Articles
1.
dx.doi.org/ 10.18577/2307-6046-2025-0-3-3-11
УДК 669.018.95:621.791.724
Dobrynin D.A., Pavlova T.V.
ELECTROLYTE-PLASMA POLISHING OF PARTS MADE BY SELECTIVE LASER SINTERING FROM METAL POWDER COMPOSITION OF ALUMINUM ALLOY GRADE VAS1. Part 2
The influence of additives in the base electrolyte, operating voltage and temperature of the electrolyte on the quality of the process of electrolyte-plasma polishing of parts manufactured by selective laser sintering from a metal powder composition of aluminum alloy grade VAS1 was studied. Electrolyte-plasma polishing of a structurally similar sample of a «bracket» type part was carried out. A technology has been developed for electrolyte-plasma polishing of parts manufactured by the selective laser sintering method from metal powder composition aluminum alloy grade VAS1.
Reference list
1. Kablov E.N., Evgenov A.G., Bakradze M.M., Nerush S.V., Krupnina O.A. New generation materials and digital additive technologies for the production of resource parts of FSUE VIAM. Part 1. Materials and synthesis technologies. Elektrometallurgiya, 2022, no. 1, pp. 2–12. DOI: 10.31044/1684-5781-2022-0-1-2-12.
2. Kablov E.N., Evgenov A.G., Petrushin N.V., Bazyleva O.A., Mazalov I.S., Dynin N.V. New generation materials and digital additive technologies for the production of resource parts of FSUE VIAM. Part 3. Adaptation and creation of materials. Elektrometallurgiya, 2022, no. 4, pp. 15–25. DOI: 10.31044/1684-5781-2022-0-4-15-25.
3. Kablov E.N., Evgenov A.G., Petrushin N.V., Bazyleva O.A., Mazalov I.S. New-generation materials and digital additive technologies for the production of resource parts of FSUE VIAM. Part 4. Development of heat-resistant materials. Elektrometallurgiya, 2022, no. 5, pp. 8–19. DOI: 10.31044/1684-5781-2022-0-5-8-19.
4. 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: September 10, 2024). DOI: 10.18577/2713-0193-2021-0-3-19-34.
5. Peskova A.V., Sukhov D.I., Mazalov P.B. Examination of the formation of the titanium alloy VT6 structure obtained by additive manufacturing. Aviacionnye materialy i tehnologii, 2020, no. 1 (58), pp. 38–44. DOI: 10.18577/2071-9140-2020-0-1-38-44.
6. Nerush S.V., Sviridov A.V., Afansiev-Khodykin A.N., Galushka I.A., Tarasov S.A. Development of brazing technology for parts obtained by additive technologies from cobalt based metal powder composition. Aviation materials and technologies, 2022, no. 2 (67), paper no. 02. Available at: http://www.journal.viam.ru (accessed: September 10, 2024). DOI: 10.18577/2713-0193-2022-0-2-18-29.
7. Marakhovskij P.S., Barinov D.Ya., Shorstov S.Yu., Vorobev N.N. On creation of physical and mathematical models of heat and mass transfer during manufacturing by additive technologies (review). Aviation materials and technologies, 2022, no. 2 (67), paper no. 10. Available at: http://www.journal.viam.ru (accessed: September 10, 2024). DOI: 10.18577/2713-0193-2022-0-2-111-119.
8. Galvanic coatings in mechanical engineering: a reference book in 2 vols. Ed. M.A. Shluger. Moscow: Mashinostroenie, 1985, vol. 1, 240 p.
9. Mirzoev R.A., Davydov A.D. Anodic processes of electrochemical and chemical processing of metals: a textbook. St. Petersburg: Publ. house of the Polytech. Univ., 2013, 382 p.
10. Kulikov I.S., Vaschenko S.V., Kamenev A.Ya. Electrolytic-plasma processing of materials. Minsk: Belarusian Navuka, 2010, 232 p.
11. Method of electrolytic-plasma processing of products made of aluminum and aluminum alloys: pat. 7291 Republic of Belarus; appl. 16.07.15; publ. 28.02.17.
12. Zakharov S.V., Korotkikh M.T. Electrolyte-plasma polishing of complex-shaped products made of aluminum alloy D16. Vestnik Kontserna VKO «Almaz–Antey», 2017, no. 3, pp. 83–87.
13. Pogrebnyak A.D., Tyurin Yu.N., Boyko A.G. et al. Electrolyte-plasma treatment and coating of metals and alloys. Uspekhi fiziki metallov, 2005, vol. 6, pp. 273–344.
14. Volenko A.P., Boychenko O.V., Chirkunova N.V. Electrolyte-plasma treatment of metal products. Vektor nauki TGU, 2012, no. 4 (22), pp. 144–147.
15. Grilikhes S. Ya. Degreasing, etching and polishing of metals. Ed. P.M. Vyacheslavov. 5th ed., rev. and add. Leningrad: Mashinostroenie, 1983, 101 p.
2. Kablov E.N., Evgenov A.G., Petrushin N.V., Bazyleva O.A., Mazalov I.S., Dynin N.V. New generation materials and digital additive technologies for the production of resource parts of FSUE VIAM. Part 3. Adaptation and creation of materials. Elektrometallurgiya, 2022, no. 4, pp. 15–25. DOI: 10.31044/1684-5781-2022-0-4-15-25.
3. Kablov E.N., Evgenov A.G., Petrushin N.V., Bazyleva O.A., Mazalov I.S. New-generation materials and digital additive technologies for the production of resource parts of FSUE VIAM. Part 4. Development of heat-resistant materials. Elektrometallurgiya, 2022, no. 5, pp. 8–19. DOI: 10.31044/1684-5781-2022-0-5-8-19.
4. 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: September 10, 2024). DOI: 10.18577/2713-0193-2021-0-3-19-34.
5. Peskova A.V., Sukhov D.I., Mazalov P.B. Examination of the formation of the titanium alloy VT6 structure obtained by additive manufacturing. Aviacionnye materialy i tehnologii, 2020, no. 1 (58), pp. 38–44. DOI: 10.18577/2071-9140-2020-0-1-38-44.
6. Nerush S.V., Sviridov A.V., Afansiev-Khodykin A.N., Galushka I.A., Tarasov S.A. Development of brazing technology for parts obtained by additive technologies from cobalt based metal powder composition. Aviation materials and technologies, 2022, no. 2 (67), paper no. 02. Available at: http://www.journal.viam.ru (accessed: September 10, 2024). DOI: 10.18577/2713-0193-2022-0-2-18-29.
7. Marakhovskij P.S., Barinov D.Ya., Shorstov S.Yu., Vorobev N.N. On creation of physical and mathematical models of heat and mass transfer during manufacturing by additive technologies (review). Aviation materials and technologies, 2022, no. 2 (67), paper no. 10. Available at: http://www.journal.viam.ru (accessed: September 10, 2024). DOI: 10.18577/2713-0193-2022-0-2-111-119.
