. 69–70.
    24. Vincelli P. Some Principles of Fungicide Resistance. Plant Pathology Fact Sheet. Kentucky: University of Kentucky College of Agriculture Plant Pathology Extension, 2008, 10 р.
    25. Brent K.J., Holloman D.W. Fungicide Resistance in Crop Pathogens: How Can it be Managed? Second, rev. ed. Fungicide Resistance Action Committee, 2007, 56 p.
    26. Karaoglanidis G.S., Thanassoulopoulos C.C., Ioannidis P.M. Fitness of Cercospora beticola field isolates – resistant and – sensitive to demethylation inhibitor fungicides. European Journal of Plant Pathology, 2001, no. 107, pp. 337–347.
    27. Ribeiro M., Simões M. Biocides. Encyclopedia of Microbiology. Fourth Ed. Washington: Elsevier, 2018, 512 p.
    28. Costa L.G. Basic toxicology of pesticides. Occupational Medicine: State of the Art Reviews, 1997, vol. 12, pp. 251–268.
    29. Rouabhi R. Introduction and toxicology of fungicides. Fungicides. Tebessa: Intech open, 2010, pp. 363–382. DOI: 10.13140/RG.2.1.2099.9125.
    30. Blondell J. Epidemiology of pesticide poisoning in the United States, with special reference to occupational cases. Occupational Medicine: State of the Art Reviews, 1997, vol. 12, pp. 209–220.
    31. Hayes W.J., Vaughn W.K. Mortality from pesticides in the United States from 1973 to 1976. Toxicology and Applied Pharmacology, 1977, vol. 42, pp. 235–252.
    32. Litovitz T.A., Felberg L., Soloway R.A. Annual reports of the American Association of Poison Control Centers. Toxic exposure surveillance system. The American Journal of Emergency Medicine, 1994, vol. 13, pp. 551–597.
    33. Edwards I.R., Ferry D.G., Temple W.A. Fungicides & related compounds. Handbook of Pesticide Toxicology. New York: Academic Press, 1991, vol. 3, pp. 1409–1470.
    34. Marrs C.T., Ballantyne B. Pesticides toxicology and international regulation. New York: Wiley and Sons Ltd, 2004, 554 p.
    35. Phillips S.D. Fungicides and biocides. Clinical Environmental Health and Toxic Exposures. 2nd eds. Philadelphia: Sullivan J.B. & Krieger G.R., 2001, pp. 1109–1125.
    36. Laptev A.B., Zheleznyak V.G., Tourova T.P., Sokolova D.Sh., Nazina T.N. The effect of the presence of toxic additives in the polymer material on the processes of its biodegradation in seawater. Trudy VIAM, 2022, no. 12 (118), paper no. 11. Available at: http://www.viam-works.ru (accessed: March 13, 2023). DOI: 10.18577/2307-6046-2022-0-12-121-134.

Full version