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Generation and design methods of osculating cone waverider with constant angle of sweepback
Received date: 2015-12-14
Revised date: 2015-12-30
Online published: 2016-02-26
In this paper, the generation and design methods of osculating cone waverider with constant angle of sweepback (OCWRCAS) are studied, and viscous is considered during design. Stable vortex can be generated by the leading edge with constant angle of sweepback, which will improve the aerodynamic ability of the waverider. Firstly, the generation method of OCWRCAS is presented based on the generation method of traditional osculating cone waverider. The design variables of sweepback angle, shock angle and the curve shape of head are extracted by analyzing the geometry character of the OCWRCAS, and the variation trend of lift to drag ratio and volumetric efficiency with these variables is also studied. The multi-objective optimal solutions are founded from two classical types of OCWRCAS by searching the total design space. Finally, the method of computational fluid dynamics is used to verify the character of wave riding and vortex lift. The results show that OCWRCAS with good ability of wave riding and high lift to drag ratio keeps relational volumetric efficiency; vortex lift can be generated by the leading edge with constant angle of sweepback at certain angle of attack.
Key words: waverider; osculating cone; viscous; angle of sweepback; vortex lift
DUAN Yanhui , FAN Zhaolin , WU Wenhua . Generation and design methods of osculating cone waverider with constant angle of sweepback[J]. ACTA AERONAUTICAET ASTRONAUTICA SINICA, 2016 , 37(10) : 3023 -3034 . DOI: 10.7527/S1000-6893.2016.0024
[1] NONWEILER T R F. Aerodynamic problems of manned space vehicles[J]. Journal of the Royal Aeronautical Society, 1959, 63(585):521-528.
[2] JONES J G, MOORE K C, PIKE J, et al. A method for designing lifting configurations for high supersonic speeds using axisymmetric flow field[J]. Archive of Applied Mechanics, 1968, 37(1):56-72.
[3] 耿永兵, 刘宏, 姚文秀, 等. 锥形流乘波体优化设计研究[J]. 航空学报, 2006, 27(1):23-28. GENG Y B, LIU H, YAO W X, et al. Viscous optimized design of waverider derived from cone flow[J]. Acta Aeronautica et Astronautica Sinica, 2006, 27(1):23-28(in Chinese).
[4] 耿永兵, 刘宏, 雷麦芳, 等. 高升阻比乘波构型优化设计[J]. 力学学报, 2006, 38(4):540-546. GENG Y B, LIU H, LEI M F, et al. Optimized design of waverider with high lift over drag ratio[J]. Chinese Journal of Theoretical and Applied Mechanics, 2006, 38(4):540-546(in Chinese).
[5] RASMUSSEN M L. Waverider configurations derived from inclined circular and elliptic cones[J]. Journal of Spacecraft and Rockets, 1980, 17(6):537-545.
[6] 乐贵高, 马大为, 李自勇. 椭圆锥乘波体高超声速流场数值计算[J]. 南京理工大学学报(自然科学版), 2006, 30(3):257-260. LE G H, MA D W, LI Z Y. Computation of hypersonic flowfields for elliptic-cone-derived waverider[J]. Journal of Nanjing University of Science and Technology (Natural Science), 2006, 30(3):257-260(in Chinese).
[7] TAKASHIMA N, LEWIS M J. Waverider configurations based on non-axisymmetric flow fields for engine-airframe integration:AIAA-1994-0380[R]. Reston:AIAA, 1994.
[8] SOBIECZKY H, DOUGHERTY F C, JONES K. Hypersonic waverider design from given shock wave[C]//First International Waverider Symposium. Maryland:University of Maryland, 1990.
[9] CENTER K, SOBIECZKY H, DOUGHERTY F C. Interactive design and analysis of hypersonic waverider geometries:AIAA-1991-1697[R]. Reston:AIAA, 1991.
[10] KONTOGIANNIS K, SOBESTER A, TAYLOR N J. On the conceptual design of waverider forebody feometries:AIAA-2015-1009[R]. Reston:AIAA, 2015.
[11] SZEMA K, LIU Z, MUNIPALLI R. An efficient GUI design tool for high-speed airbreathing propulsion integration:AIAA-2010-4362[R]. Reston:AIAA, 2010.
[12] 贺旭照, 倪鸿礼. 密切曲面锥乘波体-设计方法与性能分析[J]. 力学学报, 2011, 43(6):1077-1082. HE X Z, NI H L. Osculating curved cone(OCC) waverider:Design methods and performance analysis[J]. Chinese Journal of Theoretical and Applied Mechanics, 2011, 43(6):1077-1082(in Chinese).
[13] 贺旭照, 周正, 毛鹏飞, 等. 密切曲面内锥乘波前体进气道设计和试验研究[J]. 实验流体力学, 2014, 28(3):39-44. HE X Z, ZHOU Z, MAO P F, et al. Design and experimental study of osculating inward turning cone waverider/inlet(OICWI)[J]. Journal of Experiments in Fluid Mechanics, 2014, 28(3):39-44(in Chinese).
[14] BOWCUTT K G. Optimization of hypersonic waveriders derived from cone flows-including viscous effects[D]. Maryland:University of Maryland, 1986.
[15] RODI P E. The osculating flowfield method of waverider geometry generation:AIAA-2005-0511[R]. Reston:AIAA, 2005.
[16] RODI P E. Geometrical relationships for osculating cones and osculating flowfield waverider:AIAA-2011-1188[R]. Reston:AIAA, 2011.
[17] RODI P E. Vortex lift waverider configurations:AIAA-2012-1238[R]. Reston:AIAA, 2012.
[18] ANDERSON J D. Modern compressible flow[M]. 2nd ed. New York:McGraw-Hill Publishing Company, 1999:294-307.
[19] CORDA S, ANDERSON J. Viscous optimized hypersonic waveriders designed from axisymmetric flow fields:AIAA-1988-0369[R]. Reston:AIAA, 1988.
[20] DIETER J, GOTTFRIED S, SIEGFRIED W. Basic research and technologies for two-stage-to-orbit vehicles[M]. Weinheim:WILEY-VCH Verlag Gmbh & Co. KGaA, 2005:215-260.
[21] CENTER K, SOBIECZKY H, DOUGHERTY F. Interactive design of hypersonic waverider geometries:AIAA-1991-1697[R].Reston:AIAA, 1991.
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