Cooling efficiency investigation of forward-facing cavity and opposing jet combinatorial thermal protection system

Lu Hai-Bo; Liu Wei-Qiang

doi:10.7498/aps.61.064703

Abstract

The cooling efficiency of a forward-facing cavity and opposing jet combinatorial thermal protection system is investigated, by which the flow field parameters, the aerodynamic force, and the surface heat flux distribution are obtained. The numerical simulation method is validated by experiment with no opposing jet model. The analysis of the numerical simulation results shows that this kind of combinatorial thermal protection system has an excellent effect on cooling the outer body surface of the nose-tip. By introducing an opposing jet with a small total pressure (total pressure ratio PR is 0.1), the cooling effect of combinatorial configuration can be much better than that of a single cavity. With the opposing jet speed increasing, the cooling efficiency is improved and the aerodynamic resistance is reduced. The combinatorial system is suited for the thermal protection of hypersonic aircraft that needs a long-distance and long-time flight.

Keywords:

Authors and contacts

1.
College of Aerospace and Material Engineering, National University of Defense Technology, Changsha 410073, China

Corresponding author: Lu Hai-Bo, lhbboo@sohu.com

Funds: Project supported by the Major Program of National Natural Science Foundation of China (Grant No.90916018) and the Research Fund for the Doctoral Program of Higher Education of China (Grant No.200899980006).

References

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Cited By

[1]	Zheng T L,Zou J C,Yu B 2005 Chinese J.Aeronaut.18 372
[2]	Ye H,Geng X 2011 Sci.China:Tech.Sci.41 102 (in Chinese) [叶宏, 耿雪 2011 中国科学:技术科学 41 102]
[3]	Hartmann J,Troll B 1922 Phys.Rev.20 719
[4]	Burbank P B,Stallings R L 1959 NASA TM X-221
[5]	Yuceil B,Dolling D S,Wilson D 1993 AIAA 1993-2742
[6]	Silton S I,Goldstein D B 2000 AIAA 2000-0204
[7]	Silton S I,Goldstein D B 2005 J.Fluid Mech.528 297
[8]	Saravanan S,Jagadeesh G,Reddy K P J 2009 J.Spacecraft Rockets 46 557
[9]	Engblom W A,Goldstein D B 1997 J.Spacecraft Rockets 34 437
[10]	Warren C H E 1960 J.Fluid Mech.8 400
[11]	Meyer B,Nelson H F,Riggins D 2001 J.Aircraft 38 680
[12]	Aso S,Hayashi K,Mizoguchi M 2002 AIAA 2002-0646
[13]	Hayashi K,Aso S 2003 AIAA 2003-4041
[14]	Hayashi K,Aso S,Tani Y 2006 J.Spacecraft Rockets 43 233
[15]	Tian T,Yan C 2008 J.Beijing Univ.Aero.Astron.34 9 (in Chinese)[田婷,阎超 \2008 北京航空航天大学学报 34 9]

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Catalog

Vol. 61, Issue 6 - 2012-03-20

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