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Development of a multi-field computational tool for high-fidelity static aeroelastic simulations

Development of a multi-field computational tool for high-fidelity static aeroelastic simulations
Development of a multi-field computational tool for high-fidelity static aeroelastic simulations
A new method for high-fidelity aeroelastic static analysis of composite laminated wings is proposed. The structural analysis and the fluid-dynamic analysis are coupled in a heterogeneous staggered process. The Finite Element Method (FEM), the Carrera Unified Formulation (CUF) and Equivalent Plate Modelling (EPM) are combined to model complex three-dimensional geometries in a bi-dimensional framework; Computational Fluid Dynamics (CFD) is employed to solve the Navier-Stokes equations and different turbulence models (i.e. Spalart-Allmaras) through SU2, an open-source software that implements C++ routines for 3D fluid-dynamics analysis. The Moving Least Square patch technique is adopted to manage the fluid-structure interaction. The use of an equivalent plate model, as opposite to 1D models often employed in the literature, shows competitive performances in terms of number of degrees of freedom. High-fidelity aerodynamics allows studying non-linear phenomena associated to irregularities of the fluid-structure interaction, showing a level of accuracy that low-fidelity methods such as Vortex Lattice Method (VLM) and Doublet Lattice Method (DLM) are unable to provide. Such advantages are balanced by the need to elaborate a staggered iterative method for the resolution of static aeroelastic problems, which leads to higher computational costs.
Aeroelasticity, Composite Materials, FEM, CFD
2474-3941
236-266
Grifo, Marco
be26eb12-4ee5-4ea6-9aed-79f9136b53ca
Da Ronch, Andrea
a2f36b97-b881-44e9-8a78-dd76fdf82f1a
Milazzo, Alberto
4a4755f1-b710-4f4c-9cd6-4e6c69de4a71
Benedetti, Ivano
90848804-4c05-499d-a45f-cedda6ff6925
Di Poala, Mario
Fratini, Livan
Micari, Fabrizio
Pirrotta, Antonina
Grifo, Marco
be26eb12-4ee5-4ea6-9aed-79f9136b53ca
Da Ronch, Andrea
a2f36b97-b881-44e9-8a78-dd76fdf82f1a
Milazzo, Alberto
4a4755f1-b710-4f4c-9cd6-4e6c69de4a71
Benedetti, Ivano
90848804-4c05-499d-a45f-cedda6ff6925
Di Poala, Mario
Fratini, Livan
Micari, Fabrizio
Pirrotta, Antonina

Grifo, Marco, Da Ronch, Andrea, Milazzo, Alberto and Benedetti, Ivano (2023) Development of a multi-field computational tool for high-fidelity static aeroelastic simulations. Di Poala, Mario, Fratini, Livan, Micari, Fabrizio and Pirrotta, Antonina (eds.) In Theoretical and Applied Mechanics. pp. 236-266 . (doi:10.21741/9781644902431-43).

Record type: Conference or Workshop Item (Paper)

Abstract

A new method for high-fidelity aeroelastic static analysis of composite laminated wings is proposed. The structural analysis and the fluid-dynamic analysis are coupled in a heterogeneous staggered process. The Finite Element Method (FEM), the Carrera Unified Formulation (CUF) and Equivalent Plate Modelling (EPM) are combined to model complex three-dimensional geometries in a bi-dimensional framework; Computational Fluid Dynamics (CFD) is employed to solve the Navier-Stokes equations and different turbulence models (i.e. Spalart-Allmaras) through SU2, an open-source software that implements C++ routines for 3D fluid-dynamics analysis. The Moving Least Square patch technique is adopted to manage the fluid-structure interaction. The use of an equivalent plate model, as opposite to 1D models often employed in the literature, shows competitive performances in terms of number of degrees of freedom. High-fidelity aerodynamics allows studying non-linear phenomena associated to irregularities of the fluid-structure interaction, showing a level of accuracy that low-fidelity methods such as Vortex Lattice Method (VLM) and Doublet Lattice Method (DLM) are unable to provide. Such advantages are balanced by the need to elaborate a staggered iterative method for the resolution of static aeroelastic problems, which leads to higher computational costs.

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e-pub ahead of print date: 17 March 2022
Published date: 2023
Keywords: Aeroelasticity, Composite Materials, FEM, CFD

Identifiers

Local EPrints ID: 495384
URI: http://eprints.soton.ac.uk/id/eprint/495384
DOI: doi:10.21741/9781644902431-43
ISSN: 2474-3941
PURE UUID: 2086c1b4-1a12-4da2-9569-daf7fe8fa8a1
ORCID for Andrea Da Ronch: ORCID iD orcid.org/0000-0001-7428-6935

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Date deposited: 12 Nov 2024 17:42
Last modified: 13 Nov 2024 02:46

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Contributors

Author: Marco Grifo
Author: Andrea Da Ronch ORCID iD
Author: Alberto Milazzo
Author: Ivano Benedetti
Editor: Mario Di Poala
Editor: Livan Fratini
Editor: Fabrizio Micari
Editor: Antonina Pirrotta

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