Influence of the Rotation of a Blunt-Nose Cone on the Heat Exchange in the Supersonic Flow Over it at an Angle of Attack
Some methods of control over the thermal regimes realized in a supersonic flow past a conic body with a nose blunted over a sphere were numerically investigated with account of complicating factors. The solution of the problem on the heat and mass transfer in the boundary layer on the surface of this body in the conjugate formulation made it possible to estimate the influence of the nonisothermality of the surface of the body on the characteristics of the indicated transfer. The influence of the rotation of such a body made of composite materials on the heat exchange in the flow over it was determined.
Download to read the full article text
V. A. Bashkin and s. M. Reshet’ko, On the maximum temperature of a bluntness with account of its heat conduction, Uch. Zap. TsAGI, 20, No. 5, 53–59 (1989).
V. I. Zinchenko, A. G. Kataev, and A. S. Yakimov, Investigation of temperature regimes of aerodynamic bodies in the case of flow of a gas from their surface, Prikl. Mekh. Tekh. Fiz., No. 6, 57–64 (1992).
V. I. Zinchenko and A. S. Yakimov, Investigation of the heat-exchange characteristics in the case where a gas flows around a cone with a nose blunted over a sphere at an angle of attack and is blown from the bluntness surface, Prikl. Mekh. Tekh. Fiz., No. 4, 162–169 (1999).
A. A. Markov, Influence of the rotation of a blunt-nosed body and the external vorticity on the heat exchange at the critical point of the supersonic flow over the body, Izv. Akad. Nauk SSSR, Mekh. Zhidk. Gaza, No. 3, 179–182 (1984).
N. A. Krasilov, V. A. Levin, and S. A. Yunitskii, Investigation of the hypersonic viscous shock layer on rotating bodies in the presence of flow, Izv. Akad. Nauk SSSR, Mekh. Zhidk. Gaza, No. 1, 106−114 (1986).
V. I. Zinchenko, K. N. Efimov, and A. S. Yakimov, Investigation of the characteristics of conjugate heat and mass transfer in spatial flow past a sphere-blunted cone and blowing-in of a gas from the surface of bluntness, J. Eng. Phys. Thermophys., 80, No. 4, 751–759 (2007).
A. M. Grishin and V. M. Fomin, Conjugate and Nonstationary Problems of Reactive Media Mechanics [in Russian], Nauka, Novosibirsk (1984).
A. M. Grishin and V. I. Zinchenko, Conjugate heat exchange between a reactive solid body and a gas in the presence of nonequilibrium chemical reactions, Izv. Akad. Nauk SSSR, Mekh. Zhidk. Gaza, No. 2, 121–128 (1974).
V. I. Zinchenko, Mathematical Simulation of Conjugate Problems on Heat and Mass Exchange [in Russian], Izd. Tomsk. Univ., Tomsk (1985).
Yu. D. Shevelev, Three-Dimensional Problems of the Laminar Boundary Layer Theory [in Russian], Nauka, Moscow (1977).
A. M. Grishin, A. N. Golovanov, and A. S. Yakimov, Conjugate heat exchange in a composite material, Prikl. Mekh. Tekh. Fiz., No. 4, 141–149 (1991).
A. M. Grishin, A. D. Parashin, and A. S. Yakimov, Thermochemical destruction of a carbon-filled plastic under multiple pulsed loading, Fiz. Goreniya Vzryva, 29, No. 1, 87–95 (1993).
Yu. V. Polezhaev and F. P. Yurevich, Thermal Shielding [in Russian], Énergiya, Moscow (1976).
V. V. Lunev, K. M. Magomedov, and V. G. Pavlov, Hypersonic Flow over Blunt-Nosed Cones with Equilibrium Physicochemical Transformations [in Russian], Vych. Tsentr Akad. Nauk SSSR, Moscow (1968).
V. I. Zinchenko and A. S. Yakimov, Regimes of thermochemical destruction of a carbon phenolic material under the action of a heat flow, Fiz. Goreniya Vzryva, 24, No. 2, 141–148 (1988).
S. V. Patankar and D. B. Spalding, Heat and Mass Transfer in Boundary Layers [Russian translation], Énergiya, Moscow (1970).
T. Сеbeсi, Behavior of turbulent flow near a porous wall with pressure gradient, AIAA J., 8, No. 12, 2152–2156 (1970).
L. V. Kovalev, Heterogeneous Catalytic Processes in Aerothermodynamics [in Russian], Izd. Fiz.-Mat. Lit., Moscow (2002).
A. M. Grishin, V. I. Zinchenko, K. N. Efimov, A. N. Subbotin, and A. S. Yakimov, Iteration-Interpolation Method and Its Applications [in Russian], Izd. Tomsk. Univ., Tomsk (2004).
R. N. Feldhuhn, Heat transfer from a turbulent boundary layer on a porous hemisphere, AIAA Paper, No. 119 (1976).
G. Widhopf and R. Hall, Heat-transfer measurements on a blunted cone at angle of attack under transition and turbulent conditions, Raketn. Tekh. Kosmonavt., 10, No. 10, 71–79 (1972).
A. A. Samarskii, Introduction into the Theory of Difference Schemes [in Russian], Nauka, Moscow (1971).
A. G. Gofman and A. M. Grishin, Theoretical investigation of the thermochemical destruction of graphite in a highenthalpy air, Prikl. Mekh. Tekh. Fiz., No. 4, 107–114 (1984).
R. L. Becker, Influence of nonequilibrium chemical processes on the graphite sublimation, Raketn. Tekh. Kosmonavt., 15, No. 10, 21–29 (1977).
R. A. Andrievskii, Porous Cermet Materials [in Russian], Metallurgiya, Moscow (1964).
L. M. Buchnev, A. I. Smyslov, I. A. Dmitriev, A. F. Kuteinikov, and V. I. Kostikov, Experimental investigation of the enthalpy of a quasi-monocrystal of graphite and glassy carbon in the temperature range 300–3800 K, Teplofiz. Vys. Temp., 25, No. 6, 1120–1125 (1987).
O. M. Alifanov, A. P. Tryanin, and A. L. Lozhkin, Experimental investigation of the method of determining the internal heat-transfer coefficient in a porous body from the solution of the inverse problem, J. Eng. Phys. Thermophys., 52, No. 6, 340–346 (1987).
V. P. Sosedov, Properties of Construction Carbon-Based Materials [in Russian], Metallurgiya, Moscow (1975).
Some methods of control over the thermal regimes realized in a supersonic flow past a conic body with a nose blunted over a sphere were numerically investi