PDF下载 分享
[1]冯锦虎,高峰,何至林.超燃冲压发动机隔离段内附面层/激波串相互干扰研究[J].火箭推进,2010,36(02):5-9.
 Feng Jinhu,Gao Feng,He Zhilin.Investigation of boundary layer/shock wave train interference in a scramjet isolator[J].Journal of Rocket Propulsion,2010,36(02):5-9.
点击复制

超燃冲压发动机隔离段内附面层/激波串相互干扰研究

《火箭推进》[ISSN:1672-9374/CN:CN 61-1436/V] 卷: 36 期数: 2010年02期 页码: 5-9 栏目: 研究与设计 出版日期: 2010-04-15
Title:
Investigation of boundary layer/shock wave train interference in a scramjet isolator
文章编号:
(2010)02-0005-05
作者:
冯锦虎1高峰2何至林2
1 93605部队;2空军工程大学导弹学院,陕西 三原 713800
Author(s):
Feng Jinhu1 Gao Feng2 He Zhilin2
1. Army 93605; 2. The Missile Institute of Air Force Engineering University, Shaanxi 713800, China
关键词:
超燃冲压发动机隔离段激波串附面层流场数值模拟
分类号:
V235
文献标志码:
A
摘要:
隔离段内激波串的产生和发展以及激波/附面层相互干扰现象是极为复杂的,有效地进行激波串的组织是研究隔离段的关键所在,而其性能的好坏直接影响着超燃冲压发动机的性能。采用数值模拟的方法对不同来流附面层厚度工况的二维轴对称隔离段内流场流动特性进行了数值计算,分析了附面层/激波相互作用机理和附面层对隔离段激波串及隔离段性能的影响。结构表明:压缩-膨胀-再压缩-再膨胀……的气流流动挤压过程导致激波串的形成,逆压梯度的存在构成了附面层分离;附面层厚度的增加影响着激波串起始位置和结构;随着附面层厚度的增加,出口总压恢复系数和质量平均马赫数降低,且随着反压增大,变化趋势趋于明显。
Abstract:
The occurance and the development of the isolator shock wave train and the interference phenomenon of shock wave/boundary layer are very complicated. The numerical method was used to simulate the characteristics of the two-dimensional-axis-symmetry isolator internal flow fields under different incoming airflow boundary layer thickness, the interference mechanism of shock wave/boundary layer and the influence of the boundary layer on the isolator shock wave train and the performance of the isolator. The computational results show that the periodical expansion and the compression results in the formation of the shock wave train and the existence of the negative pressure gradients have influence upon the boundary layer separation. The location and the structure of the shock wave train are effected by the incoming airflow boundary layer thickness. With the increase of the boundary layer thickness, the total pressure recovery coefficient and average Mach number at outlet decrease. This variation is more significant with the backpressure increasing.

参考文献/References:

[1]Neumann E P, Lustwerk F. Supersonic Diffusers for Wind Tunnels[J]. Appl Mech, Vol.16, No.2, 1949:195-202. [2]Newman E P, Lustwerk F. High-Efficiency Supersonic Diffusers[J]. Aeronaut Sci, Vol.18, No.6, 1951:369-374. [3]Lukasiewicz J. Diffusers for Supersonic Wind Tunnels [J]. Aeronaut Sci, Vol.20, No.9, 1953:617-626. [4]Shapiro A H. The Dynamics and Thermodynamics of Compressible Fluid flow[J]. vols.1 and 2. New York, Ronald Press, 1953: 135-139, 1153-1156. [5]Faro IDV, editor. Handbook of supersonic aerodynamics [M]. Vol.6. Sec.17, Navweps Rep,1964. [6]Waltrup P J, Billig F S. Structure of Shock Waves in Cylindrical Ducts[J]. AIAA, Vol.11, No.10, 1973:1404-1408. [7]Om D, Viegas J R, Childs M E. Multiple Transonic Shock-Wave/turbulent Boundary-layer Interaction in a Circular Duct [J]. AIAA, Vol.23, No.10, 1985: 1506-1511.

