Study of water absorption process of hollow-fiber fiberglass based on analysis of nature-like technologies

Kopylov A.V., Prokopenkov V.G., Slavin A.V., Kurnosov A.O.
Kopylov A.V., Prokopenkov V.G., Slavin A.V., Kurnosov A.O. Study of water absorption process of hollow-fiber fiberglass based on analysis of nature-like technologies // Proceedings of VIAM. 2025. No. 7. DOI: 10.18577/2307-6046-2025-0-7-61-80. URL: https://test.viam.ru/en/journal/2025/7/5
Keywords
fiberglass, hollow glass fibers, water absorption, microchannels, nature-like technologies
Abstract

Based on the results of microstructural studies, the structural features of hollow-fiber fiberglass samples before their water absorption testing are considered. An analysis of changes in the density of hollow-fiber fiberglass samples measured by hydrostatic weighing is performed depending on the number of days during long-term water absorption. A study of the water absorption process of hollow-fiber fiberglass samples is performed based on the analysis of nature-like technologies − similar systems and models of water absorption that exist in nature.

Reference list
  1. Muhametov R.R., Petrova A.P., Ponomarenko S.A., Ahmadieva K.R., Pavlyuk B.F. Influence of woven fibrous fillers of various types on properties of cured binder VS-2526K. Trudy VIAM, 2018, no. 3 (63), paper no. 04. Available at: http//www.viam-works.ru (accessed: April 14, 2025). DOI: 10.18577/2307-6046-2018-0-3-28-36.
  2. Frantsev M.E., Kireynov A.V. Results of comparative tests of composite materials for shipbuilding purposes based on glass and basalt fibers on a polyester binder for water absorption. Transportnye sistemy, 2019, no. 1 (11), pp. 41–48. DOI: 10.46960/62045_2019_1_41.
  3. Dushin M.I., Hrulkov A.V., Muhametov R.R., Chursova L.V. Features of manufacturing of products from PCM impregnation method under pressure. Aviacionnye materialy i tehnologii, 2012, no. 1, pp. 18–26.
  4. Masket M. Flow of homogeneous liquids in a porous medium. Moscow; Leningrad: Gostoptekhizdat, 1949, 58 p.
  5. Leibenzon L.S. Movement of natural liquids and gases in a porous medium. Moscow; Leningrad: Gostoptekhizdat, 1947, 40 p.
  6. Proctor P. Stitched composite wings eyed for future transports. Aviation Week & Space Technology, 1998, no. 8, pp. 49−50.
  7. Vinogradov V.M., Goncharenko V.A., Komarov G.V. Modeling in the technology of polymer parts and products. Plasticheskie massy, 2005, no. 1, pp. 36–39.
  8. Ponomareva I.N., Mordvinov V.A. Underground hydromechanics: textbook. Perm: Perm State Technical Univ., 2009, 137 p.
  9. Basniev K.S., Dmitriev N.M., Rozenberg G.D. Oil and gas hydromechanics: textbook for universities. Moscow; Izhevsk: Institute of Computer Research, 2003, 479 p.
  10. Basniev K.S., Dmitriev N.M., Kanevskaya R.D., Maksimov V.M. Underground hydromechanics. 2nd ed., cor. Moscow; Izhevsk: Institute of Computer Research, 2006, 488 p.
  11. Kanevskaya R.D. Mathematical Modeling of Hydrodynamic Processes of Hydrocarbon Deposit Development: textbook for univ. Moscow; Izhevsk: Institute of Computer Research, 2003, 128 p.
  12. Shchelkachev V.N., Lapuk B.B. Underground Hydraulics: textbook for univ. Moscow; Izhevsk: Regular and Chaotic Dynamics, 2001, 736 p.
  13. Evdokimova V.A., Kochina I.N. Collection of Problems in Underground Hydraulics: textbook for univ. 2nd ed., reprinted from the original ed. 1979. Moscow: Alliance, 2007, 169 p.
  14. Komarova E.A. Features of the anatomical structure of the stem and spike rachis of triticale varieties in connection with spike productivity and lodging resistance: thesis abstract, Cand. Sc. (Bio.). Moscow: Rus. State Agrarian University – Moscow Agricultural Academy named after K.A. Timiryazev, 2007, 22 p.
