Wind tunnel experiments of bending-torsion and body-freedom flutter on flying wing unmanned aerial vehicles
Wind tunnel experiments are performed on a flying wing model to investigate the effects of key design parameters and their cross-interactions on the flutter speed and frequency for bending-torsion flutter (BTF) and body-freedom flutter (BFF). These design parameters include wing sweep angle, mass of...
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sg-ntu-dr.10356-1730992024-01-13T16:48:27Z Wind tunnel experiments of bending-torsion and body-freedom flutter on flying wing unmanned aerial vehicles Ang, Elijah Hao Wei Leo, Daryl Jieli Tan, Jun Kang Tay, Jonathan Chien Ming Cui, Yongdong Ng, Bing Feng School of Mechanical and Aerospace Engineering Engineering::Mechanical engineering Wind Tunnel Body-Freedom Flutter Wind tunnel experiments are performed on a flying wing model to investigate the effects of key design parameters and their cross-interactions on the flutter speed and frequency for bending-torsion flutter (BTF) and body-freedom flutter (BFF). These design parameters include wing sweep angle, mass of tip weights, and location of weights along the wingspan. A slider and rail setup for BFF is designed to enable rigid-body pitching and plunging degrees-of-freedom, while a custom fixed clamp is used to perform the BTF experiments. BTF and BFF experiences different dominant modes while undergoing flutter, with the former's dominant mode being torsion and the latter being the rigid-body short-period mode. For BTF, flutter speeds increase as weights are moved towards the wingtip or increasing tip weights, which increases the inertia of the system to enhance stability. The effect is opposite for BFF as the movement of weights outboard or increase of tip weights result in a rearwards shift of the centre of gravity that destabilises the system. In general, a higher sweep angle leads to increased sensitivity of flutter speeds to changes in mass of tip weights or changes to spanwise location of the weights. The findings from this study provide insights to the design of flying wing unmanned aerial vehicles for increased stability margins. Nanyang Technological University Submitted/Accepted version The first and last authors acknowledge the funding support from Temasek Laboratories at National University of Singapore. The first author acknowledges the support from the Nanyang President’s Graduate Scholarship. 2024-01-11T23:44:25Z 2024-01-11T23:44:25Z 2024 Journal Article Ang, E. H. W., Leo, D. J., Tan, J. K., Tay, J. C. M., Cui, Y. & Ng, B. F. (2024). Wind tunnel experiments of bending-torsion and body-freedom flutter on flying wing unmanned aerial vehicles. Aerospace Science and Technology, 144, 108798-. https://dx.doi.org/10.1016/j.ast.2023.108798 1270-9638 https://hdl.handle.net/10356/173099 10.1016/j.ast.2023.108798 2-s2.0-85179485373 144 108798 en Aerospace Science and Technology © 2023 Elsevier Masson SAS. All rights reserved. This article may be downloaded for personal use only. Any other use requires prior permission of the copyright holder. The Version of Record is available online at http://doi.org/10.1016/j.ast.2023.108798. application/pdf |
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Engineering::Mechanical engineering Wind Tunnel Body-Freedom Flutter Ang, Elijah Hao Wei Leo, Daryl Jieli Tan, Jun Kang Tay, Jonathan Chien Ming Cui, Yongdong Ng, Bing Feng Wind tunnel experiments of bending-torsion and body-freedom flutter on flying wing unmanned aerial vehicles |
| description |
Wind tunnel experiments are performed on a flying wing model to investigate the effects of key design parameters and their cross-interactions on the flutter speed and frequency for bending-torsion flutter (BTF) and body-freedom flutter (BFF). These design parameters include wing sweep angle, mass of tip weights, and location of weights along the wingspan. A slider and rail setup for BFF is designed to enable rigid-body pitching and plunging degrees-of-freedom, while a custom fixed clamp is used to perform the BTF experiments. BTF and BFF experiences different dominant modes while undergoing flutter, with the former's dominant mode being torsion and the latter being the rigid-body short-period mode. For BTF, flutter speeds increase as weights are moved towards the wingtip or increasing tip weights, which increases the inertia of the system to enhance stability. The effect is opposite for BFF as the movement of weights outboard or increase of tip weights result in a rearwards shift of the centre of gravity that destabilises the system. In general, a higher sweep angle leads to increased sensitivity of flutter speeds to changes in mass of tip weights or changes to spanwise location of the weights. The findings from this study provide insights to the design of flying wing unmanned aerial vehicles for increased stability margins. |
| author2 |
School of Mechanical and Aerospace Engineering |
| author_facet |
School of Mechanical and Aerospace Engineering Ang, Elijah Hao Wei Leo, Daryl Jieli Tan, Jun Kang Tay, Jonathan Chien Ming Cui, Yongdong Ng, Bing Feng |
| format |
Article |
| author |
Ang, Elijah Hao Wei Leo, Daryl Jieli Tan, Jun Kang Tay, Jonathan Chien Ming Cui, Yongdong Ng, Bing Feng |
| author_sort |
Ang, Elijah Hao Wei |
| title |
Wind tunnel experiments of bending-torsion and body-freedom flutter on flying wing unmanned aerial vehicles |
| title_short |
Wind tunnel experiments of bending-torsion and body-freedom flutter on flying wing unmanned aerial vehicles |
| title_full |
Wind tunnel experiments of bending-torsion and body-freedom flutter on flying wing unmanned aerial vehicles |
| title_fullStr |
Wind tunnel experiments of bending-torsion and body-freedom flutter on flying wing unmanned aerial vehicles |
| title_full_unstemmed |
Wind tunnel experiments of bending-torsion and body-freedom flutter on flying wing unmanned aerial vehicles |
| title_sort |
wind tunnel experiments of bending-torsion and body-freedom flutter on flying wing unmanned aerial vehicles |
| publishDate |
2024 |
| url |
https://hdl.handle.net/10356/173099 |
| _version_ |
1789483145049931776 |