8. Galvanic coatings in mechanical engineering: a reference book in 2 vols. Ed. M.A. Shluger. Moscow: Mashinostroenie, 1985, vol. 1, 240 p.
9. Mirzoev R.A., Davydov A.D. Anodic processes of electrochemical and chemical processing of metals: a textbook. St. Petersburg: Publ. house of the Polytech. Univ., 2013, 382 p.
10. Kulikov I.S., Vaschenko S.V., Kamenev A.Ya. Electrolytic-plasma processing of materials. Minsk: Belarusian Navuka, 2010, 232 p.
11. Method of electrolytic-plasma processing of products made of aluminum and aluminum alloys: pat. 7291 Republic of Belarus; appl. 16.07.15; publ. 28.02.17.
12. Zakharov S.V., Korotkikh M.T. Electrolyte-plasma polishing of complex-shaped products made of aluminum alloy D16. Vestnik Kontserna VKO «Almaz–Antey», 2017, no. 3, pp. 83–87.
13. Pogrebnyak A.D., Tyurin Yu.N., Boyko A.G. et al. Electrolyte-plasma treatment and coating of metals and alloys. Uspekhi fiziki metallov, 2005, vol. 6, pp. 273–344.
14. Volenko A.P., Boychenko O.V., Chirkunova N.V. Electrolyte-plasma treatment of metal products. Vektor nauki TGU, 2012, no. 4 (22), pp. 144–147.
15. Grilikhes S. Ya. Degreasing, etching and polishing of metals. Ed. P.M. Vyacheslavov. 5th ed., rev. and add. Leningrad: Mashinostroenie, 1983, 101 p.
2.
dx.doi.org/ 10.18577/2307-6046-2025-0-3-12-22
УДК 669.715
Astashkin A.I., Babanov V.V., Selivanov A.A., Tkachenko E.A.
INFLUENCE OF HOMOGENIZATION MODES OF INGOTS AND HEAT TREATMENT OF SHEETS FROM ALLOY V95oсh-T2 ON THEIR STRUCTURE AND PROPERTIES
The article presents the results of a study of the relationship between the microstructure of V95och alloy ingots after homogenization annealing in single- and two-stage modes with the parameters of technological plasticity in the temperature range of 350–450 °C. There has been stablished the dependence from the homogenization mode of the structure and properties of sheets with a thickness of more than 6 mm made of V95och alloy, aged in a new experimental mode and a serial aging mode T2. We selected the modes of homogenization annealing and aging that ensure achievement of the highest level of service characteristics of sheets.
Reference list
1. Kablov E.N. Innovative developments of FSUE «VIAM» SSC of RF on realization of «Strategic directions of the development of materials and technologies of their processing for the period until 2030». Aviacionnye materialy i tehnologii, 2015, no. 1 (34), pp. 3–33. DOI: 10.18577/2071-9140-2015-0-1-3-33.
2. Kablov E.N., Antipov V.V. The Role of New Generation Materials in Ensuring the Technological Sovereignty of the Russian Federation. Vestnik Rossiyskoy akademii nauk, 2023, vol. 93, no. 10, pp. 907–916.
3. Antipov V.V. Prospects for development of aluminium, magnesium and titanium alloys for aerospace engineering. Aviacionnye materialy i tehnologii, 2017, no. S, pp. 186–194. DOI: 10.18577/2071-9140-2017-0-S-186-194.
4. Tarasov Yu.M., Antipov V.V. The VIAM new materials – for perspective aviation engineering of production of JSC «OAK». Aviacionnye materialy i tehnologii, 2012, no. 2, pp. 5–6.
5. Duyunova V.A., Nechaikina T.A., Oglodkov M.S., Yakovlev A.L., Leonov A.A. Promising developments in the field of lightweight materials for modern aerospace technology. Tekhnologiya legkikh splavov, 2018, no. 4, pp. 28–43.
6. Antipov V.V., Serebrennikova N.Yu., Konovalov A.N., Nefedova Yu.N. Perspectives of application of fiber metal laminate materials based on aluminum alloys in aircraft design. Aviacionnye materialy i tehnologii, 2020, no. 1 (58), pp. 45–53. DOI: 10.18577/2071-9140-2020-0-1-45-53.
7. Senatorova O.G., Antipov V.V., Bronz A.V. et al. High-strength and super-strong alloys of the traditional Al–Zn–Mg–Cu system, their role in technology and development possibilities. Tekhnologiya legkikh splavov, 2016, no. 2, pp. 43–49.
8. Oglodkov M.S., Romanenko V.A., Benarieb I., Rudchenko A.S., Grigoryev M.V. Study of industrial semi-finished products from advanced aluminum-lithium alloys for aircraft products. Aviation materials and technologies, 2023, no. 3 (72), paper no. 05. Available at: http://www.journal.viam.ru (accessed: September 20, 2024). DOI: 10.18577/2713-0193-2023-0-3-62-77.
9. Senatorova O.G., Uksusnikov A.N., Legoshina S.F., Ivanov A.L., Sidelnikov V.V. Effect of various small additives on the structure and properties of sheets made of high-strength alloys of the Al–Zn–Mg–Cu system. Aviacionnye materialy i tehnologii, 2002, is.: Promising aluminum, magnesium and titanium alloys for aerospace engineering, pp. 91–95.
10. Nikitin V.I. Genetic engineering technologies – a new direction in the production of aluminum alloys. Proc. scientific-technical. conf. «New directions of development of production and consumption of aluminum and its alloys». Samara, 2000, pp. 158–165.
11. Aviation materials: handbook in 13 vols. Ed. E.N. Kablov. 7th ed., rev. and add. Moscow: VIAM, 2008, vol. 4: Aluminum and Beryllium Alloys, Part 1: Wrought Aluminum Alloys, book 2, pp. 35–66.
12. Fridlyander I.N. Metallurgy of Aluminum Alloys. Moscow: Nauka, 1985, 238 p.
13. Kolobnev N.I., Ber L.B., Tsukanov S.L. Heat Treatment of Wrought Aluminum Alloys. Moscow: NP «APRAL», 2020, 552 p.
14. Wei Wang, Ralph T. Shuey. Homogenization Model for 7xxx Aluminum Alloy. Proceedings of the 12th International Conference on Aluminium Alloys. Yokohama, 2010, pp. 264–269.
15. Nechaykina T.A., Oglodkov M.S., Ivanov A.L., Kozlova O.Yu., Yakovlev S.I., Shlyapnikov M.A. Features of hardening of wide cladding sheets from V95p.ch. aluminum alloy on a continuous heat treatment line. Trudy VIAM, 2021, no. 11 (105), paper no. 03. Available at: http://www.viam-works.ru (accessed: September 20, 2024). DOI: 10.18577/2307-6046-2021-0-11-25-33.
16. Astashkin A.I., Zaitsev D.V., Selivanov A.A., Tkachenko E.A. The influence of homogenization annealing оn the structural phase evolution and technological plasticity of aluminum alloy 1163 ingots. Trudy VIAM, 2024, no. 7 (137), paper no. 02. Available at: http://www.viam-works.ru (accessed: September 20, 2024). DOI: 10.18577/2307-6046-2024-0-7-12-23.