  15. Mineev A.P. On tall trees. Moscow: Quantum, 1992, pp. 10–15.
  16. Muhametov R.R., Ahmadieva K.R., Chursova L.V., Kogan D.I. New polymeric binding for perspective methods of manufacturing of constructional fibrous PCM. Aviacionnye materialy i tekhnologii, 2011, no. 2, pp. 38–42.
  17. Deleglise M. Modeling of high speed RTM injection with highly reactive resin with on-line mixing. Applied Science and Manufacturing, 2011, vol. 42 (10), pp. 1390–1397.
  18. Graf M., Fries E., Renkl J. et al. High-Pressure Resin Transfer Molding – Process Advancements. 10-th Annual automotive composites conferences and exhibition ACCE. Los Angeles, 2010, pp. 15–16.
  19. Mouton S., Teissandier D., Sebastian P., Nadeau J.P. Manufacturing requirements in design: The RTM process in aeronautics. Composites. Part A: Applied Science and Manufacturing, 2010, vol. 41, no. 1, pp. 125–130.
  20. Kablov E.N. The role of chemistry in the creation of new generation materials for complex technical systems. Reports XX Mendeleev Congress on General and Applied Chemistry. Ekaterinburg: Ural Branch of the RAS, 2016, pp. 25–26.
  21. Guseva M.A., Sinyakov S.D., Dolgova E.V., Ponomarenko S.A. Study of the effect of the properties of phenol-formaldehyde resin and the curing mode on the characteristics of the FN binder. Aviation materials and technologies, 2022, no. 2 (67), paper no. 06. Available at: http://www.journal.viam.ru (accessed: April 23, 2025). DOI: 10.18577/2713-0193-2022-0-2-63-73.
  22. Malysheva G.V., Marakhovskiy P.S., Barinov D.Ya., Nikolaev E.V. Optimization of the curing modes of fiber-glass based on epoxy binder. Aviation materials and technologies, 2023, no. 2 (71), paper no. 08. Available at: http://www.journal.viam.ru (accessed: April 23, 2025). DOI: 10.18577/2713-0193-2023-0-2-94-103.
  23. Belinis P.G., Lukyanenko Yu.V., Rogozhnikov V.N., Tsykun R.G., Donetskiy K.I. Design research on a constructural multilayer woven preform of an integral panel fragment for aircraft. Aviation materials and technologies, 2023, no. 3 (72), paper no. 09. Available at: http://www.journal.viam.ru (accessed: April 23, 2025). DOI: 10.18577/2713-0193-2023-0-3-114-124.
  24. Puzyretskiy E.A., Donetski K.I., Shabalin L.P., Karavaev R.Yu., Savinov D.V. Theoretical and experimental study of the vacuum forming of semipregs based on carbon fillers (tapes and fabric) and melting epoxy binding. Aviation materials and technologies, 2024, no. 2 (75), paper no. 08. Available at: http://www.journal.viam.ru (accessed: April 23, 2025). DOI: 10.18577/2713-0193-2024-0-2-109-121.
  25. Grigoriev V.A., Kalabukhov D.S., Zakharchenko V.S. et al. Fundamentals of the theory, calculation and design of air-breathing engines: textbook for universities. Samara: Publ. house of Samara Univ., 2021, 67 p.
  26. Echo of black holes. Modcos. Available at: https://www.modcos.com/articles.php?id=138 (accessed: April 17, 2025).
  27. Hydrogasdynamics. Calculation of the Laval nozzle. Reshebnik. Available at: https://reshebnik.su/node/11234 (accessed: April 17, 2025).
  28. Microstrobe II – Dantec Dynamics. Precision Measurement Systems & Sensors. Dantecdynamics. Available at: https://www.dantecdynamics.com/components/microstrobe-ii/?sourceid=13683 (accessed: April 17, 2025).
  29. Measurement Principles of PIV. Dantecdynamics. Available at: https://www.dantecdynamics.com/solutions/fluid-mechanics/particle-image-velocimetry-piv/measurement-principles-of-piv/ (accessed: April 17, 2025).
  30. The principle of the PIV method. Laser-portal. Available at: https://www.laser-portal.ru/content_185 (accessed: April 17, 2025).