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High-fidelity aeroelastic transonic analysis using higher-order structural models

High-fidelity aeroelastic transonic analysis using higher-order structural models
High-fidelity aeroelastic transonic analysis using higher-order structural models
A novel computational approach for static aeroelastic analysis of metal and composite wings in transonic flows is proposed. Static aeroelastic analysis is often performed coupling beam/plate structural formulations with low-fidelity inviscid and irrotational aerodynamics. When high subsonic, transonic or supersonic regimes are met, low-fidelity aerodynamics is unable to accurately describe flow separation, viscous phenomena, and/or shock waves, unless suitable corrections are considered. This work combines the use of a variable-order kinematics structural model with Computational Fluid Dynamics (CFD), with the aim of developing a flexible computational aeroelastic framework. In particular, the structural model is based on the Carrera Unified Formulation and Equivalent Plate Modelling, whose governing equations are then solved through the Finite Element Method. The CFD analysis is performed using the high-fidelity open-source software SU2. The fluid–structure interaction is captured resorting to an energetic approach based on the Moving Least Squares patch technique. The generality and flexibility of the developed tool is demonstrated considering: the structural analysis of a wing exhibiting taper ratio, sweep angle, spars and ribs; the aeroelastic static analysis of a transonic AGARD 445.6 wing; and a prototype aeroelastic tailoring study on a composite wing. Comparison with available literature results confirms the robustness of the approach.
Carrera unified formulation, Composite structures, Computational fluid dynamics (CFD), Equivalent plate modelling, Fluid–structure interaction, Static aeroelasticity, Computational fluid dynamics
0263-8223
Grifo, Marco
be26eb12-4ee5-4ea6-9aed-79f9136b53ca
Gulizzi, Vincenzo
821eb1f4-a989-4785-a651-d1556f5c93ac
Milazzo, Alberto
50a659c1-080b-4e78-a87a-98bf10f877ba
Da Ronch, Andrea
a2f36b97-b881-44e9-8a78-dd76fdf82f1a
Benedetti, Ivano
20d4c25e-c3e6-4bba-90fb-69b98fb2ed4f
Grifo, Marco
be26eb12-4ee5-4ea6-9aed-79f9136b53ca
Gulizzi, Vincenzo
821eb1f4-a989-4785-a651-d1556f5c93ac
Milazzo, Alberto
50a659c1-080b-4e78-a87a-98bf10f877ba
Da Ronch, Andrea
a2f36b97-b881-44e9-8a78-dd76fdf82f1a
Benedetti, Ivano
20d4c25e-c3e6-4bba-90fb-69b98fb2ed4f

Grifo, Marco, Gulizzi, Vincenzo, Milazzo, Alberto, Da Ronch, Andrea and Benedetti, Ivano (2023) High-fidelity aeroelastic transonic analysis using higher-order structural models. Composite Structures, 321, [117315]. (doi:10.1016/j.compstruct.2023.117315).

Record type: Article

Abstract

A novel computational approach for static aeroelastic analysis of metal and composite wings in transonic flows is proposed. Static aeroelastic analysis is often performed coupling beam/plate structural formulations with low-fidelity inviscid and irrotational aerodynamics. When high subsonic, transonic or supersonic regimes are met, low-fidelity aerodynamics is unable to accurately describe flow separation, viscous phenomena, and/or shock waves, unless suitable corrections are considered. This work combines the use of a variable-order kinematics structural model with Computational Fluid Dynamics (CFD), with the aim of developing a flexible computational aeroelastic framework. In particular, the structural model is based on the Carrera Unified Formulation and Equivalent Plate Modelling, whose governing equations are then solved through the Finite Element Method. The CFD analysis is performed using the high-fidelity open-source software SU2. The fluid–structure interaction is captured resorting to an energetic approach based on the Moving Least Squares patch technique. The generality and flexibility of the developed tool is demonstrated considering: the structural analysis of a wing exhibiting taper ratio, sweep angle, spars and ribs; the aeroelastic static analysis of a transonic AGARD 445.6 wing; and a prototype aeroelastic tailoring study on a composite wing. Comparison with available literature results confirms the robustness of the approach.

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More information

Accepted/In Press date: 28 June 2023
e-pub ahead of print date: 4 July 2023
Published date: 1 October 2023
Additional Information: Funding Information: IB and ADR acknowledge the support of the Department of Engineering of the University of Palermo, Italy through the grant Premio gruppo di ricerca 2020. The Authors acknowledge the support of the computational resources of IRIDIS at the University of Southampton, UK. Publisher Copyright: © 2023 Elsevier Ltd
Keywords: Carrera unified formulation, Composite structures, Computational fluid dynamics (CFD), Equivalent plate modelling, Fluid–structure interaction, Static aeroelasticity, Computational fluid dynamics

Identifiers

Local EPrints ID: 483656
URI: http://eprints.soton.ac.uk/id/eprint/483656
ISSN: 0263-8223
PURE UUID: f096f9f4-2a03-4fe6-b011-69d567344fad
ORCID for Andrea Da Ronch: ORCID iD orcid.org/0000-0001-7428-6935

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Date deposited: 02 Nov 2023 18:27
Last modified: 13 Jun 2024 01:45

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Contributors

Author: Marco Grifo
Author: Vincenzo Gulizzi
Author: Alberto Milazzo
Author: Andrea Da Ronch ORCID iD
Author: Ivano Benedetti

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