Version 1
: Received: 8 September 2020 / Approved: 11 September 2020 / Online: 11 September 2020 (09:37:22 CEST)
How to cite:
ghalandari, M.; mahariq, I.; Al barakeh, Z. Optimization of the High Aspect Ratio Wing with Position and Distribution of Aileron Mass on the Speed and Frequency. Preprints2020, 2020090253
ghalandari, M.; mahariq, I.; Al barakeh, Z. Optimization of the High Aspect Ratio Wing with Position and Distribution of Aileron Mass on the Speed and Frequency. Preprints 2020, 2020090253
ghalandari, M.; mahariq, I.; Al barakeh, Z. Optimization of the High Aspect Ratio Wing with Position and Distribution of Aileron Mass on the Speed and Frequency. Preprints2020, 2020090253
APA Style
ghalandari, M., mahariq, I., & Al barakeh, Z. (2020). Optimization of the High Aspect Ratio Wing with Position and Distribution of Aileron Mass on the Speed and Frequency. Preprints. https://doi.org/
Chicago/Turabian Style
ghalandari, M., Ibrahim mahariq and Zaher Al barakeh. 2020 "Optimization of the High Aspect Ratio Wing with Position and Distribution of Aileron Mass on the Speed and Frequency" Preprints. https://doi.org/
Abstract
As the aileron mass parameter and its position on the velocity and frequency of the flutter is an important problem in design of the aircraft wings, the optimization of the composite wing with an aileron is represented in this paper. Mass properties and its distribution have a great influence on the multi-disciplinary optimization procedure based on speed and frequency of flutter. At first, flutter speed was obtained with and without aileron, then aileron was mass-equilibrated and other studies were performed using the proposed method. It is deduced that changing the position and mass properties of the aileron the speed and frequency of the flutter changed. The position of the aileron was determined for better wing performance in flutter instability and minimizing the composite stress. In the present study, it has been attempted to model the aerodynamics of the problem under ultrasound with the panel method, and the structure has been modeled using finite element method and coupled with the aerodynamics. Using the p-k method, the equations are solved and the results are extracted.
Copyright:
This is an open access article distributed under the Creative Commons Attribution License which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.