Transforming the shock pattern of supersonic jets using fluidic injection

被引:0
|
作者
Semlitsch, Bernhard [1 ,5 ]
Cuppoletti, Daniel R. [2 ,6 ]
Gutmark, Ephraim J. [3 ,7 ]
Mihăescu, Mihai [4 ,8 ]
机构
[1] University of Cambridge, Cambridge,CB3 0DY, United Kingdom
[2] U.S. Air Force Research Laboratory, Wright-Patterson Air Force Base, OH,45433, United States
[3] University of Cincinnati, Cincinnati,OH,45221-0070, United States
[4] Royal Institute of Technology, Stockholm,10044, Sweden
[5] Whittle Laboratory, Department of Engineering, 1 JJ Thomson Avenue, United Kingdom
[6] National Research Council, AIAA
[7] Department of Aerospace Engineering, 799 Rhodes Hall
[8] Linné FLOW Centre, Department of Mechanics, Osquars Backe 18, Sweden
来源
AIAA Journal | 2019年 / 57卷 / 05期
关键词
Convergent-divergent nozzle - Fluidic injections - Operating condition - Operating configurations - Pressure oscillation - Shock associated noise - Shock structure - Supersonic jets;
D O I
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学科分类号
摘要
Double shock diamonds establish in the exhaust of modular convergent-divergent nozzles. These consist of two shock structures: one originating from the nozzle throat, and another from its exit. Analyzing the shock pattern developing for different fluidic injection operating conditions, it is shown that fluidic injection allows the rearrangement of the shock structures relative to each other. Overlapping the two structures causes large pressure oscillations in the exhaust and high amplitudes of shock associated noise, whereas staggering the shock structures mitigates these effects. The screech tone frequency does not change for all injection operating configurations, although the shock diamonds are shifted drastically with respect to each other. Hence, the screech phenomenon is dominated by the primary shock spacing originating from the nozzle throat. © 2020 Oxford University Press. All rights reserved.
引用
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页码:1851 / 1861
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