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Design optimization of a two-dimensional subsonic engine air intake

Design optimization of a two-dimensional subsonic engine air intake
Design optimization of a two-dimensional subsonic engine air intake
A novel geometry modeling technique is defined for the optimization of pressure recovery through a two dimensional subsonic diffuser based on that of a Formula One race car airbox. The airbox design procedure involves considering the expansion of the flow entering the airbox coupled with a bend through 90 deg. Both of these features are discussed separately in terms of parameterization approaches before the most suitable techniques are united in the final optimization study producing an airbox harboring strong local geometric control and with a set of design variables compact enough to retain optimizer efficiency. A global Krig response surface model is employed to support our optimization studies, comprising design of experiments and updates based upon the expected improvement to the objective function followed by a local exploration in a reduced area of the design space. We find that we can efficiently converge to an optimum airbox design. The geometry modeling technique discussed allows for potentially radical designs with high pressure recoveries.
0001-1452
2672-2681
Hoyle, N.
133e2089-49ad-4755-829a-43e65450013e
Bressloff, N.W.
4f531e64-dbb3-41e3-a5d3-e6a5a7a77c92
Keane, A.J.
26d7fa33-5415-4910-89d8-fb3620413def
Hoyle, N.
133e2089-49ad-4755-829a-43e65450013e
Bressloff, N.W.
4f531e64-dbb3-41e3-a5d3-e6a5a7a77c92
Keane, A.J.
26d7fa33-5415-4910-89d8-fb3620413def

Hoyle, N., Bressloff, N.W. and Keane, A.J. (2006) Design optimization of a two-dimensional subsonic engine air intake. AIAA Journal, 44 (11), 2672-2681. (doi:10.2514/1.16123).

Record type: Article

Abstract

A novel geometry modeling technique is defined for the optimization of pressure recovery through a two dimensional subsonic diffuser based on that of a Formula One race car airbox. The airbox design procedure involves considering the expansion of the flow entering the airbox coupled with a bend through 90 deg. Both of these features are discussed separately in terms of parameterization approaches before the most suitable techniques are united in the final optimization study producing an airbox harboring strong local geometric control and with a set of design variables compact enough to retain optimizer efficiency. A global Krig response surface model is employed to support our optimization studies, comprising design of experiments and updates based upon the expected improvement to the objective function followed by a local exploration in a reduced area of the design space. We find that we can efficiently converge to an optimum airbox design. The geometry modeling technique discussed allows for potentially radical designs with high pressure recoveries.

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Published date: 2006

Identifiers

Local EPrints ID: 43641
URI: http://eprints.soton.ac.uk/id/eprint/43641
DOI: doi:10.2514/1.16123
ISSN: 0001-1452
PURE UUID: 21497c61-b25f-4b2b-9460-720ee88642ee
ORCID for A.J. Keane: ORCID iD orcid.org/0000-0001-7993-1569

Catalogue record

Date deposited: 29 Jan 2007
Last modified: 16 Mar 2024 02:53

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Contributors

Author: N. Hoyle
Author: N.W. Bressloff
Author: A.J. Keane ORCID iD

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