Vortilon

Vortilons can be seen projecting from underneath the center leading edge of the wings of this Hawker 850XP

Vortilons are fixed aerodynamic devices on aircraft wings used to improve handling at low speeds.[1][2]

The vortilon was invented[3] by aerodynamicists working at Douglas Aircraft who had previously developed the engine pylons for the Douglas DC-8. The original pylons which wrapped around the leading edge of the wing had to be cut back to reduce excessive cruise drag.[4] Wind tunnel testing of the next Douglas commercial aircraft, the Douglas DC-9 which had no under-wing engines, showed a cutback engine pylon would be beneficial to wing lift and upwash at the tail at the low speed stall. The pylon was reduced in size and became the vortilon (VORTex-generating-pYLON).[5]

Vortilons consist of one or more flat plates attached to the underside of the wing near its leading edge, aligned with the flight direction.[6] When the speed is reduced and the aircraft approaches stall, the local flow at the leading edge is diverted outwards; this spanwise component of velocity around the vortilon creates a vortex streamed around the top surface, which energises the boundary layer.[6] A more turbulent boundary layer, in turn, delays the local flow separation.

A view of three vortilons on the wing of a Cozy MKIV aircraft

Vortilons are often used to improve low-speed aileron performance,[1][7] thereby increasing resistance to spin. They can be used as an alternative to wing fences, which also restrict airflow along the span of the wing.[1] Vortilons only stream vortices at high angles of attack[8] and produce less drag at higher speeds than wing fences.[9] Pylons used to mount jet engines under the wing produce a similar effect.[10]

The occurrence of span-wise flow at high angles of attack, such as observed on swept wings, is an essential requirement for vortilons to become effective. According to Burt Rutan, vortilons installed on straight wings would not have any effect.[11]

Vortilons were first introduced with the McDonnell Douglas DC-9 to achieve a strong nose down pitching moment just beyond the normal stall and their influence ceased to have any effect beyond 30 degrees angle of attack.[10][12] They have been used on subsequent aircraft, including:

  1. ^ a b c d "Unicom". Flying: 75. July 2002. Retrieved 2011-10-07.
  2. ^ Houghton, Edward Lewis; Carpenter, Peter William (2003). Aerodynamics for engineering students (5th ed.). Oxford: Butterworth-Heinemann. pp. 514. ISBN 0750651113. OCLC 50441321.
  3. ^ "Stall control device for swept wings".
  4. ^ https://www.scribd.com/document/50976964/Applied-aerodynamics-at-the-Douglas-Aircraft-Company, Fig.23
  5. ^ https://arc.aiaa.org/doi/abs/10.2514/3.43770, p.Fig 13
  6. ^ a b Raymer, Daniel P. (1999). "8.2 Aerodynamic Considerations in Configuration Layout". Aircraft Design: A Conceptual Approach (3rd ed.). Reston, Virginia: American Institute of Aeronautics and Astronautics. p. 183. ISBN 1-56347-281-3.
  7. ^ a b McClellan, J. Mac (November 2002). "Hawker 800XP". Flying: 75. Retrieved 2011-10-07.
  8. ^ Barnard, R.H.; Philpott, D.R. (2010). "Boundary layer and stalling problems on swept wings". Aircraft Flight (4th ed.). Harlow, England: Prentice Hall. p. 75. ISBN 978-0-273-73098-9.
  9. ^ a b McClellan, J. Mac (February 1993). "BAE 1000 Lifts Hawker Name to New Heights". Flying: 88. Retrieved 2011-10-07.
  10. ^ a b "The DC-9 and the Deep Stall". Flight International: 442. 25 March 1965. Retrieved 2011-10-07.
  11. ^ Vortilons for Variezes, The canard pusher, n°42, October 1984
  12. ^ Shevell, Richard S.; Schaufele, Roger D. (November–December 1966). "Aerodynamic Design Features of the DC-9". Journal of Aircraft. 3 (6): 515–523. doi:10.2514/3.43770.
  13. ^ a b Smith, Steve. "Resources for learning about vortilons". NASA Quest. Archived from the original on 2010-11-11. Retrieved 2011-10-07.
  14. ^ https://archive.org/details/DTIC_ADA247719 8-4
  15. ^ https://www.nasa.gov/centers/dryden/pdf/88410main_H-1957V1.pdf,p.87 [dead link]