Acta Aeronautica et Astronautica Sinica ›› 2024, Vol. 45 ›› Issue (6): 629613-629613.doi: 10.7527/S1000-6893.2023.29613
• Special Topic: New Conceptual Aerodynamic Layout Design for Aircraft • Previous Articles
Junfu LI1,2, Qing CHEN1,3,4, Wei WANG2, Zhonghua HAN1,3,4(
), Yuting TAN2, Yulin DING1,3,4, Lu XIE2, Jianling QIAO1,3,4, Ke SONG1,3,4, Junqiang AI2
CJA
Received:2023-09-19
Revised:2023-10-07
Accepted:2023-10-24
Online:2023-11-02
Published:2023-11-01
Contact:
Zhonghua HAN
E-mail:hanzh@nwpu.edu.cn
Supported by:CLC Number:
Junfu LI, Qing CHEN, Wei WANG, Zhonghua HAN, Yuting TAN, Yulin DING, Lu XIE, Jianling QIAO, Ke SONG, Junqiang AI. Design of low sonic boom high efficiency layout for advanced supersonic civil aircraft[J]. Acta Aeronautica et Astronautica Sinica, 2024, 45(6): 629613-629613.
Fig.1
Schematic of sonic boom prediction method for near-field prediction coupled far-field propagation
Fig.2
Flow of JSGD anti-design method[16]
Fig.3
Mixed reliability anti-design process based on PNFO
Fig.4
Three-view drawing of layout scheme (XC-01)
Fig.5
Design features of XC-01 layout
Fig.6
Overpressure distribution of XC-01 layout
Fig.7
Far-field and near-field sonic boom signal at triploid body length below XC-01 layout
Fig.8
Body profile comparison of XC-01 layout and XC-02 layout
Fig.9
Equivalent cross-sectional area matching
Fig.10
Near-field and far-field sonic boom signal below aircraft (Ma=1.6, H=16 km)
Fig.11
Flow field characteristics of shock wave and expansion wave
Fig.12
Shock wave and expansion wave reflection in near-field sonic boom signal
Fig.13
Comparison of XC-02 and XC-03 layouts
Fig.14
Flow field characteristics of XC-02 and XC-03 layouts at symmetric surface
Fig.15
Far-field and near-field sonic boom signal sonic boom signal below aircraft of XC-02and XC-03 layouts
Fig.16
Converted equivalent area comparison of XC-03 and XC-04 layouts
Fig.17
Body profile comparison of XC-03 and XC-04 layouts
Fig.18
Far-field and near-field sonic boom signal sonic boom signal below aircraft of XC-03and XC-04 layouts
Fig.19
Three times low sonic boom design
Fig.20
Flow field characteristics of XC-01 and XC-04 layout at symmetric surface
Fig.21
Afterbody flow field analysis of XC-04 and XC-04 layouts
Fig.22
Comparison of near-field sonic boom signal at triploid body length below XC-01 and XC-04 layout
Fig.23
Propagation process of sonic boom signal of XC-01 and XC-04 layouts
Fig.24
Comparison of far-field sonic boom signal of XC-01 and XC-04 layouts
Fig.25
Ground waveform spectral distribution of XC-01 and XC-04 layouts
Fig.26
Comparison of near field waveform at 20°and 40° circumferential angle of XC-01 and XC-04 layouts
Fig.27
Comparison of far field waveform at 20° and 40° circumferential angle of XC-01 and XC-04 layouts
Fig.28
Comparison of perceived loudness in decibel of sonic boom tapestry between XC-01 and XC-04 layouts
Fig.29
Aerodynamic characteristics of XC-01 and XC-04 layouts
Fig.30
Perceived loudness in decibel at different heights
Fig.31
Perceived loudness in decibel at different heights at 0° circumferential angle
Fig.32
Far-field propagation waveform at different heights
Fig.33
Perceived loudness in decibel at different Mach numbers
Fig.34
Perceived loudness in decibel at different Mach numbers at 0°circumferential angle
Fig.35
Comparison of actual and theoretical equivalent cross-sectional areas at different inner wing swept angles and different outer wing swept angles
Fig.36
Perceived loudness in decibel at different inner wing swept angles and different outer wing swept angles
Fig.37
Aerodynamic characteristics at different Mach numbers
Fig.38
Aerodynamic characteristics at different flying heights
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