Application of Aeroelastic Tailoring for Load Alleviation on a Flying Demonstrator Wing

This article presents the application of aeroelastic tailoring in the design of wings for a flying demonstrator, as well as the validation of the design methodology with flight test results. The investigations were performed in the FLEXOP project (Flutter Free Flight Envelope Expansion for Economica...

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Bibliographic Details
Published inAerospace Vol. 9; no. 10; p. 535
Main Authors Krüger, Wolf R., Meddaikar, Yasser M., Dillinger, Johannes K. S., Sodja, Jurij, De Breuker, Roeland
Format Journal Article
LanguageEnglish
Published Basel MDPI AG 01.10.2022
Subjects
Active control
aeroelastic tailoring
Aeroelasticity
Aircraft
Composite materials
composite optimization
Couplings
Design optimization
Drone aircraft
Experiments
FLEXOP
Flight envelopes
Flight tests
Flutter
Free flight
Genetic algorithms
Laminated materials
Laminates
Load
Load alleviation
Optimization
UAV
Unmanned aerial vehicles
Vibration
Wing boxes
Wing design
Wing span
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Summary:This article presents the application of aeroelastic tailoring in the design of wings for a flying demonstrator, as well as the validation of the design methodology with flight test results. The investigations were performed in the FLEXOP project (Flutter Free Flight Envelope Expansion for Economical Performance Improvement), funded under the Horizon 2020 framework. This project aimed at the validation of methods and tools for active flutter control, as well as at the demonstration of the potential of passive load alleviation through composite tailoring. The technologies were to be demonstrated by the design, manufacturing and flight testing of an unmanned aerial vehicle of approximately 7 m wingspan. This article addresses the work towards the load alleviation goals. The design of the primary load-carrying wing-box in this task is performed using a joint DLR–TU Delft optimization strategy. Two sets of wings are designed in order to demonstrate the potential benefits of aeroelastic tailoring—first, a reference wing in which the laminates of the wing-box members are restricted to balanced and symmetric laminates; second, a tailored wing in which the laminates are allowed to be unbalanced, hence allowing for the shear–extension and bending–torsion couplings essential for aeroelastic tailoring. Both designs are numerically optimized, then manufactured and extensively tested to validate and improve the simulation models corresponding to the wing designs. Flight tests are performed, the results of which form the basis for the validation of the applied aeroelastic tailoring approach presented in the article.
ISSN:2226-4310
2226-4310
DOI:10.3390/aerospace9100535