17. Fridlyander I.N., Berstenev V.V., Tkachenko E.A. et al. Effect of heat treatment and deformation on grain size and mechanical properties of duralumin alloys. Metallovedenie i termicheskaya obrabotka metallov, 2003, no. 7, pp. 3–6.
18. Nechaikina T.A., Blinova N.E., Ivanov A.L., Kozlova O.Yu., Kozhekin A.E. Research of the effect of homogenization and quench hardening modes on the structure and mechanical properties of retail rings from alloy В95o.ch.-T2. Trudy VIAM, 2018, no. 10 (70), paper no. 04. Available at: http://www.viam-works.ru (accessed: September 20, 2024). DOI: 10.18577/2307-6046-2018-0-10-27-36.
19. Yu-lin Zheng, Cheng-bo Li, Shengdan Liu et al. Effect of homogenization time on quench sensitivity of 7085 aluminum alloy. Transactions of Nonferrous Metals Society of China, 2014, vol. 24, pp. 2275−2281.
20. Aryshenskiy V.Yu., Grechnikova A.F., Drits A.M., Sosedkov S.M. Selection of technological parameters for reducing the grain size in the base and cladding of cladding sheets made of aluminum alloys. Tekhnologiya legkikh splavov, 2010, no. 3, pp. 21–30.
21. Tkachenko E.A., Senatorova O.G., Milevskaya T.V., Ivanov A.L. Influence of grain size on the complex of properties of clad cladding cold-rolled sheets made of base alloys 1163 and B95pch. Tsvetnye metally, 2014, no. 13, pp. 57–63.
2. Kablov E.N., Antipov V.V. The Role of New Generation Materials in Ensuring the Technological Sovereignty of the Russian Federation. Vestnik Rossiyskoy akademii nauk, 2023, vol. 93, no. 10, pp. 907–916.
3. Antipov V.V. Prospects for development of aluminium, magnesium and titanium alloys for aerospace engineering. Aviacionnye materialy i tehnologii, 2017, no. S, pp. 186–194. DOI: 10.18577/2071-9140-2017-0-S-186-194.
4. Tarasov Yu.M., Antipov V.V. The VIAM new materials – for perspective aviation engineering of production of JSC «OAK». Aviacionnye materialy i tehnologii, 2012, no. 2, pp. 5–6.
5. Duyunova V.A., Nechaikina T.A., Oglodkov M.S., Yakovlev A.L., Leonov A.A. Promising developments in the field of lightweight materials for modern aerospace technology. Tekhnologiya legkikh splavov, 2018, no. 4, pp. 28–43.
6. Antipov V.V., Serebrennikova N.Yu., Konovalov A.N., Nefedova Yu.N. Perspectives of application of fiber metal laminate materials based on aluminum alloys in aircraft design. Aviacionnye materialy i tehnologii, 2020, no. 1 (58), pp. 45–53. DOI: 10.18577/2071-9140-2020-0-1-45-53.
7. Senatorova O.G., Antipov V.V., Bronz A.V. et al. High-strength and super-strong alloys of the traditional Al–Zn–Mg–Cu system, their role in technology and development possibilities. Tekhnologiya legkikh splavov, 2016, no. 2, pp. 43–49.
8. Oglodkov M.S., Romanenko V.A., Benarieb I., Rudchenko A.S., Grigoryev M.V. Study of industrial semi-finished products from advanced aluminum-lithium alloys for aircraft products. Aviation materials and technologies, 2023, no. 3 (72), paper no. 05. Available at: http://www.journal.viam.ru (accessed: September 20, 2024). DOI: 10.18577/2713-0193-2023-0-3-62-77.
9. Senatorova O.G., Uksusnikov A.N., Legoshina S.F., Ivanov A.L., Sidelnikov V.V. Effect of various small additives on the structure and properties of sheets made of high-strength alloys of the Al–Zn–Mg–Cu system. Aviacionnye materialy i tehnologii, 2002, is.: Promising aluminum, magnesium and titanium alloys for aerospace engineering, pp. 91–95.
10. Nikitin V.I. Genetic engineering technologies – a new direction in the production of aluminum alloys. Proc. scientific-technical. conf. «New directions of development of production and consumption of aluminum and its alloys». Samara, 2000, pp. 158–165.
11. Aviation materials: handbook in 13 vols. Ed. E.N. Kablov. 7th ed., rev. and add. Moscow: VIAM, 2008, vol. 4: Aluminum and Beryllium Alloys, Part 1: Wrought Aluminum Alloys, book 2, pp. 35–66.
12. Fridlyander I.N. Metallurgy of Aluminum Alloys. Moscow: Nauka, 1985, 238 p.
13. Kolobnev N.I., Ber L.B., Tsukanov S.L. Heat Treatment of Wrought Aluminum Alloys. Moscow: NP «APRAL», 2020, 552 p.
14. Wei Wang, Ralph T. Shuey. Homogenization Model for 7xxx Aluminum Alloy. Proceedings of the 12th International Conference on Aluminium Alloys. Yokohama, 2010, pp. 264–269.
15. Nechaykina T.A., Oglodkov M.S., Ivanov A.L., Kozlova O.Yu., Yakovlev S.I., Shlyapnikov M.A. Features of hardening of wide cladding sheets from V95p.ch. aluminum alloy on a continuous heat treatment line. Trudy VIAM, 2021, no. 11 (105), paper no. 03. Available at: http://www.viam-works.ru (accessed: September 20, 2024). DOI: 10.18577/2307-6046-2021-0-11-25-33.
16. Astashkin A.I., Zaitsev D.V., Selivanov A.A., Tkachenko E.A. The influence of homogenization annealing оn the structural phase evolution and technological plasticity of aluminum alloy 1163 ingots. Trudy VIAM, 2024, no. 7 (137), paper no. 02. Available at: http://www.viam-works.ru (accessed: September 20, 2024). DOI: 10.18577/2307-6046-2024-0-7-12-23.
17. Fridlyander I.N., Berstenev V.V., Tkachenko E.A. et al. Effect of heat treatment and deformation on grain size and mechanical properties of duralumin alloys. Metallovedenie i termicheskaya obrabotka metallov, 2003, no. 7, pp. 3–6.
18. Nechaikina T.A., Blinova N.E., Ivanov A.L., Kozlova O.Yu., Kozhekin A.E. Research of the effect of homogenization and quench hardening modes on the structure and mechanical properties of retail rings from alloy В95o.ch.-T2. Trudy VIAM, 2018, no. 10 (70), paper no. 04. Available at: http://www.viam-works.ru (accessed: September 20, 2024). DOI: 10.18577/2307-6046-2018-0-10-27-36.
19. Yu-lin Zheng, Cheng-bo Li, Shengdan Liu et al. Effect of homogenization time on quench sensitivity of 7085 aluminum alloy. Transactions of Nonferrous Metals Society of China, 2014, vol. 24, pp. 2275−2281.