相似文献/References:

[1]朱舒扬.全尺寸超燃冲压发动机推力测量台架研制[J].火箭推进,2015,41(05):106.
 ZHU Shuyang.Development of thrust measurement platform for full-scale scramjet[J].Journal of Rocket Propulsion,2015,41(02):106.
[2]姚照辉,李光熙,张蒙正,等.燃油分配对超燃冲压发动机的性能影响仿真分析[J].火箭推进,2013,39(04):30.
 YAO Zhao-hui,LI Guang-xi,ZHANG Meng-zheng,et al.Simulation and analysis for influence of fuel distribution on scramjet performance[J].Journal of Rocket Propulsion,2013,39(02):30.
[3]刘 昊,李光熙,杜 泉,等.超燃冲压发动机全流道反应流场仿真分析[J].火箭推进,2013,39(06):1.
 LIU Hao,LI Guang-xi,DU Quan,et al.Numerical simulation of reaction flow field in full flowpath of scramjet[J].Journal of Rocket Propulsion,2013,39(02):1.
[4]张 倩,王 兵,张耘隆,等.RBCC的可实现性方案—DRBCC分析[J].火箭推进,2014,40(05):1.
 ZHANG Qian,WANG Bing,ZHANG Yun-long,et al.An analysis of RBCC realizability scheme: DRBCC[J].Journal of Rocket Propulsion,2014,40(02):1.
[5]赵宏亮,张蒙正.超燃冲压发动机推阻力特性研究综述[J].火箭推进,2014,40(06):41.
 ZHAO Hong-liang,ZHANG Meng-zheng.Investigation of thrust/drag property of scramjet[J].Journal of Rocket Propulsion,2014,40(02):41.
[6]张蒙正,邹 宇.美国典型高超飞行器项目研发及启示[J].火箭推进,2012,38(02):1.
 ZHANG Meng-zheng,ZOU Yu.Development of American typical hypersonic flight vehicles and its enlightenment[J].Journal of Rocket Propulsion,2012,38(02):1.
[7]李龙飞,王延涛,杨伟东,等.超声速燃烧地面试验的蓄热式加热器及其关键技术[J].火箭推进,2012,38(02):16.
 LI Long-fei,WANG Yan-tao,YANG Wei-dong,et al.Thermal energy storage heater and its key technologies for supersonic combustion ground test facilities[J].Journal of Rocket Propulsion,2012,38(02):16.
[8]文 科,李旭昌,马岑睿,等.不同入口马赫数对超燃冲压发动机尾喷管的性能影响研究[J].火箭推进,2011,37(03):18.
 WEN Ke,LI Xu-chang,MA Cen-rui,et al.Influence of nozzle inlet Mach number on performance of scramjet nozzle[J].Journal of Rocket Propulsion,2011,37(02):18.
[9]王玉峰,吴宝元,王东东.变比热对超燃冲压发动机尾喷管设计的影响分析[J].火箭推进,2010,36(02):43.
 Wang Yufeng,Wu BaoYuan,Wang Dongdong.Scramjet engine nozzle design with variable specific heat[J].Journal of Rocket Propulsion,2010,36(02):43.
[10]杨事民,唐豪,黄胡.凹腔超声速燃烧室氢气燃烧流场数值模拟[J].火箭推进,2008,34(01):12.
 Yang Shimin,Tang Hao,Huang Yue.Numerical simulation of hydrogen combustion on flow field in supersonic combustor with cavity[J].Journal of Rocket Propulsion,2008,34(02):12.

备注/Memo

收稿日期:2009-09-01;修回日期:2010-03-10。基金项目:空军工程大学导弹学院“研究生学位论文创新基金”(DY09204)。
基金项目:空军工程大学导弹学院“研究生学位论文创新基金”(DY09204)。
作者简介: 冯锦虎(1984—),男,硕士,研究领域为航空宇航推进理论与工程。

更新日期/Last Update: 1900-01-01