Effect of Wing Pressure Distribution on Sonic-Boom Intensity of Supersonic Transport Aircrafts

Kefeng Zheng; Wenping Song; Han Nie; Yulin Ding; Jianling Qiao; Qing Chen; Zhonghua Han

doi:10.1007/978-981-97-4010-9_77

Effect of Wing Pressure Distribution on Sonic-Boom Intensity of Supersonic Transport Aircrafts

Kefeng Zheng, Wenping Song, Han Nie, Yulin Ding, Jianling Qiao, Qing Chen, Zhonghua Han

School of Aeronautics

Northwestern Polytechnical University Xian

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

Abstract

Low sonic-boom and low drag characteristics are both important for the next-generation supersonic transport aircraft. The natural-laminar-flow (NLF) wing design technology is able to remarkably reduce the friction drag and thus improve the cruising efficiency of an aircraft. It is achieved by aerodynamic shape design on the wing to obtain the required pressure distribution which can suppress the growth of unstable waves in the boundary layer. However, the change of the wing geometry and pressure distribution could influence the sonic-boom intensity of the aircraft. In order to compromise low sonic-boom and low drag characteristics, the mechanism of how the pressure distribution influences the sonic-boom intensity is of great interest to researchers. The objective of this article is to investigate the effect of wing pressure distribution on sonic-boom intensity and reveal the relationship between low sonic-boom design and natural-laminar-flow wing design on supersonic transport aircrafts. First, the CST method is used to disturb airfoils of a typical supersonic transport wing-body configuration to obtain a set of configurations with different wing pressure distributions. Second, the flow fields of these configurations are calculated using RANS equation, and the undertrack near-field overpressure is extracted from the flow field of each configuration. The equivalent area due to volume and equivalent area due to lift are also analyzed. Finally, the undertrack near-field overpressure is propagated to the ground using augmented Burgers equation. Results show that the variation of wing pressure distributions by disturbing airfoils has more significant influence on the equivalent area due to lift, which indicates that we can compromise low sonic-boom and low drag characteristics by restricting equivalent area due to lift during NLF wing design on supersonic transport aircrafts.

Original language	English
Title of host publication	2023 Asia-Pacific International Symposium on Aerospace Technology, APISAT 2023, Proceedings - Volume II
Editors	Song Fu
Publisher	Springer Science and Business Media Deutschland GmbH
Pages	999-1008
Number of pages	10
ISBN (Print)	9789819740093
DOIs	https://doi.org/10.1007/978-981-97-4010-9_77
State	Published - 2024
Event	Asia-Pacific International Symposium on Aerospace Technology, APISAT 2023 - Lingshui, China Duration: 16 Oct 2023 → 18 Oct 2023

Publication series

Name	Lecture Notes in Electrical Engineering
Volume	1051 LNEE
ISSN (Print)	1876-1100
ISSN (Electronic)	1876-1119

Conference

Conference	Asia-Pacific International Symposium on Aerospace Technology, APISAT 2023
Country/Territory	China
City	Lingshui
Period	16/10/23 → 18/10/23

Keywords

Equivalent area
Natural-laminar-flow design
Sonic-boom intensity
Supersonic transport aircraft
Wing pressure distribution

Access to Document

10.1007/978-981-97-4010-9_77

Cite this

Zheng, K., Song, W., Nie, H., Ding, Y., Qiao, J., Chen, Q., & Han, Z. (2024). Effect of Wing Pressure Distribution on Sonic-Boom Intensity of Supersonic Transport Aircrafts. In S. Fu (Ed.), 2023 Asia-Pacific International Symposium on Aerospace Technology, APISAT 2023, Proceedings - Volume II (pp. 999-1008). (Lecture Notes in Electrical Engineering; Vol. 1051 LNEE). Springer Science and Business Media Deutschland GmbH. https://doi.org/10.1007/978-981-97-4010-9_77

Zheng, Kefeng ; Song, Wenping ; Nie, Han et al. / Effect of Wing Pressure Distribution on Sonic-Boom Intensity of Supersonic Transport Aircrafts. 2023 Asia-Pacific International Symposium on Aerospace Technology, APISAT 2023, Proceedings - Volume II. editor / Song Fu. Springer Science and Business Media Deutschland GmbH, 2024. pp. 999-1008 (Lecture Notes in Electrical Engineering).

