Multidisciplinary design optimization of twin-fuselage aircraft with boundary-layer-ingesting distributed propulsion
Multidisciplinary design optimization of twin-fuselage aircraft with boundary-layer-ingesting distributed propulsion
The requirements of sustainable and fuel-efficient next-generation air transportation place greater demands on future aircraft design. Distributed electric propulsion (DEP) and twin-fuselage (TF) are promising concepts to improve aircraft aerodynamic efficiency and flight performance. This paper aims to develop a multidisciplinary design analysis and optimization (MDAO) framework for the TF DEP aircraft concept to investigate the potential of introducing these two technologies in improving aircraft energy efficiency. The most important effect modeled in this study is the influence of the boundary-layer-ingesting DEP system on the propulsive efficiency. Besides, analytical models are derived for the mass, aerodynamic, and performance analysis, separately. Design cases of a wing-segment-mounted DEP, and a TF DEP unmanned aerial vehicle are analyzed to investigate the design space of DEP parameters and to demonstrate the MDAO process. The results show that the best arrangement of the DEP is to distribute the propulsors evenly on the three wing segments of the wing divided by the two fuselages. The optimization leads to more than a 65% increment in the endurance and an 8% reduction in the takeoff mass of the exemplary aircraft.
1588-1602
Ma, Yiyuan
ccea8698-10f9-4f34-9cc7-c4983400b103
Zhang, Wei
e896f9bd-f169-4c5a-a465-cadf5d5a96a3
Elham, Ali
676043c6-547a-4081-8521-1567885ad41a
1 November 2022
Ma, Yiyuan
ccea8698-10f9-4f34-9cc7-c4983400b103
Zhang, Wei
e896f9bd-f169-4c5a-a465-cadf5d5a96a3
Elham, Ali
676043c6-547a-4081-8521-1567885ad41a
Ma, Yiyuan, Zhang, Wei and Elham, Ali
(2022)
Multidisciplinary design optimization of twin-fuselage aircraft with boundary-layer-ingesting distributed propulsion.
Journal of Aircraft, 59 (6), .
(doi:10.2514/1.C036559).
Abstract
The requirements of sustainable and fuel-efficient next-generation air transportation place greater demands on future aircraft design. Distributed electric propulsion (DEP) and twin-fuselage (TF) are promising concepts to improve aircraft aerodynamic efficiency and flight performance. This paper aims to develop a multidisciplinary design analysis and optimization (MDAO) framework for the TF DEP aircraft concept to investigate the potential of introducing these two technologies in improving aircraft energy efficiency. The most important effect modeled in this study is the influence of the boundary-layer-ingesting DEP system on the propulsive efficiency. Besides, analytical models are derived for the mass, aerodynamic, and performance analysis, separately. Design cases of a wing-segment-mounted DEP, and a TF DEP unmanned aerial vehicle are analyzed to investigate the design space of DEP parameters and to demonstrate the MDAO process. The results show that the best arrangement of the DEP is to distribute the propulsors evenly on the three wing segments of the wing divided by the two fuselages. The optimization leads to more than a 65% increment in the endurance and an 8% reduction in the takeoff mass of the exemplary aircraft.
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Accepted/In Press date: 18 May 2022
e-pub ahead of print date: 3 June 2022
Published date: 1 November 2022
Identifiers
Local EPrints ID: 483421
URI: http://eprints.soton.ac.uk/id/eprint/483421
ISSN: 0021-8669
PURE UUID: 94f6cef0-966d-4dae-a48f-fe89f7b53208
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Date deposited: 30 Oct 2023 17:57
Last modified: 17 Mar 2024 05:10
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Author:
Yiyuan Ma
Author:
Wei Zhang
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