Authors: Kevin Anderson, Sukhwinder Singh Sandhu, Nouh Anies, Shilpa Ravichandra, Steven Dobbs, Donald Edberg

Abstract:

This paper presents the results of a Finite Element based vibration analysis of a solar powered Unmanned Aerial Vehicle (UAV). The purpose of this paper was to quantify the free vibration, forced vibration response due to differing point inputs in order to predict the relative response magnitudes and frequencies at various wing locations of vibration induced power generators (magnet in coil) excited by gust and/or control surface pulse-decays used to help power the flight of the electric UAV. A Fluid Structure Interaction (FSI) study was performed in order to ascertain pertinent design stresses and deflections as well as aerodynamic parameters of the UAV airfoil. The 10 ft span airfoil is modeled using Mylar as the primary material. Results show that the free mode in bending is 4.8 Hz while the first forced bending mode is on range of 16.2 to 16.7 Hz depending on the location of excitation. The free torsional bending mode is 28.3 Hz, and the first forced torsional mode is range of 26.4 to 27.8 Hz, depending on the location of excitation. The FSI results predict the coefficients of aerodynamic drag and lift of 0.0052 and 0.077, respectively, which matches hand-calculations used to validate the Finite Element based results. FSI based maximum von Mises stresses and deflections were found to be 0.282 MPa and 3.4 mm, respectively. Dynamic pressures on the airfoil range from 1.04 to 1.23 kPa corresponding to velocity magnitudes in range of 22 to 66 m/s.

Keywords: ANSYS, finite element, FSI, UAV, vibrations.

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1109087

Procedia APA BibTeX Chicago EndNote Harvard JSON MLA RIS XML ISO 690 PDF Downloads 2703

References:

[1] Lee, Bohwa, Poomin Park, Keunbae Kim, and Sejin Kwon. 2014. The Flight Test and Power Simulations of an UAV Powered by Solar Cells, a Fuel Cell and Batteries. Journal of Mechanical Science and Technology. 28, no. 1: 399-405.
[2] 2008. Solar-powered UAV Takes Flight. Reinforced Plastics. 52, no. 9: 5.
[3] Anonymous. 2005. Solar-powered UAV Flies Two Days Straight. Machine Design. 77, no. 16: 26.
[4] Jashnani, S, T.R Nada, M Ishfaq, A Khamker, and P Shaholia. 2013. Sizing and Preliminary Hardware Testing of Solar Powered UAV. The Egyptian Journal of Remote Sensing and Space Science.
[5] 2007. Custom Battery Pack Powers UAV. Power Electronics Technology (Online Exclusive).
[6] Suzuki, Koji, Paulo Kemper Filho, and James Morrison. 2012. Automatic Battery Replacement System for UAVs: Analysis and Design. Journal of Intelligent & Robotic Systems. 65, no. 1: 563-586.
[7] 2010. Fuel Cell/battery Hybrid UAV Takes off in Taiwan. Fuel Cells Bulletin. 2010, no. 6: 4-5.
[8] Chang, Tan, and Hu Yu. 2015. Improving Electric Powered UAVs’ Endurance by Incorporating Battery Dumping Concept. Procedia Engineering. 99: 168-179.
[9] Lindahl, P, E Moog, and S. R Shaw. 2012. Simulation, Design, and Validation of an UAV SOFC Propulsion System. IEEE Transactions on Aerospace and Electronic Systems. 48, no. 3: 2582-2593.
[10] Jang, Jung Soon, and D Liccardo. 2007. Small UAV Automation Using MEMS. IEEE Aerospace and Electronic Systems Magazine. 22, no. 5: 30-34.
[11] Oliver, Joseph A, John B Kosmatka, François M Hemez, and Charles R Farrar. 2007. Finite Element Model Correlation of a Composite UAV Wing Using Modal Frequencies. Proceedings of SPIE. 6532, no. 1.
[12] Haghighat, Sohrab, S Haghighat, Hugh H.T Liu, H.H.T Liu, J.R.R.A Martins, and Joaquim R.R.A Martins. 2008. Modeling and Simulation of Flexible UAVs with Large Aspect Ratio. 2008 Asia Simulation Conference - 7th International Conference on System Simulation and Scientific Computing. 504-509.
[13] Ahmad, Kamran, and Hammad Rahman. 2012. Flutter Analysis of XHALE UAV-A Test Bed for Aeroelastic Results Validation. Applied Mechanics and Materials. 245: 303.
[14] Waisman, H. 2004. Open-loop Flutter Analysis of a Composite UAV Model Using the Active Stiffening Effect. Finite Elements in Analysis and Design. 40, no. 11: 1283-1295.
[15] Grodzki, W, and A Łukaszewicz. 2015. Design and Manufacture of Unmanned Aerial Vehicles (UAV) Wing Structure Using Composite Materials.Materialwissenschaft Und Werkstofftechnik. 46, no. 3: 269- 278
[16] 2009. Best Practice Guidelines for handling Automotive External Aerodynamics with Fluent. Marco Lanfrit. : 3-4