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title = "Effect of Wing Pressure Distribution on Sonic-Boom Intensity of Supersonic Transport Aircrafts",

abstract = "Low sonic-boom and low drag characteristics are both important for the next-generation supersonic transport aircraft. The natural-laminar-flow (NLF) wing design technology is able to remarkably reduce the friction drag and thus improve the cruising efficiency of an aircraft. It is achieved by aerodynamic shape design on the wing to obtain the required pressure distribution which can suppress the growth of unstable waves in the boundary layer. However, the change of the wing geometry and pressure distribution could influence the sonic-boom intensity of the aircraft. In order to compromise low sonic-boom and low drag characteristics, the mechanism of how the pressure distribution influences the sonic-boom intensity is of great interest to researchers. The objective of this article is to investigate the effect of wing pressure distribution on sonic-boom intensity and reveal the relationship between low sonic-boom design and natural-laminar-flow wing design on supersonic transport aircrafts. First, the CST method is used to disturb airfoils of a typical supersonic transport wing-body configuration to obtain a set of configurations with different wing pressure distributions. Second, the flow fields of these configurations are calculated using RANS equation, and the undertrack near-field overpressure is extracted from the flow field of each configuration. The equivalent area due to volume and equivalent area due to lift are also analyzed. Finally, the undertrack near-field overpressure is propagated to the ground using augmented Burgers equation. Results show that the variation of wing pressure distributions by disturbing airfoils has more significant influence on the equivalent area due to lift, which indicates that we can compromise low sonic-boom and low drag characteristics by restricting equivalent area due to lift during NLF wing design on supersonic transport aircrafts.",

keywords = "Equivalent area, Natural-laminar-flow design, Sonic-boom intensity, Supersonic transport aircraft, Wing pressure distribution",

author = "Kefeng Zheng and Wenping Song and Han Nie and Yulin Ding and Jianling Qiao and Qing Chen and Zhonghua Han",

note = "Publisher Copyright: {\textcopyright} The Author(s), under exclusive license to Springer Nature Singapore Pte Ltd. 2024.; Asia-Pacific International Symposium on Aerospace Technology, APISAT 2023 ; Conference date: 16-10-2023 Through 18-10-2023",

year = "2024",

doi = "10.1007/978-981-97-4010-9_77",

language = "英语",

isbn = "9789819740093",

series = "Lecture Notes in Electrical Engineering",

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Zheng, K, Song, W, Nie, H, Ding, Y, Qiao, J, Chen, Q & Han, Z 2024, Effect of Wing Pressure Distribution on Sonic-Boom Intensity of Supersonic Transport Aircrafts. in S Fu (ed.), 2023 Asia-Pacific International Symposium on Aerospace Technology, APISAT 2023, Proceedings - Volume II. Lecture Notes in Electrical Engineering, vol. 1051 LNEE, Springer Science and Business Media Deutschland GmbH, pp. 999-1008, Asia-Pacific International Symposium on Aerospace Technology, APISAT 2023, Lingshui, China, 16/10/23. https://doi.org/10.1007/978-981-97-4010-9_77

Effect of Wing Pressure Distribution on Sonic-Boom Intensity of Supersonic Transport Aircrafts. / Zheng, Kefeng; Song, Wenping; Nie, Han et al.
2023 Asia-Pacific International Symposium on Aerospace Technology, APISAT 2023, Proceedings - Volume II. ed. / Song Fu. Springer Science and Business Media Deutschland GmbH, 2024. p. 999-1008 (Lecture Notes in Electrical Engineering; Vol. 1051 LNEE).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

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AU - Ding, Yulin

AU - Qiao, Jianling

AU - Chen, Qing

AU - Han, Zhonghua

N1 - Publisher Copyright: © The Author(s), under exclusive license to Springer Nature Singapore Pte Ltd. 2024.