20. Aryshenskiy V.Yu., Grechnikova A.F., Drits A.M., Sosedkov S.M. Selection of technological parameters for reducing the grain size in the base and cladding of cladding sheets made of aluminum alloys. Tekhnologiya legkikh splavov, 2010, no. 3, pp. 21–30.
21. Tkachenko E.A., Senatorova O.G., Milevskaya T.V., Ivanov A.L. Influence of grain size on the complex of properties of clad cladding cold-rolled sheets made of base alloys 1163 and B95pch. Tsvetnye metally, 2014, no. 13, pp. 57–63.
3.
dx.doi.org/ 10.18577/2307-6046-2025-0-3-23-32
УДК 669.018.292:669.295
Yashin M.S., Kapitanenko D.V.
INVESTIGATION OF THERMO-MECHANICAL PARAMETERS OF HOT AND WARM ROLLING OF TITANIUM ALLOY VT23 TYPE
In present work the study of technology particularities of high-strength titanium alloy rolling sheets VT23 under conditions of the National Research Center «Kurchatov Institute» – VIAM. Computer modeling in a special software package was used to develop the alloy rolling regimes. Samples of the VT23 alloy were rolled at different temperatures, as a result, optimal regimes of hot and warm pressure treatment were obtained. The mechanical properties and structure of the obtained sheets were analyzed, which satisfy the required values.
Reference list
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2. Kablov E.N., Bakradze M.M., Gromov V.I., Voznesenskaya N.M., Yakusheva N.A. New high strength structural and corrosion-resistant steels for aerospace equipment developed by FSUE «VIAM» (review). Aviacionnye materialy i tehnologii, 2020, no. 1 (58), pp. 3–11. DOI: 10.18577/2071-9140-2020-0-1-3-11.
3. Nochovnaya N.A., Shiryaev A.A., Sharapkin D.S. Complex of mechanical and operational properties of rolled blanks from metastable-β-titanium alloy VT47. Aviation materials and technologies, 2022, no. 3 (68), paper no. 05. Available at: http://www.journal.viam.ru (accessed: September 17, 2024). DOI: 10.18577/2713-0193-2022-0-3-50-59.
4. 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: 10.18577/2071-91.
5. Khorev A.I. Complex-alloyed titanium alloy VT23 for universal use. Tekhnologiya mashinostroyeniya, 2007, no. 7, pp. 23–40.
6. Kablov E.N., Putyrskiy S.V., Yakovlev A.L., Krokhina V.A., Naprienko S.A. Study of fatigue fracture resistance of stampings made of high-strength titanium alloy VT22M, manufactured with final deformation in the (α+β)- and β-regions. Titan, 2021, vol. 70, no. 1, pp. 26–33.
7. Aviation materials: handbook in 13 vols. Moscow: VIAM, 2010, vol. 6: Titanium alloys, 95 p.
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9. Krokhina V.A., Arislanov А.A., Putyrskiy S.V., Anisimova A.Yu. Investigation of the regularities of the formation of the structure of rods made of titanium alloy VT6 depending on various technological schemes of manufacture. Aviation materials and technologies, 2023, no. 4 (73), paper no. 04. Available at: http://www.journal.viam.ru (accessed: September 17, 2024). DOI: 10.18577/2713-0193-2023-0-4-36-44.
10. Skugorev A.V., Kapitanenko D.V., Shishkov S.Yu., Melnikova D.A. Formation of the structure and mechanical properties of high-alloy titanium alloys during isothermal stamping in air. Titan, 2021, vol. 3 (72), pp. 34–40.
11. Shvetsov O.V., Kondratiev S.Yu. Influence of hardening and aging modes on the operational properties of VT23 alloy. Nauchno-tekhnicheskie vedomosti SPbGU. Estestvennye i inzhenernye nauki, 2018, vol. 24, no. 2, pp. 119–133.
12. Razuvaev E.I., Moiseev N.V., Kapitanenko D.V., Bubnov M.V. Modern technologies of plastic working of metals. Trudy VIAM, 2015, no. 2, paper no. 03. Available at: http://www.viam-works.ru (accessed: September 25, 2024). DOI: 10.18577/2307-6046-2015-0-2-3-3.
13. Duyunova V.A., Oglodkov M.S., Putyrskiy S.V., Kochetkov A.S., Zueva O.V. Modern technologies for melting titanium alloy ingots (review). Aviation materials and technologies, 2022, no. 1 (66), paper no. 03. Available at: http://www.journal.viam.ru (accessed: September 17, 2024). DOI: 10.18577/2713-0193-2022-0-1-30-40.
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2. Kablov E.N., Bakradze M.M., Gromov V.I., Voznesenskaya N.M., Yakusheva N.A. New high strength structural and corrosion-resistant steels for aerospace equipment developed by FSUE «VIAM» (review). Aviacionnye materialy i tehnologii, 2020, no. 1 (58), pp. 3–11. DOI: 10.18577/2071-9140-2020-0-1-3-11.
3. Nochovnaya N.A., Shiryaev A.A., Sharapkin D.S. Complex of mechanical and operational properties of rolled blanks from metastable-β-titanium alloy VT47. Aviation materials and technologies, 2022, no. 3 (68), paper no. 05. Available at: http://www.journal.viam.ru (accessed: September 17, 2024). DOI: 10.18577/2713-0193-2022-0-3-50-59.
4. 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: 10.18577/2071-91.
5. Khorev A.I. Complex-alloyed titanium alloy VT23 for universal use. Tekhnologiya mashinostroyeniya, 2007, no. 7, pp. 23–40.
6. Kablov E.N., Putyrskiy S.V., Yakovlev A.L., Krokhina V.A., Naprienko S.A. Study of fatigue fracture resistance of stampings made of high-strength titanium alloy VT22M, manufactured with final deformation in the (α+β)- and β-regions. Titan, 2021, vol. 70, no. 1, pp. 26–33.
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9. Krokhina V.A., Arislanov А.A., Putyrskiy S.V., Anisimova A.Yu. Investigation of the regularities of the formation of the structure of rods made of titanium alloy VT6 depending on various technological schemes of manufacture. Aviation materials and technologies, 2023, no. 4 (73), paper no. 04. Available at: http://www.journal.viam.ru (accessed: September 17, 2024). DOI: 10.18577/2713-0193-2023-0-4-36-44.
10. Skugorev A.V., Kapitanenko D.V., Shishkov S.Yu., Melnikova D.A. Formation of the structure and mechanical properties of high-alloy titanium alloys during isothermal stamping in air. Titan, 2021, vol. 3 (72), pp. 34–40.
11. Shvetsov O.V., Kondratiev S.Yu. Influence of hardening and aging modes on the operational properties of VT23 alloy. Nauchno-tekhnicheskie vedomosti SPbGU. Estestvennye i inzhenernye nauki, 2018, vol. 24, no. 2, pp. 119–133.
