ДОСЛІДЖЕННЯ МЕХАНІЗМІВ РУЙНУВАННЯ І ЗАХИСТУ СКЛАДНИХ ТЕРМОДИНАМІЧНИХ СИСТЕМ
DOI:
https://doi.org/10.30890/2709-2313.2023-23-01-015Ключові слова:
Mechanism of destruction, heat flow, load, protection system, coating, insulationАнотація
The successful application of basic and protective materials of components of complex thermodynamic systems depends on the extent to which the behavior and properties of materials are studied in detail under different conditions and during real operation.Metrics
Посилання
Lobunko O.P., Iskra O.O. Substantiation of the protection system's configuration for the reusable spacecraft. III International Scientific and Practical Conference science in the environment of rapid changes: materials of the International Scientific and Practical Conference, Belgium, 2023. P. 189-194.
Lobunko O., Iskra O. Mathematical Modeling of the Thermal Conditions of Aerospace Products" Protection Systems. International Scientific and Technical Conference "Sensors, Devices and Systems - 2023": Proceedings of the International Scientific and Technical Conference, Ukraine, Cherkasy, 2023. Р. 8-10.
Lobunko O.P. Simulation of degradation of individual characteristics of gas turbine engine components. XXXI International scientific and practical conference "Science, worldview and modern youth": materials of the International Scientific and Practical Conference, USA, San Francisco, August 8-11, 2023. P. 118-123. ISBN 979-8-89074-562-0, doi - 10.46299/ISG.2023.1.31.
Polezhayev Y.V., Frolov G.A. Thermal destruction of materials. Kyiv: IPM, 2005. 288 p.
Lobunko O.P., Makarevych I.M. Directions for improving algorithms for monitoring and predicting the technical condition of aircraft engines. Collection of scientific works of the SRIA. Kyiv, 2005, issue 1(8). Р. 89-94.
Karpinos B.S., Korovin A.V., Lobunko O.P., Vedishcheva M.Y. Operational damage of aircraft turbojet twin-circuit engines with afterburners. Journal Vesnik dyvtomobilnosti. Zaporizhzhya, 2014. Р. 18-24.
Karpinos B.S., Lobunko O.P., Grenj V.M., Korovin O.V. Computer modeling of operational states of the fuel manifold of an aircraft engine. Collection of scientific papers of the SRIA. Kyiv, 2013, issue 9(16), Р. 174 179.
Karpinos B.S., Lobunko O.P., Kuzmin S.M., Gren V.M. Methods for predicting the durability of structural elements of aircraft power plants based on modeling the stress state and the influence of operational factors. Collection of scientific works of the SRIA. Kyiv, 2014, issue 10(17). P. 183-187.
Lobunko O.P., Yarovitsyn O.V. Modern scientific and technological aspects of repair of aircraft engine parts. Collection of scientific papers of the SRIA. Kyiv, 2019, issue №15 (22). Р.153-160.
Yushchenko K.A., Lobunko O.P. Systematization and certification of standard technologies for the repair of aircraft parts. SPC "Actual Problems of Aviation Equipment Development". Kyiv, 2012. p. 37.
Piacquadio, S., Pridöhl, D., Henkel, N., Bergström, R., Zamprotta, A., Dafnis, A., & Schröder, K.-U. (2023). Comprehensive Comparison of Different Integrated Thermal Protection Systems with Ablative Materials for Load-Bearing Components of Reusable Launch Vehicles. Aerospace, 10, 319. https://doi.org/10.3390/aerospace10030319.
Xu, Q., Li, S., & Meng, Y. (2021). Optimization and Re-Design of Integrated Thermal Protection Systems Considering Thermo-Mechanical Performance. Applied Sciences, 11. https://doi.org/10.3390/app11156916.
Wang, S., Gao, F., Liu, H., Zhang, J., Fan, M., & Yang, K. (2021). Study on the influence of the thermal protection material on the heat dissipation of the battery pack for energy storage. E3S Web of Conferences, 252. https://doi.org/10.1051/e3sconf/202125202045.
Naito, M., Kodaira, S., Ogawara, R., Tobita, K., Someya, Y., Kusumoto, T., Kusano, H., Kitamura, H., Koike, M., Uchihori, Y., Yamanaka, M., Mikoshiba, R., Endo, T., Kiyono, N., Hagiwara, Y., Kodama, H., Matsuo, S., Takami, Y., Sato, T., & Orimo, S. (2020). Investigation of shielding material properties for effective space radiation protection. Life Sciences in Space Research, 26, 69-76. https://doi.org/10.1016/j.lssr.2020.05.001.
Ma, S., Zhang, S., Wu, J., Zhang, Y., Chu, W., & Wang, Q. (2023). Experimental Study on Active Thermal Protection for Electronic Devices Used in Deep—Downhole—Environment Exploration. Energies, 16, 1231. https://doi.org/10.3390/en16031231.
Hilorme, T., Nakashydze, L., Mazyrik, S., Gabrinets, V., Kolbunov, V., & Gomilko, I. (2022). Substantiation for the selection of parameters for ensuring electro-thermal protection of solar batteries in spacecraft power systems. Eastern-European Journal of Enterprise Technologies, 3 (8 (117)), 17-24. https://doi.org/10.15587/1729-4061.2022.258480.
Gupta, R.K., Ramkumar, P. (2015). Titanium Aluminides for Metallic Thermal Protection System of Reusable Space Transportation Vehicle: A Review. Frontiers in Aerospace Engineering, 4 (1). http://doi.org/10.12783/fae.2015.0401.02.
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