PY - 2024

Y1 - 2024

N2 - Low sonic-boom and low drag characteristics are both important for the next-generation supersonic transport aircraft. The natural-laminar-flow (NLF) wing design technology is able to remarkably reduce the friction drag and thus improve the cruising efficiency of an aircraft. It is achieved by aerodynamic shape design on the wing to obtain the required pressure distribution which can suppress the growth of unstable waves in the boundary layer. However, the change of the wing geometry and pressure distribution could influence the sonic-boom intensity of the aircraft. In order to compromise low sonic-boom and low drag characteristics, the mechanism of how the pressure distribution influences the sonic-boom intensity is of great interest to researchers. The objective of this article is to investigate the effect of wing pressure distribution on sonic-boom intensity and reveal the relationship between low sonic-boom design and natural-laminar-flow wing design on supersonic transport aircrafts. First, the CST method is used to disturb airfoils of a typical supersonic transport wing-body configuration to obtain a set of configurations with different wing pressure distributions. Second, the flow fields of these configurations are calculated using RANS equation, and the undertrack near-field overpressure is extracted from the flow field of each configuration. The equivalent area due to volume and equivalent area due to lift are also analyzed. Finally, the undertrack near-field overpressure is propagated to the ground using augmented Burgers equation. Results show that the variation of wing pressure distributions by disturbing airfoils has more significant influence on the equivalent area due to lift, which indicates that we can compromise low sonic-boom and low drag characteristics by restricting equivalent area due to lift during NLF wing design on supersonic transport aircrafts.

AB - Low sonic-boom and low drag characteristics are both important for the next-generation supersonic transport aircraft. The natural-laminar-flow (NLF) wing design technology is able to remarkably reduce the friction drag and thus improve the cruising efficiency of an aircraft. It is achieved by aerodynamic shape design on the wing to obtain the required pressure distribution which can suppress the growth of unstable waves in the boundary layer. However, the change of the wing geometry and pressure distribution could influence the sonic-boom intensity of the aircraft. In order to compromise low sonic-boom and low drag characteristics, the mechanism of how the pressure distribution influences the sonic-boom intensity is of great interest to researchers. The objective of this article is to investigate the effect of wing pressure distribution on sonic-boom intensity and reveal the relationship between low sonic-boom design and natural-laminar-flow wing design on supersonic transport aircrafts. First, the CST method is used to disturb airfoils of a typical supersonic transport wing-body configuration to obtain a set of configurations with different wing pressure distributions. Second, the flow fields of these configurations are calculated using RANS equation, and the undertrack near-field overpressure is extracted from the flow field of each configuration. The equivalent area due to volume and equivalent area due to lift are also analyzed. Finally, the undertrack near-field overpressure is propagated to the ground using augmented Burgers equation. Results show that the variation of wing pressure distributions by disturbing airfoils has more significant influence on the equivalent area due to lift, which indicates that we can compromise low sonic-boom and low drag characteristics by restricting equivalent area due to lift during NLF wing design on supersonic transport aircrafts.

KW - Equivalent area

KW - Natural-laminar-flow design

KW - Sonic-boom intensity

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Zheng K, Song W, Nie H, Ding Y, Qiao J, Chen Q et al. Effect of Wing Pressure Distribution on Sonic-Boom Intensity of Supersonic Transport Aircrafts. In Fu S, editor, 2023 Asia-Pacific International Symposium on Aerospace Technology, APISAT 2023, Proceedings - Volume II. Springer Science and Business Media Deutschland GmbH. 2024. p. 999-1008. (Lecture Notes in Electrical Engineering). doi: 10.1007/978-981-97-4010-9_77

Effect of Wing Pressure Distribution on Sonic-Boom Intensity of Supersonic Transport Aircrafts

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