12. Razuvaev E.I., Moiseev N.V., Kapitanenko D.V., Bubnov M.V. Modern technologies of plastic working of metals. Trudy VIAM, 2015, no. 2, paper no. 03. Available at: http://www.viam-works.ru (accessed: September 25, 2024). DOI: 10.18577/2307-6046-2015-0-2-3-3.
13. Duyunova V.A., Oglodkov M.S., Putyrskiy S.V., Kochetkov A.S., Zueva O.V. Modern technologies for melting titanium alloy ingots (review). Aviation materials and technologies, 2022, no. 1 (66), paper no. 03. Available at: http://www.journal.viam.ru (accessed: September 17, 2024). DOI: 10.18577/2713-0193-2022-0-1-30-40.
14. Tsepin M.A., Begnarsky V.V., Lisunets N.L., Sinitsyn M.V., Erokhov M.A. Using specialized programs in developing technological processes for metal forming. Tsvetnye metally, 2007, no. 5, pp. 98–101.
15. Stebunov S.A., Biba N.V. Qform – a program created for technologists. Kuznechno-shtampovoe proizvodstvo. Obrabotka metallov davleniem, 2004, no. 9, pp. 38–43.
4.
dx.doi.org/ 10.18577/2307-6046-2025-0-3-33-46
УДК 678.8
Khrulkov A.V., Donetskiy K.I., Melnikov D.A., Klimenko O.N., Slavin A.V.
PREPREG TACK AS A FUNCTION OF VARIOUS PARAMETERS DURING LAYING OUT BLANKS OF PARTS AND SAMPLES FROM POLYMER COMPOSITE MATERIALS
Polymer composite materials are gradually replacing metals, including in such important structures as an aircraft wing or a fuselage. One of the technological stages in the manufacture of blanks for future parts is the process of laying out the prepreg on the tooling. When laying out, the stickiness of the prepreg plays an important role. The stickiness of the prepreg to the substrate should be such that it does not separate from it during transportation and is easily separated when moving onto the tooling. An analysis of the stickiness level depending on temperature, compaction force, and the speed of separation from the substrate is given in this article.
Reference list
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6. Bolshakov V.A., Antyufeeva N.V. Evaluation of the curing process model of the adhesive binder in prepreg. Aviation materials and technologies, 2023, no. 4 (73), paper no. 07. Available at: http://www.journal.viam.ru (accessed: August 02, 2024). DOI: 10.18577/2713-0193-2023-0-4-66-77.
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9. Tkachuk A.I., Lyubimova A.S., Kuznetcova P.A. Opportunities of the development of plant-based epoxy resins (review). Trudy VIAM, 2022, no. 8 (114), paper no. 04. Available at: http://www.viam-works.ru (accessed: November 08, 2023). DOI: 10.18577/2307-6046-2022-0-8-49-64.
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13. Postnov V.I., Veshkin E.A., Makrushin K.V., Sudin Yu.I. Technological features of manufacturing polymer composite materials of main rotor blades for a light helicopter. Aviation materials and technologies, 2023, no. 1 (70), paper no. 06. Available at: http://www.journal.viam.ru (accessed: December 04, 2023). DOI: 10.18577/2713-0193-2023-0-1-82-92.
14. Raskutin A.E. Russian polymer composite materials of new generation, their exploitation and implementation in advanced developed constructions. Aviacionnye materialy i tehnologii, 2017, no. S, pp. 349–367. DOI: 10.18577/2071-9140-2017-0-S-349-367.
15. Budelmann D., Schmidt C., Meiners D. Adhesion-cohesion balance of prepreg tack in thermoset automated fiber placement. Part 1: Adhesion and surface wetting. Composites Part C, 2023, no. 12, art. 100396.
16. Budelmann D., Schmidt C., Meiners D. Prepreg tack: A review of mechanisms, measurement, and manufacturing implication. Polymer Composites, 2020, no. 41, pp. 3440–3458. DOI: 10.1002/pc.25642.
17. Budelmann D. Tack of epoxy resin films for aerospace-grade prepregs: Influence of resin formulation, B-staging and toughening. Polymer Testing, 2022, no. 114, art. 107709.
18. Gerasimov S.B. Development of polymer composite materials for the manufacture of large-sized complex-profile products using the automated laying method: thesis, Cand. Sc. (Techn.). Moscow, 2000, p. 24.
19. Budelmann D., Schmidt C., Steuernagel L., Meiners D. Adhesion-cohesion balance of prepreg tack in thermoset automated fiber placement. Part 2: Ply-ply cohesion through contact formation and autohesion. Composites Part C, 2023, no. 12, art. 100396.
20. Postnov V.I., Nikitin K.E., Petukhov V.I., Burkhan O.L., Orzaev V.G. Method and device for determining the tack of prepregs. Aviacionnye materialy i tehnologii, 2009, no. 3, pp. 29–33.
21. Strelnikov S.V., Petukhov V.I., Postnov V.I., Shvets N.I. New solutions in the technology of manufacturing prepregs for interior panels. Izvestiya Samarskogo nauchnogo tsentra RAN, 2011, vol. 13, no. 4 (2), pp. 498–507.
22. Measuring techniques for prepreg tackiness: A COMPARATIVE STUDY SAMPE Europe Conference 2023 Madrid – Spain. Available at: https://www.researchgate.net/publication/374949895_Measuring_techniques_for_ prepreg_tackiness_A_comparative_study (available at: September 17, 2024).
23. Crossley R.J., Schubel P.J., Warrior N.A. The experimental determination of prepreg tack and dynamic stiffness. Composite Part A: Applied Science Manufacture, 2012, no. 43, pp. 423–434.
24. Heinecke F., Willberg C. Manufacturing-induced imperfections in composite parts manufactured via automated fiber placement. Experimental Mechanics, 2010, no. 50, pp. 599–606.
25. Experimental analysis of prepreg tack. Available at: https://inria.hal.science/hal-01131583/ (available at: September 17, 2024).
26. Tackiness characterization of thermoset prepreg materials. Available at: https://spectrum.library.concordia.ca/id/eprint/987702/1/Dodongeh_MASc_S2021.pdf (available at: September 17, 2024).
27. Mishkin S.I., Klimenko O.N., Kutcevich K.E. Determination of stickiness of prepregs on the basis of carbon fillers the sounding method. Trudy VIAM, 2018, no. 3 (109), paper no. 04. Available at: http://www.viam-works.ru (accessed: August 05, 2024). DOI: 10.18577/2307-6046-2022-0-3-35-43.
2. Slavin A.V., Donetskiy K.I., Khrulkov A.V. Prospects for the use of polymer composite materials in aircraft structures in 2025–2035 (review). Trudy VIAM, 2022, no. 11 (117), paper no. 08. Available at: http://www.viam-works.ru (accessed: September 05, 2024). DOI: 10.18577/2307-6046-2022-0-11-81-92.
3. Kablov E.N. The role of fundamental research in the creation of new generation materials. Reports of the XXI Mendeleev Congress on General and Applied Chemistry: in 6 vols. St. Petersburg, 2019, vol. 4, p. 24.
