Subsonic Aeroelastic Analysis of a Thin Flat Plate
The interaction between an aircraft structure and the airflow surrounding it has been known to severely affect the stability, performance and manoeuvrability of the aircraft. These interactions form the heart of aero elasticity, a field that comprises all types of aeroelastic phenomena. In this w...
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| 主要作者: | |
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| 格式: | Thesis |
| 語言: | English English |
| 出版: |
2001
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| 主題: | |
| 在線閱讀: | http://psasir.upm.edu.my/id/eprint/7978/1/ITMA_2001_6.pdf |
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| 總結: | The interaction between an aircraft structure and the airflow surrounding it has been
known to severely affect the stability, performance and manoeuvrability of the aircraft.
These interactions form the heart of aero elasticity, a field that comprises all types of
aeroelastic phenomena. In this work, a parametric aeroelastic analysis of a thin flat plate
clamped at the leading edge and exposed to subsonic airflow was conducted. The
aeroelastic effects predicted to occur was flutter, a type of self-excited oscillation.
The analysis was simulated using ZAERO, a panel code aeroelastic program, which
requires free vibration input, obtained using MSC-NASTRAN, a finite element code.
The flutter equation was obtained using Newton's Law of Motion to model the plate
while the airflow was modeled using the Small Disturbance Unsteady Aerodynamic
Theory. Free vibration results and flutter results obtained were validated against
published works found in reference [8, 60 and 61]. The important parameters studied were the aspect ratio and the mass -ratio of the plate.
The effect of the number of free vibration modes employed in the analysis was also
tested. From the results, it was shown that the flutter velocity decreased as the mass
ratio and aspect ratio were increased. The flutter frequency also decreased with higher
mass ratio and at large aspect ratio. The use of a higher number of modes in the flutter
analysis was found to increase the accuracy of the flutter. |
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