Problems of heat and mass transfer in chemically reacting boundary layers on blunted bodies

This article considers a nonlinear system of partial differential equations describing the boundary layer. Such a system is commonly solved by numerical methods. Here, the Dorodnitsyn–Lees variables were used to carry out an analysis and derive the formulas for calculating the body temperatures and the heat fluxes to the body generated by the reacting compressible gradient boundary layer.

1. Galitseiskii B.M., Sovershennyi V.D., Formalev V.F., Chernyi M.S. Teplovaya zashchita lopatok turbin [Heat Shielding of Turbine Blades]. Moscow, MAI, 1996. 353 p. (In Russian)

2. Formalev V.F., Kolesnik S.A. Matematicheskoe modelirovanie sopryazhennogo teploobmena mezhdu vyazkimi gazodinamicheskimi techeniyami i anizotropnymi telami [Mathematical Modeling of Coupled Heat Transfer between Viscous Gas-Dynamic Flows and Anisotropic Bodies]. Moscow, LENAND, 2019. 320 p. (In Russian)

3. Avduevskii V.S., Galitseiskii B.M., Glebov G.A., Danilov Yu.I., Dreitser G.A., Kalinin E.K., Koshkin V.K., Mikhailova T.V., Molchanov A.M., Ryzhov Yu.A., Solntsev V.P. Osnovy teploperedachi v aviatsionnoi i raketno-kosmicheskoi tekhnike [Principles of Heat Transfer in Aviation and Rocket-and-Space Engineering]. Moscow, Mashinostroenie, 1992. 624 p. (In Russian)

4. Dorrance W.H. Giperzvukovye techeniya vyazkogo gaza [Viscous Hypersonic Flow]. Moscow, Mir, 1966. 440 p. (In Russian)

5. Bodryshev V.V., Rabinskiy L.N., Orekhov A.A. Analysis of interaction structure of circular laminar jets using digital image processing. J. Visualization, 2022, vol. 25, no. 33, pp. 1137–1150. https://doi.org/10.1007/s12650-022-00851-w.

6. Orekhov A., Rabinskiy L., Fedotenkov G. Analytical model of heating an isotropic half-space by a moving laser source with a Gaussian distribution. Symmetry, 2022, vol. 14, no. 4, art. 650. https://doi.org/10.3390/sym14040650.

7. Fedotenkov G., Rabinskiy L., Lurie S. Conductive heat transfer in materials under intense heat flows. Symmetry, 2022, vol. 14, no. 9, art. 1950. https://doi.org/10.3390/sym14091950.

8. Dobryanskiy V.N., Fedotenkov G.V., Orekhov A.A., Rabinskiy L.N. Estimation of finite heat distribution rate in the process of intensive heating of solids. Lobachevskii J. Math., 2022, vol. 43, no. 7, pp. 1832–1841. https://doi.org/10.1134/S1995080222100079.

9. Orekhov A.A., Rabinskiy L.N., Fedotenkov G.V., Hein T.Z. Heating of a half-space by a moving thermal laser pulse source. Lobachevskii J. Math., 2021, vol. 42, no. 8, pp. 1912–1919. https://doi.org/10.1134/S1995080221080229.

10. Formalev V.F., Kolesnik S.A., Kuznetsova E.L. Heat and mass transfer on the side surfaces of blunt nose parts of hypersonic aircraft. High Temp., 2022, vol. 60, suppl. 2, pp. S288–S291. https://doi.org/10.1134/S0018151X21050060.

11. Astapov A.N., Zhavoronok S.I., Kurbatov A.S., Rabinskiy L.N., Tushavina O.V. Main problems in the creation of thermal-protection systems based on structurally heterogeneous materials and the methods of their solution. High Temp., 2021, vol. 59, nos. 2–6, pp. 346–372. https://doi.org/10.1134/S0018151X21020012.

12. Formalev V.F., Garibyan B.A., Orekhov A.A. Mathematical modeling of heat transfer in anisotropic half-space based on the generalized parabolic wave heat transfer equation. Lobachevskii J. Math., 2022, vol. 43, no. 7, pp. 1842–1849. https://doi.org/10.1134/S1995080222100110.

13. Arzhanikov N.S., Sadekova G.S. Aerodinamika bol’shikh skorostei [High Speed Aerodynamics]. Moscow, Vyssh. Shk., 1965. 559 p. (In Russian)

14. Polezhaev Yu.V., Yurevich F.B. Teplovaya zashchita [Heat Shield]. Moscow, Energiya, 1976. 392 p. (In Russian)

15. Schlichting H. Teoriya pogranichnogo sloya [Boundary-Layer Theory]. Moscow, Nauka, 1969. 391 p. (In Russian)