4. Onishchenko G.G., Kablov E.N., Ivanov V.V. Scientific and technological development of Russia in the context of achieving national goals: problems and solutions. Innovatsii, 2020, no. 6 (260), pp. 3–16.
5. Tkachuk A.I., Donetsky K.I., Terekhov I.V., Karavaev R.Yu. The use of thermosetting matrices for the manufacture of polymer composite materials by the non-autoclave molding methods. Aviation materials and technology, 2021, no. 1 (62), paper no. 03. Available at: https://www.journal.viam.ru (accessed: August 02, 2024). DOI: 10.18577/2713-0193-2021-0-1-22-33.
6. Bolshakov V.A., Antyufeeva N.V. Evaluation of the curing process model of the adhesive binder in prepreg. Aviation materials and technologies, 2023, no. 4 (73), paper no. 07. Available at: http://www.journal.viam.ru (accessed: August 02, 2024). DOI: 10.18577/2713-0193-2023-0-4-66-77.
7. Startsev V.O., Antipov V.V., Slavin A.V., Gorbovets M.A. Modern domestic polymer composite materials for aviation industry (review). Aviation materials and technologies, 2023, no. 2 (71), paper no. 10. Available at: http://www.journal.viam.ru (accessed: August 02, 2024). DOI: 10.18577/2713-0193-2023-0-2-122-144.
8. Mukhametov R.R., Petrova A.P. Thermosetting binders for polymer composite materials: textbook. Ed. E.N. Kablov. Moscow: NRC «Kurchatov Institute» – VIAM, 2021, p. 363.
9. Tkachuk A.I., Lyubimova A.S., Kuznetcova P.A. Opportunities of the development of plant-based epoxy resins (review). Trudy VIAM, 2022, no. 8 (114), paper no. 04. Available at: http://www.viam-works.ru (accessed: November 08, 2023). DOI: 10.18577/2307-6046-2022-0-8-49-64.
10. Kogan D.I., Chursova L.V., Panina N.N. et al. Promising polymeric materials for structural composite products with energy-efficient molding mode. Plasticheskie massy, 2020, no. 3–4, pp. 52–54.
11. Veshkin E.A. Technologies for non-autoclave molding of low-porosity polymer composite materials and large-sized structures made of them: thesis, Cand. Sc. (Tech.). Moscow, 2016, 146 p.
12. Erasov V.S., Sibayev I.G. Scheme for the development and evaluation of properties of structural aviation composite materials. Aviation materials and technologies, 2023, no. 1 (70), paper no. 05. Available at: http://www.journal.viam.ru (accessed: December 04, 2023). DOI: 10.18577/2713-0193-2023-0-1-61-81.
13. Postnov V.I., Veshkin E.A., Makrushin K.V., Sudin Yu.I. Technological features of manufacturing polymer composite materials of main rotor blades for a light helicopter. Aviation materials and technologies, 2023, no. 1 (70), paper no. 06. Available at: http://www.journal.viam.ru (accessed: December 04, 2023). DOI: 10.18577/2713-0193-2023-0-1-82-92.
14. Raskutin A.E. Russian polymer composite materials of new generation, their exploitation and implementation in advanced developed constructions. Aviacionnye materialy i tehnologii, 2017, no. S, pp. 349–367. DOI: 10.18577/2071-9140-2017-0-S-349-367.
15. Budelmann D., Schmidt C., Meiners D. Adhesion-cohesion balance of prepreg tack in thermoset automated fiber placement. Part 1: Adhesion and surface wetting. Composites Part C, 2023, no. 12, art. 100396.
16. Budelmann D., Schmidt C., Meiners D. Prepreg tack: A review of mechanisms, measurement, and manufacturing implication. Polymer Composites, 2020, no. 41, pp. 3440–3458. DOI: 10.1002/pc.25642.
17. Budelmann D. Tack of epoxy resin films for aerospace-grade prepregs: Influence of resin formulation, B-staging and toughening. Polymer Testing, 2022, no. 114, art. 107709.
18. Gerasimov S.B. Development of polymer composite materials for the manufacture of large-sized complex-profile products using the automated laying method: thesis, Cand. Sc. (Techn.). Moscow, 2000, p. 24.
19. Budelmann D., Schmidt C., Steuernagel L., Meiners D. Adhesion-cohesion balance of prepreg tack in thermoset automated fiber placement. Part 2: Ply-ply cohesion through contact formation and autohesion. Composites Part C, 2023, no. 12, art. 100396.
20. Postnov V.I., Nikitin K.E., Petukhov V.I., Burkhan O.L., Orzaev V.G. Method and device for determining the tack of prepregs. Aviacionnye materialy i tehnologii, 2009, no. 3, pp. 29–33.
21. Strelnikov S.V., Petukhov V.I., Postnov V.I., Shvets N.I. New solutions in the technology of manufacturing prepregs for interior panels. Izvestiya Samarskogo nauchnogo tsentra RAN, 2011, vol. 13, no. 4 (2), pp. 498–507.
22. Measuring techniques for prepreg tackiness: A COMPARATIVE STUDY SAMPE Europe Conference 2023 Madrid – Spain. Available at: https://www.researchgate.net/publication/374949895_Measuring_techniques_for_ prepreg_tackiness_A_comparative_study (available at: September 17, 2024).
23. Crossley R.J., Schubel P.J., Warrior N.A. The experimental determination of prepreg tack and dynamic stiffness. Composite Part A: Applied Science Manufacture, 2012, no. 43, pp. 423–434.
24. Heinecke F., Willberg C. Manufacturing-induced imperfections in composite parts manufactured via automated fiber placement. Experimental Mechanics, 2010, no. 50, pp. 599–606.
25. Experimental analysis of prepreg tack. Available at: https://inria.hal.science/hal-01131583/ (available at: September 17, 2024).
26. Tackiness characterization of thermoset prepreg materials. Available at: https://spectrum.library.concordia.ca/id/eprint/987702/1/Dodongeh_MASc_S2021.pdf (available at: September 17, 2024).
27. Mishkin S.I., Klimenko O.N., Kutcevich K.E. Determination of stickiness of prepregs on the basis of carbon fillers the sounding method. Trudy VIAM, 2018, no. 3 (109), paper no. 04. Available at: http://www.viam-works.ru (accessed: August 05, 2024). DOI: 10.18577/2307-6046-2022-0-3-35-43.
5.
dx.doi.org/ 10.18577/2307-6046-2025-0-3-47-59
УДК 678.83
Kulagina G.S., Nasonov F.A., Zhelezina G.F., Demina A.S., Solovjova N.A., Morozov B.B., Shuldeshova P.M., Filatov A.A.
ANTIFRICTION AND CONSTRUCTIONAL ORGANOPLASTICS FOR ELEMENTS OF DESIGNS OF AIRPLANES OF DEVELOPMENT SUKHOI DESIGN BUREAU
Tests of details of airplanes of Sukhoi Design Bureau are executed. Details are made of prepregs of antifriction material and constructive organoplastiсs. Efficiency of antifriction material and constructional organoplastiсs for raising resistance to antifriction loss and for increasing resource of moving elements of an airplane mechanization, as well as fixed parts, which are in contact, are shown. The possibility of production of mechanization elements of an airplane by means of the co-forming prepregs of antifriction and constructive organoplastiсs has been proved.
