Impact of Aerodynamic Interactions on Aeroelastic Stability of Wing-Propeller Systems

This paper presents initial findings from aeroelastic studies conducted on a wing-propeller model, aimed at evaluating the impact of aerodynamic interactions on wing flutter mechanisms and overall aeroelastic performance. The flutter onset is assessed using a frequency-domain method. Mid-fidelity to...

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Bibliographic Details
Published inApplied sciences Vol. 14; no. 19; p. 8709
Main Authors Böhnisch, Nils, Braun, Carsten, Marzocca, Pier, Muscarello, Vincenzo
Format Journal Article
LanguageEnglish
Published Basel MDPI AG 01.10.2024
Subjects
aerodynamic interactions
Aerodynamics
aeroelasticity
Aircraft
Design
Dust
Efficiency
Fluid-structure interaction
Investigations
multibody dynamics
Public software
Simulation
vortex particle method
Vortices
whirl flutter
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Summary:This paper presents initial findings from aeroelastic studies conducted on a wing-propeller model, aimed at evaluating the impact of aerodynamic interactions on wing flutter mechanisms and overall aeroelastic performance. The flutter onset is assessed using a frequency-domain method. Mid-fidelity tools based on the time-domain approach are then exploited to account for the complex aerodynamic interaction between the propeller and the wing. Specifically, the open-source software DUST and MBDyn are leveraged for this purpose. The investigation covers both windmilling and thrusting conditions. During the trim process, adjustments to the collective pitch of the blades are made to ensure consistency across operational points. Time histories are then analyzed to pinpoint flutter onset, and corresponding frequencies and damping ratios are identified. The results reveal a marginal destabilizing effect of aerodynamic interaction on flutter speed, approximately 5%. Notably, the thrusting condition demonstrates a greater destabilizing influence compared to the windmilling case. These comprehensive findings enhance the understanding of the aerodynamic behavior of such systems and offer valuable insights for early design predictions and the development of streamlined models for future endeavors.
ISSN:2076-3417
2076-3417
DOI:10.3390/app14198709