压缩拐角激波与旁路转捩边界层干扰数值研究
Numerical study of shock wave and bypass transitional boundary layer interaction in a supersonic compression ramp
查看参考文献32篇
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文摘
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为了研究激波与旁路转捩边界层的干扰机理,采用直接数值模拟(DNS)方法对来流马赫数Ma_∞=2.9,24°压缩拐角内激波与转捩边界层的相互作用进行了系统的研究。考察了旁路转捩干扰下压缩拐角内分离区形态和激波波系结构的典型特征。比较了转捩干扰与湍流干扰流动结构的差异,并分析了造成差异的原因。研究了拐角内转捩边界层的演化特性,探讨了转捩干扰下脉动峰值压力和峰值摩阻的分布规律及形成机制。研究结果表明:相较于湍流干扰,两侧发卡涡串的展向挤压使得分离区起始点以V字型分布,且分离激波沿展向以破碎状态为主,激波脚呈现多层结构;拐角内的干扰作用急剧加速了边界层的转捩过程;转捩干扰下的拐角内峰值脉动压力以单峰结构出现在分离区的下游,同时干扰区内的强湍动能和高雷诺剪切应力使得其局部峰值摩阻系数要高于湍流干扰。 |
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其他语种文摘
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A direct numerical simulation (DNS) of shock wave and bypass transitional boundary layer interaction for a 24° compression ramp at Mach number Ma_∞=2.9 is conducted. The intricate flow phenomena in the ramp-corner, including separation bubble characteristics and shock wave behavior, have been studied systematically. The DNS results of transitional interaction are compared with the corresponding turbulent interaction and the reasons for the differences are analyzed. The evolution of the transitional boundary layer in the ramp is researched. The fluctuation of wall pressure and distribution of skin friction coefficient in transitional interaction are investigated in detail. Results indicate that the distribution of coherent vortex structures is non-uniform in the spanwise direction and the separation bubble is reduced to a V-shape by the mutual interactions of the hairpin vortices chains. The shock fronts are destroyed badly and even break down by the interaction. The multiple layer of shock foots is observed obviously. The interactions rapidly accelerate the evolution of transition and greatly amplify the intensity of fluctuations. The peak of wall pressure fluctuations appears with single-peak structure at the downstream of separation region. And the overshoot of skin friction induced by transitional interaction is explained by the strong Reynolds shear stress and high turbulent kinetic energy. |
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来源
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航空学报
,2016,37(12):3588-3604 【核心库】
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DOI
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10.7527/s1000-6893.2016.0096
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关键词
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压缩拐角
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激波/边界层干扰
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旁路转捩
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脉动压力
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摩阻
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直接数值模拟
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地址
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中国空气动力研究与发展中心计算空气动力研究所, 绵阳, 621000
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中国科学院力学研究所, 高温气体动力学国家重点实验室, 北京, 100190
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语种
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中文 |
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文献类型
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研究性论文 |
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ISSN
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1000-6893 |
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学科
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力学;航空 |
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基金
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国家自然科学基金
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文献收藏号
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CSCD:5884584
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参考文献 共
32
共2页
|
|
1.
Holden M S.
Reviews of aerothermal problems associated with hypersonic flight: AIAA-1986-0267,1986
|
被引
1
次
|
|
|
|
|
2.
Andreopoulos J. Some new aspects of the shock wave/boundary layer interaction in compression ramp flows.
Journal of Fluid Mechanics,1987,180:405-428
|
被引
7
次
|
|
|
|
|
3.
Edwards J R. Numerical simulations of shock/boundary layer interactions using time dependent modeling techniques: A survey of recent results.
Progress in Aerospace Sciences,2008,44(6):447-465
|
被引
6
次
|
|
|
|
|
4.
Knight D. Assessment of CFD capability for prediction of hypersonic shock interactions.
Progress in Aerospace Sciences,2012,48/49(2):8-26
|
被引
14
次
|
|
|
|
|
5.
Delery J M. Shock wave/turbulent boundary layer interaction and its control.
Progress in Aerospace Sciences,1985,22(4):209-280
|
被引
15
次
|
|
|
|
|
6.
Clemens N T. Low frequency unsteadiness of shock wave turbulent boundary layer interactions.
Annual Review of Fluid Mechanics,2014,46(1):469-492
|
被引
47
次
|
|
|
|
|
7.
Gaitonde D V. Progress in shock wave boundary layer interactions.
Progress in Aerospace Sciences,2015,72:80-99
|
被引
43
次
|
|
|
|
|
8.
Dolling D S. Fifty years of shock-wave/boundary-layer interaction research: what next?.
AIAA Journal,2001,39(8):1517-1530
|
被引
66
次
|
|
|
|
|
9.
Sandham N D. Transitional shock wave/boundary layer interactions in hypersonic flow.
Journal of Fluid Mechanics,2014,752:349-382
|
被引
4
次
|
|
|
|
|
10.
Erdem E. Experiments on transitional shock wave boundary layer interactions at Mach 5.
Experiments in Fluids,2013,54(10):1598-1620
|
被引
1
次
|
|
|
|
|
11.
Schrijer F J.
Experiments on hypersonic boundary layer separation and reattachment on a blunted cone flare using quantitative infrared thermograph: AIAA-2003-6967,2003
|
被引
1
次
|
|
|
|
|
12.
Xie S F.
Research of flow field characteristics of hypersonic shock wave/transitional boundary layer interaction: AIAA-2015-3569,2015
|
被引
1
次
|
|
|
|
|
13.
Teramoto S. Large eddy simulation of transitional boundary layer with impinging shock wave.
AIAA Journal,2005,43(11):2354-2363
|
被引
4
次
|
|
|
|
|
14.
Krishnan L. Shock wave/boundary layer interactions in a model Scramjet intake.
AIAA Journal,2009,47(7):1680-1691
|
被引
8
次
|
|
|
|
|
15.
Tokura Y.
DNS of a spatially evolving transitional turbulent boundary layer with impinging shock wave: AIAA-2011-0729,2011
|
被引
1
次
|
|
|
|
|
16.
Ludeke H.
Direct numerical simulation of the transition process in a separated supersonic ramp flow: AIAA-2010-4470,2010
|
被引
1
次
|
|
|
|
|
17.
童福林. 转捩对压缩拐角激波/边界层干扰分离泡的影响.
航空学报,2016,37(10):2909-2921
|
被引
4
次
|
|
|
|
|
18.
Ringuette M J. Experimental study of a Mach 3 compression ramp interaction at Re_θ=2 400.
AIAA Journal,2009,47(2):373-385
|
被引
7
次
|
|
|
|
|
19.
Bookey P.
New experimental data of STBLI at DNS/LES accessible Reynolds numbers: AIAA-2005-0309,2005
|
被引
2
次
|
|
|
|
|
20.
Wu M. Direct numerical simulation of supersonic turbulent boundary layer over a compression ramp.
AIAA Journal,2007,45(4):879-889
|
被引
32
次
|
|
|
|
|
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