Study of ablative properties of carbon thermal protection materials

G. Ya. Gerasimov; Герасимов Г. Я.; V. Yu. Levashov; Левашов В. Ю.; P. V. Kozlov; Козлов П. В.; N. G. Bykova; Быкова Н. Г.; I. E. Zabelinsky; Забелинский И. Е.

doi:10.31857/S0207401X25040048

Study of ablative properties of carbon thermal protection materials

Autores: Gerasimov G.Y.¹, Levashov V.Y.², Kozlov P.V.², Bykova N.G.², Zabelinsky I.E.²
Afiliações:
1. Lomonosov Moscow State University, Moscow
2. Lomonosov Moscow State University
Edição: Volume 44, Nº 4 (2025)
Páginas: 31-45
Seção: Combustion, explosion and shock waves
URL: https://journal-vniispk.ru/0207-401X/article/view/288402
DOI: https://doi.org/10.31857/S0207401X25040048
ID: 288402

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The current state of research on the study of the ablative properties of carbon thermal protection materials for spacecraft is considered in relation to the conditions of spacecraft motion in the Earth’s atmosphere. Various carbon/polymer composites, which are the main and most versatile class of thermal protection materials due to their ability to adapt to various thermal loads, are analyzed. A critical review of the physicochemical processes occurring during ablation of carbon-containing composites, as well as methods for their modeling, is made. An analysis of experimental facilities used to study the ablative properties of carbon thermal protection materials is carried out, as well as their operating principles, potential use and limitations.

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thermal protection materials, ablation processes, plasma afcilities, heat transfer, heterogeneous reactions

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Rússia, Moscow

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2. Fig. 1. Application areas of reusable (REUS) and ablative (ABL) TPS materials depending on the altitude H, pressure p and velocity V of the descent vehicle in the Earth’s atmosphere: 1 – Space Shuttle, 2 – Apollo, 3 – return from Mars, 4 – return from distant planets.

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3. Fig. 2. Microstructure of the carbon filler of TPS material: a – felt and b – foam [49].

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4. Fig. 3. The main ablation processes occurring on the surface of TPS material at high temperatures.

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5. Fig. 4. Micrographs of graphite material before (a) and after (b) exposure to nitrogen plasma [56].

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6. Fig. 5. Photograph of the test chamber of the electric arc plasma installation [41]. The arrow shows the flow of low-temperature plasma.

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7. Fig. 6. Schematic diagram of the experimental setup [20] for studying laser ablation of a C/C composite: 1 – excimer laser, 2 – vacuum chamber, 3 – ablation product torch, 4 – sample, 5 – UV lenses, 6 – ICCD camera, 7 – spectrometer, 8 – optical fiber.

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8. Fig. 7. Schematic representation of the test section of the X2 impact unit [79]: 1 – impact unit nozzle, 2 – model support stand, 3 – copper electrodes, 4 – graphite model.

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9. Fig. 8. Comparison of the calculated spectra of the radiative heat flux Q at the braking point without taking into account (1) and taking into account (2) the chemical ablation process during the movement of the Stardust spacecraft in the Earth’s atmosphere [29].

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Volume 44, Nº 5 (2025)

Volume 44, Nº 5 (2025)

Study of ablative properties of carbon thermal protection materials

Texto integral

Resumo

Palavras-chave

Texto integral

Sobre autores

G. Gerasimov

V. Levashov

P. Kozlov

N. Bykova

I. Zabelinsky

Bibliografia

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