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2. Kablov E.N., Shevchenko Yu.N., Grinevich A.V. Problems of certification of aviation materials at the present stage. 75 years. Aviation materials. Selected works of VIAM 1932–2007. Ed. E.N. Kablov. Moscow: VIAM, 2007, pp. 388–396.
3. Kablov E.N. Innovative developments of FSUE «VIAM» SSC of RF on realization of «Strategic directions of the development of materials and technologies of their processing for the period until 2030». Aviacionnye materialy i tehnologii, 2015, no. 1 (34), pp. 3–33. DOI: 10.18577/2071-9140-2015-0-1-3-33.
4. Startsev V.O., Antipov V.V., Slavin A.V., Gorbovets M.A. Modern domestic polymer composite materials for aviation industry (review). Aviation materials and technologies, 2023, no. 2 (71), paper no. 10. Available at: http://www.journal.viam.ru (accessed: January 26, 2024). DOI: 10.18577/2713-0193-2023-0-2-122-144.
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6.
dx.doi.org/ 10.18577/2307-6046-2025-0-3-60-69
УДК 678.8
Ivanov M.S., Morozova V.S., Pavlukovich N.G.
INFLUENCE OF TECHNOLOGICAL MODES OF MANUFACTURE ON PROPERTIES OF CONSOLIDATED PLATES OF CARBON FIBER REINFORCED THERMOPLASTIC BASED ON POLYETHERETHERKETONE
In the article has been studied dependence of properties of consolidated plates of carbon fiber reinforced thermoplastic based on polyetheretherketone and woven carbon filler on the technological parameters of manufacture: pressure and temperature of pressing, time and cooling rate under pressure, as well as the melt flow rate of polyetheretherketone at a given temperature. The influence of technological molding parameters on the level of consolidation of carbon fiber reinforced thermoplastic plates was assessed using non-destructive testing methods and by determination of their mechanical properties.
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19. Pavlukovich N.G., Ivanov М.S., Morozova V.S., Donskih I.N. Investigation of the thermal stability of the melt polyetheretherketone PEEK-50P and carbon fiber based on it. Aviation materials and technologies, 2024, no. 2 (75), paper no. 07. Available at: http://www.journal.viam.ru (accessed: September 13, 2024). DOI: 10.18577/2713-0193-2024-0-2-90-98.
20. Vasconcelos G.C., Mazur R.L., Ribeiro B., Botehlo E. Evaluation of Decomposition Kinetics of Poly (Ether-Ether-Ketone) by Thermogravimetric Analysis. Materials Research, 2014, vol. 17 (1), pp. 227–235.
21. 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: September 13, 2024). DOI: 10.18577/2307-6046-2021-0-5-105-113.
2. Erasov V.S., Sibayev I.G. Scheme for the development and evaluation of properties of structural aviation composite materials. Aviation materials and technologies, 2023, no. 1 (70), paper no. 05. Available at: http://www.journal.viam.ru (accessed: September 13, 2024). DOI: 10.18577/2713-0193-2023-0-1-61-81.
3. Startsev V.O., Antipov V.V., Slavin A.V., Gorbovets M.A. Modern domestic polymer composite materials for aviation industry (review). Aviation materials and technologies, 2023, no. 2 (71), paper no. 10. Available at: http://www.journal.viam.ru (accessed: 13.09.2024). DOI: 10.18577/2713-0193-2023-0-2-122-144.
4. Gunyaev G.M., Kablov E.N. Structural carbon fiber reinforced plastics at the turn of the century. Aviation materials. Selected works of «VIAM» 1932–2002. Moscow: VIAM, 2002, pp. 242–247.
5. Kablov E.N. Trends and guidelines for innovative development of Russia: collection of scientific and information materials. 3rd ed. Moscow: VIAM, 2015, 720 p.
6. Kablov E.N. What to make the future of? New generation materials, technologies for their creation and processing – the basis of innovations. Krylya Rodiny, 2016, no. 5, pp. 8–18.
7. Sorokin A.E., Ivanov M.S., Sagomonova V.A. Thermoplastic polymer composite materials based on polyetheretherketones of various manufacturers. Aviation materials and technologies, 2022, no. 1 (66), paper no. 04. Available at: http://www.journal.viam.ru (accessed: October 02, 2024). DOI: 10.18577/2713-0193-2022-0-1-41-50.
8. Ivanov M.S., Sorokin A.E. Sheet thermoplastic carbon fiber based on polyetheretherketone for the manufacture of aircraft engine nacelle parts by thermoforming. Proc. V All-Rus. scientific-technical conf. «Polymer composite materials and production technologies of the new generation». Moscow: NRC «Kurchatov Institute» – VIAM, 2021, art. 03.
9. Beev A.A., Khashirova S.Yu., Beeva D.A., Shokumova M.U. Powdered aromatic polyetheretherketones and copolyetheretherketones. Plasticheskie massy, 2022, no. 7–8, pp. 6–9. DOI: 10.35164/0554-2901-2022-7-8-6-9.
10. Mikitaev A.K., Salamov A.Kh., Beev A.A., Beeva D.A. Filling of polyetheretherketones (PEEK) as a method for producing composites with high performance properties. Plasticheskie massy, 2017, no. 5–6, pp. 6–9. DOI: 10.35164/0554-2901-2017-5-6-6-9.
11. Lyashenko E.Yu., Yakovleva K.A., Andreeva T.I. et al. Composite materials based on polyetheretherketone. Plasticheskie massy, 2023, no. 1–2, pp. 11–13. DOI: 10.35164/0554-2901-2023-1-2-11-13.
12. Kharaev A.M., Bazheva R.Ch. Polyetheretherketones: synthesis, properties, application (review). Plasticheskie massy, 2018, no. 7–8, pp. 15–23. DOI: 10.35164/0554-2901-2018-7-8-15-23.
13. May R. Polyetheretherketones. Encyclopedia of Polymer Science and Technology. Wiley, 2008, pp. 1–9. DOI: 10.1002/0471440264.pst266.
14. Method for producing polyetheretherketone: pat. 2673242 Rus. Federation; appl. 27.06.18; publ. 23.11.18.
15. Kolpachkov E.D., Petrova A.P., Kurnosov A.O., Sokolov I.I. Methods of molding aviation products from PCM (review). Trudy VIAM, 2019, no. 11 (83), paper no. 03. Available at: http://www.viam-works.ru (accessed: September 13, 2024). DOI: 10.18577/2307-6046-2019-0-11-22-36.
16. Illig A., Shvatsman P. Thermoforming: A Practical Guide. St. Petersburg: Profession, 2007, 288 p.
17. Wilkinson S.L. Optimisation of the stamp forming process for thermoplastic composites. University of Bristol, 2021, 167 р.
