大推力系数超声速反向射流流动结构研究

Chen Xi Zhang; Yi Li; Shuo Tang; Jin Ze Zhang

doi:10.13675/j.cnki.tjjs.210661

大推力系数超声速反向射流流动结构研究

Translated title of the contribution: Flow Structure Analysis on High Thrust Coefficient Supersonic Opposing Jet

Chen Xi Zhang, Yi Li, Shuo Tang, Jin Ze Zhang

School of Astronautics

Research output: Contribution to journal › Article › peer-review

Abstract

Numerical simulation was carried out using detached eddy simulation（DES）method in order to research the flow structure of the supersonic opposing jet with high thrust coefficient（C_t=4）. A single nozzle configuration based on NASA Langley cold flow experiment was selected and post-process methods such as time averaging flow analysis and flow structure visualization were applied. The results show that under the condition of high thrust coefficient，the opposing jet presents a stable short penetration mode（SPM），which presents a large-angle cone shape. The expanded jet terminates through a Mach disk（or the jet terminal shock）and reverses its orientation as a conical free mixing layer. Early K-H vortex flow characteristics appeared in the conical mixing layer but cannot observe the typical K-H vortices. Flow structure visualization techniques show vortices break up occurs at the edge of the Mach disk，which is a main source of aerodynamic disturbance in the subsonic reverse flow zone.

Translated title of the contribution	Flow Structure Analysis on High Thrust Coefficient Supersonic Opposing Jet
Original language	Chinese (Traditional)
Article number	210661
Journal	Tuijin Jishu/Journal of Propulsion Technology
Volume	43
Issue number	12
DOIs	https://doi.org/10.13675/j.cnki.tjjs.210661
State	Published - Dec 2022

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@article{bdf1c19e515a4361b2e01a7143306c11,

title = "大推力系数超声速反向射流流动结构研究",

abstract = "Numerical simulation was carried out using detached eddy simulation（DES）method in order to research the flow structure of the supersonic opposing jet with high thrust coefficient（Ct=4）. A single nozzle configuration based on NASA Langley cold flow experiment was selected and post-process methods such as time averaging flow analysis and flow structure visualization were applied. The results show that under the condition of high thrust coefficient，the opposing jet presents a stable short penetration mode（SPM），which presents a large-angle cone shape. The expanded jet terminates through a Mach disk（or the jet terminal shock）and reverses its orientation as a conical free mixing layer. Early K-H vortex flow characteristics appeared in the conical mixing layer but cannot observe the typical K-H vortices. Flow structure visualization techniques show vortices break up occurs at the edge of the Mach disk，which is a main source of aerodynamic disturbance in the subsonic reverse flow zone.",

keywords = "Detached eddy simulation, Flow structure, Opposing jet, Shot penetration mode, Supersonic flow",

author = "Zhang, {Chen Xi} and Yi Li and Shuo Tang and Zhang, {Jin Ze}",

year = "2022",

month = dec,

doi = "10.13675/j.cnki.tjjs.210661",

language = "繁体中文",

volume = "43",

journal = "Tuijin Jishu/Journal of Propulsion Technology",

issn = "1001-4055",

publisher = "Journal of Propulsion Technology",

number = "12",

}

TY - JOUR

T1 - 大推力系数超声速反向射流流动结构研究

AU - Zhang, Chen Xi

AU - Li, Yi

AU - Tang, Shuo

AU - Zhang, Jin Ze

PY - 2022/12

Y1 - 2022/12

N2 - Numerical simulation was carried out using detached eddy simulation（DES）method in order to research the flow structure of the supersonic opposing jet with high thrust coefficient（Ct=4）. A single nozzle configuration based on NASA Langley cold flow experiment was selected and post-process methods such as time averaging flow analysis and flow structure visualization were applied. The results show that under the condition of high thrust coefficient，the opposing jet presents a stable short penetration mode（SPM），which presents a large-angle cone shape. The expanded jet terminates through a Mach disk（or the jet terminal shock）and reverses its orientation as a conical free mixing layer. Early K-H vortex flow characteristics appeared in the conical mixing layer but cannot observe the typical K-H vortices. Flow structure visualization techniques show vortices break up occurs at the edge of the Mach disk，which is a main source of aerodynamic disturbance in the subsonic reverse flow zone.

AB - Numerical simulation was carried out using detached eddy simulation（DES）method in order to research the flow structure of the supersonic opposing jet with high thrust coefficient（Ct=4）. A single nozzle configuration based on NASA Langley cold flow experiment was selected and post-process methods such as time averaging flow analysis and flow structure visualization were applied. The results show that under the condition of high thrust coefficient，the opposing jet presents a stable short penetration mode（SPM），which presents a large-angle cone shape. The expanded jet terminates through a Mach disk（or the jet terminal shock）and reverses its orientation as a conical free mixing layer. Early K-H vortex flow characteristics appeared in the conical mixing layer but cannot observe the typical K-H vortices. Flow structure visualization techniques show vortices break up occurs at the edge of the Mach disk，which is a main source of aerodynamic disturbance in the subsonic reverse flow zone.

KW - Detached eddy simulation

KW - Flow structure

KW - Opposing jet

KW - Shot penetration mode

KW - Supersonic flow

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U2 - 10.13675/j.cnki.tjjs.210661

DO - 10.13675/j.cnki.tjjs.210661

M3 - 文章

AN - SCOPUS:85146256821

SN - 1001-4055

VL - 43

JO - Tuijin Jishu/Journal of Propulsion Technology

JF - Tuijin Jishu/Journal of Propulsion Technology

IS - 12

M1 - 210661

ER -

大推力系数超声速反向射流流动结构研究

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