Concurrent wing and high-lift system aerostructural optimization
Concurrent wing and high-lift system aerostructural optimization
A method is presented for concurrent aerostructural optimization of wing planform, airfoil and high lift devices. The optimization is defined to minimize the aircraft fuel consumption for cruise, while satisfying the field performance requirements. A coupled adjoint aerostructural tool, that couples a quasi-three-dimensional aerodynamic analysis method with a finite beam element structural analysis is used for this optimization. The Pressure Difference Rule is implemented in the quasi-three-dimensional analysis and is coupled to the aerostructural analysis tool in order to compute the maximum lift coefficient of an elastic wing. The proposed method is able to compute the maximum wing lift coefficient with reasonable accuracy compared to high-fidelity CFD tools that require much higher computational cost. The coupled aerostructural system is solved using the Newton method. The sensitivities of the outputs of the developed tool with respect to the input variables are computed through combined use of the chain rule of differentiation, automatic differentiation and coupled-adjoint method. The results of a sequential optimization, where the wing shape and high lift device shape are optimized sequentially, is compared to the results of simultaneous wing and high lift device optimization
947–963
van den Kieboom, K. T. H.
f0346825-60d8-4aa6-a7f9-ef95135d3c63
Elham, Ali
676043c6-547a-4081-8521-1567885ad41a
1 March 2018
van den Kieboom, K. T. H.
f0346825-60d8-4aa6-a7f9-ef95135d3c63
Elham, Ali
676043c6-547a-4081-8521-1567885ad41a
van den Kieboom, K. T. H. and Elham, Ali
(2018)
Concurrent wing and high-lift system aerostructural optimization.
Structural and Multidisciplinary Optimization, 57 (3), .
(doi:10.1007/s00158-017-1787-0).
Abstract
A method is presented for concurrent aerostructural optimization of wing planform, airfoil and high lift devices. The optimization is defined to minimize the aircraft fuel consumption for cruise, while satisfying the field performance requirements. A coupled adjoint aerostructural tool, that couples a quasi-three-dimensional aerodynamic analysis method with a finite beam element structural analysis is used for this optimization. The Pressure Difference Rule is implemented in the quasi-three-dimensional analysis and is coupled to the aerostructural analysis tool in order to compute the maximum lift coefficient of an elastic wing. The proposed method is able to compute the maximum wing lift coefficient with reasonable accuracy compared to high-fidelity CFD tools that require much higher computational cost. The coupled aerostructural system is solved using the Newton method. The sensitivities of the outputs of the developed tool with respect to the input variables are computed through combined use of the chain rule of differentiation, automatic differentiation and coupled-adjoint method. The results of a sequential optimization, where the wing shape and high lift device shape are optimized sequentially, is compared to the results of simultaneous wing and high lift device optimization
This record has no associated files available for download.
More information
Accepted/In Press date: 11 August 2017
Published date: 1 March 2018
Identifiers
Local EPrints ID: 470878
URI: http://eprints.soton.ac.uk/id/eprint/470878
ISSN: 1615-147X
PURE UUID: 44164f85-a81d-41c9-903d-d75df3a439af
Catalogue record
Date deposited: 20 Oct 2022 16:45
Last modified: 16 Mar 2024 21:27
Export record
Altmetrics
Contributors
Author:
K. T. H. van den Kieboom
Download statistics
Downloads from ePrints over the past year. Other digital versions may also be available to download e.g. from the publisher's website.
View more statistics