18. De Almeida O., Bessard E., Bernhart G. Influence of processing parameters and semi-finished product on consolidation of carbon/PEEK laminates. 15th European Conference on Composite Materials. 2012. URL: https://www.researchgate.net/publication/287042143 (accessed: September 13, 2024).
19. Pavlukovich N.G., Ivanov М.S., Morozova V.S., Donskih I.N. Investigation of the thermal stability of the melt polyetheretherketone PEEK-50P and carbon fiber based on it. Aviation materials and technologies, 2024, no. 2 (75), paper no. 07. Available at: http://www.journal.viam.ru (accessed: September 13, 2024). DOI: 10.18577/2713-0193-2024-0-2-90-98.
20. Vasconcelos G.C., Mazur R.L., Ribeiro B., Botehlo E. Evaluation of Decomposition Kinetics of Poly (Ether-Ether-Ketone) by Thermogravimetric Analysis. Materials Research, 2014, vol. 17 (1), pp. 227–235.
21. 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: September 13, 2024). DOI: 10.18577/2307-6046-2021-0-5-105-113.
7.
dx.doi.org/ 10.18577/2307-6046-2025-0-3-70-88
УДК 666.3
Butuzov A.V., Semina A.V.
PRECERAMIC POLYMERS FOR THE PRODUCTION OF CERAMIC PRODUCTS BY VAT PHOTOPOLYMERIZATION Part 1. METHODS OF PRODUCTION AND PROPERTIES
The first part of the review considers the main types of preceramic organosilicon polymers and the types of their polymer derived ceramics formed during pyrolysis. An analysis of scientific-technical literature and patent sources of information on methods of synthesis, chemical modification, physico-chemical properties, main manufacturers and areas of application of organosilicon polymers is carried out. The main structural factors of preceramic polymers are described, which make it possible to vary the entire complex of physico-chemical properties of a ceramic material in a wide range.
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8.
dx.doi.org/ 10.18577/2307-6046-2025-0-3-89-100
УДК 678.8
Startsev V.O., Startsev O.V., Pavlov M.R., Nechaev A.A.
STRENGTH AND MOISTURE RESISTANCE OF FIBERGLASS PLASTIC VPS-53/T-25 AT THE INITIAL STAGE OF NATURAL AND ACCELERATED AGING
Comparative tests of the resistance of fiberglass VPS-53/T-25 to aging were conducted during exposure in natural conditions of moderately warm and moderate climate for 3 and 6 months and to simulating effects in two modes of laboratory accelerated tests. It was found that during 6 months of exposure the strength of fiberglass decreased by 7 %, while the moisture diffusion coefficient increased by 60 and 120 % accordingly. The prospects of using Fick and Langmuir models for comparing the effects of composite materials aging during tests in natural and laboratory conditions were shown.
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9.
dx.doi.org/ 10.18577/2307-6046-2025-0-3-101-116
УДК 620.1
Erasov V.S., Sibayev I.G., Sutubalov A.I.
SLICE TESTING OF STRUCTURAL AVIATION MATERIALS AND COATINGS
The article provides an analysis of domestic and foreign methods of mechanical testing of structural aviation composite materials and coatings on a slice. The types of cross-section fittings and their main differences are presented. The development of testing methods by instrumental indentation and scratching (sclerometry) is shown, in which destruction occurs by cutting the material with an indenter. A typical slice diagram in the coordinates «load‒displacement of the punch», diagrams of embedding and scratching with indentors, photographs of scratches without destruction and with traces of destruction on the deformable surface are presented.
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17. Golovin Yu.I. Nanoindentation and mechanical properties of materials at the submicro- and nanoscale. Recent results and achievements (Review). Fizika tverdogo tela, 2021, vol. 63, is. 1, pp. 3–42. DOI: 10.21883/FTT.2021.01.50395.171.
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19. ISO 14577-2:2015. Metallic materials ‒ Instrumented indentation test for hardness and materials parameters – Part 2: Verification and calibration of testing machines. International Organization for Standardization, 2015, 32 p.
20. ISO 14577-3:2015. Metallic materials ‒ Instrumented indentation test for hardness and materials parameters ‒ Part 3: Calibration of reference blocks. International Organization for Standardization, 2015, 16 p.
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25. State Standard R 56232‒2014. Determination of the stress-strain diagram by the instrumental indentation of a ball. General requirements. Moscow: Standartinform, 2018, 41 p.
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27. State Standard R 8.904‒2015. State system for ensuring the uniformity of measurements. Measurement of hardness and other characteristics of materials by instrumental indentation. Part 2. Verification and calibration of hardness testers. Moscow: Standartinform, 2018, 30 p.
28. State Standard R 8.907–2015. State verification scheme for hardness measuring instruments according to the Martens and indentation scales. Moscow: Standartinform, 2018, 8 p.
29. Marchenkov A.Yu., Terentyev E.V. Scale effect in scratch tests of materials with different deformable volumes. Zavodskaya laboratoriya. Diagnostika materialov, 2017, vol. 83, no. 9, pp. 66‒69.
30. Brinkevich D.I., Prosolovich V.S., Yankovsky Yu.N. et al. Sclerometric method for measuring the microhardness of photoresist on silicon. Pribory i metody izmereniy, 2016, vol. 7, no. 1. 77–84. DOI: 10.21122/2220-9506-7-1-77-84.
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10.
CONTENТS
Light-metal alloys
Dobrynin D.A., Pavlova T.V. Electrolyte-plasma polishing of parts made by selective laser sintering from metal powder composition of aluminum alloy grade VAS1. Part 2
Astashkin A.I., Babanov V.V., Selivanov A.A., Tkachenko E.A. Influence of homogenization modes of ingots and heat treatment of sheets from alloy V95oсh-Т2 on their structure and properties
Yashin M.S., Kapitanenko D.V. Investigation of thermo-mechanical parameters of hot and warm rolling of titanium alloy VT23 type
Polymer materials
Khrulkov A.V., Donetsky K.I., Melnikov D.A., Klimenko O.N., Slavin A.V. Prepreg tack as a function of various parameters during laying out blanks of parts and samples from polymer composite materials
Kulagina G.S., Nasonov F.A., Zhelezina G.F., Demina A.S., Solovyeva N.A., Morozov B.B., Shuldeshova P.M., Filatov A.A. Antifriction and constructional organoplastics for elements of designs of airplanes of development Sukhoi design bureau
Composite materials
Ivanov M.S., Morozova V.S., Pavlukovich N.G. Influence of technological modes of manufacture on properties of consolidated plates of carbon fiber reinforced thermoplastic based on polyetheretherketone
Butuzov A.V., Semina A.V. Preceramic polymers for the production of ceramic products by vat photopolymerization. Part 1. Methods of production and properties
Startsev V.O., Startsev O.V., Pavlov M.R., Nechaev A.A. Strength and moisture resistance of fiberglass plastic VPS-53/T-25 at the initial stage of natural and accelerated aging
Material tests
Erasov V.S., Sibayev I.G., Sutubalov A.I. Slice testing of structural aviation materials and coatings