«Previous Article|Table of Contents|Next Article»

《火箭推进》[ISSN:1672-9374/CN:CN 61-1436/V]

Issue:

2018年02期

Page:

1-9

Research Field:

研究与设计

Publishing date:

Info

Title:

Aerodynamic modification design and analysis of waverider with controllable leading and trailing edges

Author(s):

LI Yongzhou¹; LI Guangxi¹; ZHANG Kunyuan²; MA Yuan¹

1. Xi'an Aerospace Propulsion Institute,Xi'an 710100,China; 2.College of Energy and Power Engineering,Nanjing University of Aeronautics and Astronautics,Nanjing 210016,China

Keywords:

waverider;  aerodynamic modification;  streamline tracing;  geometric reconstruction;  projection shape

PACS:

V221-34

DOI:

-

Abstract:

Based on the supersonic aerodynamic principle combined with the streamline tracing and geometric reconstruction technique, a design method of waverider with controlled the leading and trailing edge was developed in this paper. Under the conditions that the horizontal projection of leading edge is hyper elliptical and the trailing edge is circular, the aerodynamic modification waverider was designed by using this method. Numerical simulation results at design point(Ma=6.0)and relay point(Ma=4.0)indicate that the surface of aerodynamic modification waverider is of smooth transition while the leading and tailing edge are specified simultaneously, except a very small high pressure area at both sides of the exit. Therefore, it is able to maintain the wave structure and characteristics of original waverider. Compared with the original waverider, the volume ratio, life force and pre-compression efficiency of aerodynamic modification waverider are higher. In addition, the pitching moment is almost equal but the lift-drag ratio is decreased. Under the viscous condition, the lift-drag ratio decreases from 2.91 to 2.53 at design point and decreases from 2.69 to 2.32 at relay point. The above results correspond to the design expectation, and the design method is feasible.

References:

[1] DUNCAN LUNAN M A. Waverider,a revised chronology: AIAA 2015-3529 [R]. Reston: AIAA,2015.
[2] NONWEILER T R F. Aerodynamic problems of manned space vehicles [J]. Journal of the royal aeronautical society,1959,63: 521-530.
[3] JONES J U,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.
[4] SOBIECZKY H,ZORES B,WANG Z. High speed flow design using the theory of osculating cones and axisymmetric flows [J]. Chinese journal of aeronautics,1999,12(1): 1-8.
[5] TAKASHIMA N. LEWIS MJ. A cone-wedge waverider configuration for engine-airframe integration [J]. Journal of aircraft,1995,32(5): 1142–1144
[6] RASMUSSEN M L. Waverider configurations derived from inclined circular and elliptic cones [J]. Journal of spacecraft and rockets,1980,17(5): 537-545.
[7] LOBBIA M A,SUZUKI K. Experimental investigation of a Mach 3.5 waverider designed using computational fluid dynamics [J]. AIAA journal,2015,53(6): 1590-1601.
[8] LIU C Z,BAI P,CHEN B Y,et al. Rapid design and optimization of waverider from 3D flow: AIAA 2016-3288 [R]. Reston: AIAA,2016.
[9] JONES K D,SOBIECZKY H,SEEBASSA R. et al. Waverider design for generalized shock geometries [J]. Journal of spacecraft rockets,1995,32(6): 957–963.
[10] 李永洲,张堃元. 基于马赫数分布可控曲面外/内锥形基准流场的前体/进气道一体化设计[J].航空学报,2015,36(1): 289-301.
[11] RODI P.E. The osculating flowfield method of waverider geometry generation, AIAA 2005–0511 [R]. Reston: AIAA,2005.
[12] LEWIS M J,CHAUFFOUR M L.Shock-based waverider design with pressure gradient corrections and computational simulations [J]. Journal of aircraft,2005,42(5): 1350–1352.
[13] 李永洲,孙迪,张堃元. 前后缘型线同时可控的乘波体设计[J]. 航空学报,2017,38(1): 120153.
[14] MAXWELL J R.Hypersonic waverider stream surface actuation for variable design point operation: AIAA 2016-4706 [R]. Reston: AIAA,2016.
[15] DRAYNA T W,NOMPELIS I,CANDLER G V. Hypersonic inward turning inlets: design and optimization: AIAA 2006-297 [R]. Reston: AIAA,2006.
[16] ZHANG K Y. Research progress of hypersonic inlet inverse design based on curved shock compression system:AIAA 2015-3647 [R]. Reston: AIAA,2015.

Memo

Memo:

-

Common functions

Last Update: 1900-01-01