Acta Aeronautica et Astronautica Sinica ›› 2023, Vol. 44 ›› Issue (20): 128503-128503.doi: 10.7527/S1000-6893.2023.28503
• Fluid Mechanics and Flight Mechanics • Previous Articles Next Articles
Mengge WANG1,2, Xiaoming HE1(
), Juanjuan WANG3, Yue ZHANG1,2, Kun WANG1, Huijun TAN1, Liugang LI4
CJA
Received:2023-02-01
Revised:2023-02-21
Accepted:2023-04-13
Online:2023-10-25
Published:2023-04-21
Contact:
Xiaoming HE
E-mail:70203999@nuaa.edu.cn
Supported by:CLC Number:
Mengge WANG, Xiaoming HE, Juanjuan WANG, Yue ZHANG, Kun WANG, Huijun TAN, Liugang LI. Shock wave/boundary layer interaction control method based on oscillating vortex generator[J]. Acta Aeronautica et Astronautica Sinica, 2023, 44(20): 128503-128503.
Fig.1
Design concept diagram of oscillating vortex generator
Fig.2
Structure realization of oscillating vortex generator
Fig.3
3D model of oscillating vortex generator
Fig.4
Grid topology of oscillating vortex generator array
Fig.5
Relative positions of oscillating vortex generator array
Fig.6
Boundary layer profile and wall pressure distribution with different mesh numbers
Fig.7
Model of flow field and outfield
Table 1
Main flow parameters of shock waves upstream and downstream
| 来流参数 | 取值 |
|---|---|
| 马赫数Ma | 3.0 |
| 速度u0/(m·s-1) | 885.2 |
| 气流偏转角αf/(°) | 12.0 |
| 边界层厚度δ/mm | 8.0 |
| 总压P*/kPa | 203.0 |
| 总温T*/K | 606.0 |
Fig.8
Flow parameter distribution at inlet boundary
Fig.9
Comparison of boundary layer velocity distributions obtained by experiment and simulation[17]
Fig.10
Location of maximum upwash velocity and minimum velocity points of wake on symmetry plane[17]
Fig.11
Pressure curves at outlet at different time steps
Fig.12
Comparison of pitching moment coefficient between experimental data and simulation data
Fig.13
Time-mean boundary layer profiles at different positions along flow direction of oscillating vortex generator array
Fig.14
Evolution of flowing vortices in oscillating vortex generator arrays[19]
Fig.15
Time-averaged velocity at different spanwise locations downstream of vortex generator
Fig.16
Boundary layer profiles at typical moments at different spanwise positions at x=10hv
Fig.17
Time mean velocity distribution of oscillating vortex generator and fixed geometry vortex generator arrays near wall (z=0.25hv)
Fig.18
Comparison of velocity distribution during "suction" and "extrusion" of oscillating vortex generator
Fig.19
Time-averaged Mach number distribution of oscillating vortex generator array on different xoz planes
Fig.20
Liutex-Omega isosurfaces and wall limiting streamlines at typical moments during oscillation of oscillating vortex generator
Fig.21
Changes of time-averaged Mach number at y=0hv on plane of symmetry with different configurations
Table 2
Comparison of downstream performance parameters with different configurations
| 监控面高度 | 状态 | 总压恢复系数 | 出口马赫数 |
|---|---|---|---|
| 3.75δ | 无控状态 | 0.774 | 1.880 |
| 定几何涡流发生器 | 0.769 | 1.870 | |
| 振荡式涡流发生器 | 0.809 | 1.915 |
Fig.22
Variation of shape factor in oscillating vortex generators at different frequencies
Fig.23
Variation of mean Mach number at symmetry plane of oscillating vortex generator at different frequencies
Fig.24
Wall static pressure and wall friction coefficient distribution along symmetry line y=0hv at different shock impingement positions
Table 3
Separation length of symmetry line (y=0hv) at different shock wave impingement positions
| 激波入射位置 | 分离点 | 再附点 | 分离区长度 |
|---|---|---|---|
| Xp=34hv | x=24hv | x=48hv | 24hv |
| Xp=42hv | x=31hv | x=56hv | 25hv |
| Xp=45hv | x=35hv | x=61hv | 26hv |
| 无控状态 | x=20hv | x=54hv | 34hv |
Fig.25
Distribution of friction lines at different shock impingement positions
Fig.26
Incident shock wave surface and streamline emitted from vortex generator front 0.15 mm away from wall
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