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针对航天飞机热防护系统组件之间的缝隙气动加热问题,建立二维缝隙局部网格模型,利用CFD方法研究了二维定常可压缝隙内高超声速气动热环境规律,主要分析了来流攻角、来流马赫数、缝隙宽度、倒角和台阶等因素对流场和气动热环境的影响规律。结果表明上述因素均会对缝隙局部热环境产生影响,在防热设计中应该综合考虑。通过本文的研究工作,给出了一种工程设计中可用的缝隙热环境设计方法。
Abstract:Aiming at the problem of thermal protection system gap heating of space shuttle,a two dimentional mesh model was established and the technology of computational fluid dynamics( CFD) was adopted to simulate hypersonic gap heating problem. The effect of attack angle,Mach number,gap width,chamfer and step on heat transfer to the gap wall were discussed. The results show that the abovementioned factors affect the gap heating significantly. A method which could be used in engineering design was developed.
[1]范绪箕.高速飞行器热结构分析与应用[M].北京:国防工业出版社,北京,2009.
[2]Cleland J,Iannetti F.Thermal protection system of the space shuttle[R].NASA-CR-4227,1989.
[3]Berry S A,Horvath T J,Weilmuenster K J.X-38 experimental aeroheating at Mach 10[J].Journal of Spacecraft and Rockets,2004,41(2).
[4]Petley D H,Smith D M,Edwards C L.Surface step induced gap heating in the shuttle thermal protection system[J].Journal of Spacecraft and Rockets,1984,11(2):156-161.
[5]Pitts W C,Murbach M S.Flight measurements of tile gap heating on the space shuttle[C].AIAA/ASME 3rd Joint Thermophysics,Fluids,Plasma and Heat Transfer Conference,AIAA-1982-82-0840.
[6]Scott C D,Maraia R J.Gap heating with pressure gradients[M].American Institute of Aeronautics and Astronautics.1979,06.
[7]Hinderks M,Radespiel R,Gulhan A.Simulation of hypersonic gap flow with consideration of fluid structure interaction[C].34th AIAA Fluid Dynamics Conference and Exhibit,AIAA-2004-04-2238,Portland,OR.
[8]Hinderks M,Radespiel R.Investigation of hypersonic gap flow of a reentry nosecap with consideration of fluid structure interaction[R].44th AIAA Aerospace Sciences Meeting and Exhibit,AIAA-2006-06-0188,Reno,NV.
[9]Paolicchi L T L C,Santosy W F N.Length-to-Depth ratio effects on aerodynamic surface quantities of a rarefied hypersonic gap flow[C].44th AIAA Thermophysics Conference,AIAA-2013-13-2789,San Diego,CA.
[10]童秉纲.航天飞机防热瓦缝隙气动加热的讨论[M].气动实验与测量控制,1990.
[11]唐功跃,吴国庭,姜贵庆.缝隙流动分析及其热环境的工程计算[J].中国空间科学技术,1996,16(6):17.
[12]唐贵明.狭窄缝隙内的热流分布实验研究[J].流体力学实验与测量,2000,14(4):1-6.
[13]秦强,马建军.陶瓷防热瓦间缝隙气动加热规律研究[J].装备环境工程,2013,10(5):42-46.
[14]Fay J A,Riddell F R.Theory of stagnation point heat transfer in dissociated air[J].Aero Sci,1985,25(2).
Basic Information:
DOI:10.16358/j.issn.1009-1300.2016.02.08
China Classification Code:V475.2
Citation Information:
[1]屈强,许小静,洪文虎,等.缝隙内高超声速气动加热数值模拟[J].战术导弹技术,2016,No.176(02):41-46.DOI:10.16358/j.issn.1009-1300.2016.02.08.
Fund Information:
国家自然科学基金项目(11572353,51572298,11502306)