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Performance of Isolated UAV Rotors at Low Reynolds Number

Journal Article
2020-01-0046
ISSN: 2641-9637, e-ISSN: 2641-9645
Published March 10, 2020 by SAE International in United States
Performance of Isolated UAV Rotors at Low Reynolds Number
Sector:
Event: AeroTech
Citation: Tomar, Y., Shukla, D., and Komerath, N., "Performance of Isolated UAV Rotors at Low Reynolds Number," SAE Int. J. Adv. & Curr. Prac. in Mobility 2(3):1259-1265, 2020, https://doi.org/10.4271/2020-01-0046.
Language: English

References

  1. Alakai Technologies Corporation https://skai.co/ 2019
  2. Volocopter https://www.volocopter.com/en/ 2019
  3. EHang http://www.ehang.com/ehang184/index 2019
  4. González-Jorge , H. , Martínez-Sánchez , J. , and Bueno , M. Unmanned Aerial Systems for Civil Applications: A Review Drones 1 1 2 2017
  5. Bohorquez , F. 2007
  6. Hein , B.R. and Chopra , I. Hover Performance of a Micro Air Vehicle: Rotors at Low Reynolds Number Journal of the American Helicopter Society 52 3 254 262 2007
  7. Kunz , P. and Stawn , R. Analysis and Design of Rotors at Ultra-Low Reynolds Numbers 40th AIAA Aerospace Sciences Meeting & Exhibit 2003 99
  8. Rubio , O. , Gutiérrez , F. , Zuñiga , J.C. , and Funes-Gallanzi , M. Low-Re μUAV Rotor Design Fluid Dynamics in Physics, Engineering and Environmental Applications Berlin Springer 2013 489 500
  9. Lakshminarayan , V.K. and Baeder , J.D. Computational Investigation of Micro Hovering Rotor Aerodynamics Journal of the American Helicopter Society 55 2 22001 22001 2010
  10. Schroeder , E. and Baeder , J. Using Computational Fluid Dynamics for Micro-Air Vehicle Airfoil Validation and Prediction 23rd AIAA Applied Aerodynamics Conference 2005 4841
  11. Griffiths , D.A. A Study of Dual-Rotor Interference and Ground Effect Using a Free-Vortex Wake Model American Helicopter Society 58th Annual Forum Montreal, Canada June 11-13 2002
  12. Lee , J. , Yee , K. , and Sejong , O. Aerodynamic Characteristic Analysis of Multi-Rotors Using a Modified Free-Wake Method Transactions of the Japan Society for Aeronautical and Space Sciences 52 177 168 179 2009
  13. Gupta , V. and Baeder , J.D. Quad Tilt Rotor Aerodynamics in Helicopter Mode Annual Forum Proceedings-American Helicopter Society 61 1 416 2005
  14. Yoon , S. , Lee , H.C. , and Pulliam , T.H. Computational Analysis of Multi-Rotor Flows 54th AIAA Aerospace Sciences Meeting 2016 0812
  15. Rajagopalan , R.G. , Baskaran , V. , Hollingsworth , A. , Lestari , A. et al. RotCFD - A Tool for Aerodynamic Interference of Rotors: Validation and Capabilities Future Vertical Lift Aircraft Design Conference San Francisco, CA 2012
  16. Radhakrishnan , A. and Schmitz , F. An Experimental Investigation of a Quad Tilt Rotor in Low Speed Forward Flight Proceedings of the 4th Decennial Specialists’ Conference on Aeromechanics San Francisco, CA 2004
  17. Ramasamy , M. Measurements Comparing Hover Performance of Single, Coaxial, Tandem, and Tilt-Rotor Configurations 69th AHS Annual Forum 2013 31 21 23
  18. Shukla , D. and Komerath , N. Multirotor Drone Aerodynamic Interaction Investigation Drones 2 4 43 2018
  19. Shukla , D. and Komerath , N. Low Reynolds Number Multirotor Aerodynamic Wake Interactions Experiments in Fluids 60 4 77 2019
  20. Shukla , D. and Komerath , N. An Experimental Investigation of Rotor-Box Aerodynamic Interaction Journal of Fluids Engineering 141 12 121103 2019

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