ACTA AERONAUTICAET ASTRONAUTICA SINICA ›› 2023, Vol. 44 ›› Issue (6): 127085-127085.doi: 10.7527/S1000-6893.2022.27085
• Fluid Mechanics and Flight Mechanics • Previous Articles
Weijia LIU, Yingkun LI(
), Xiong CHEN, Chunlei LI
CJA
Received:2022-03-01
Revised:2022-03-21
Accepted:2022-04-06
Online:2022-07-12
Published:2022-04-12
Contact:
Yingkun LI
E-mail:liyingkun@njust.edu.cn
Supported by:CLC Number:
Weijia LIU, Yingkun LI, Xiong CHEN, Chunlei LI. Panel flutter characteristics on shock wave/boundary layer interaction based on fluid⁃structure coupling[J]. ACTA AERONAUTICAET ASTRONAUTICA SINICA, 2023, 44(6): 127085-127085.
Fig. 1
Generic cycle of loosely coupled algorithm
Fig. 2
Time-averaged skin friction coefficient over flexible panel
Fig. 3
Fluid-structural coupling calculation model of flexible panel in shock/boundary layer interaction
Fig. 4
Effect of grid resolution and time step size on panel oscillation at3/4chord of flexible panel in shock/boundary layer interaction(xi/a=0.4)
Fig. 5
Vibration response at 3/4 chord of flexible panel
Fig. 6
Spectrum of vibration at different positions of panel
Fig. 7
Mean and selected instantaneous panel shapes,and x-t diagram of panel deflections
Fig. 8
Pressure contour and density contour for panel flutter at Φ=180°
Fig. 9
Effect of panel flutter on flow separation(xi/a=0.4)
Fig. 10
Skin-friction along panel and instantaneous pressure distribution on panel
Fig. 11
Streamwise velocity contours for xi/a=0.4 and over flexible panel and rigid-flat panel(Scale has been magnified by factor of 10 in y-direction)
Fig. 12
Velocity distribution along different axial positions in computational domain
Fig. 13
Effect of shock impingement location on panel flutter
Fig. 14
Power spectrum analysis of panel flutter
Fig. 15
Comparison of pressure difference between upper and lower surface of panel
Fig. 16
Mean deformation distribution of panel
Fig. 17
Comparison of vibration velocity in y-direction and pressure response at 3/4 chord of panel
Fig. 18
Effect of shock impingement location on flow separation
Fig. 19
Separation length normalized by corresponding rigid-flat panel result
Fig. 20
Skin-friction along panel with xi/a=0.35
Fig. 21
Streamwise velocity contours for xi/a=0.35 and over flexible panel and rigid-flat panel(Scale has been magnified by factor of 10 in y-direction)
Fig. 22
Pressure contours at Φ=180° under different working conditions(Scale has been magnified by factor of 10 in y-direction)
Fig. 23
Velocity distribution curves of different axial positions along y at Φ=180°
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