Flap (aeronautics)

The position of the trailing edge flaps on a typical airliner. In this picture, the flaps are extended, note also the drooped leading edge slats.

Flaps are devices used to alter the lift characteristics of a wing and are mounted on the trailing edges of the wings of a fixed-wing aircraft to reduce the speed at which the aircraft can be safely flown and to increase the angle of descent for landing. They do this by lowering the stall speed and increasing the drag. Flaps shorten takeoff and landing distances.

Extending flaps increases the camber or curvature of the wing, raising the maximum lift coefficient — the lift a wing can generate. This allows the aircraft to generate as much lift, but at a lower speed, reducing the stalling speed of the aircraft, or the minimum speed at which the aircraft will maintain flight. Extending flaps increases drag, which can be beneficial during approach and landing, because it slows the aircraft. On some aircraft, a useful side effect of flap deployment is a decrease in aircraft pitch angle which lowers the nose thereby improving the pilot's view of the runway over the nose of the aircraft during landing. However the flaps may also cause pitch-up depending on the type of flap and the location of the wing.

There are many different types of flaps used, with the specific choice depending on the size, speed and complexity of the aircraft on which they are to be used, as well as the era in which the aircraft was designed. Plain flaps, slotted flaps, and Fowler flaps are the most common. Krueger flaps are positioned on the leading edge of the wings and are used on many jet airliners.

The Fowler, Fairey-Youngman and Gouge types of flap increase the wing area in addition to changing the camber. The larger lifting surface reduces wing loading and allows the aircraft to generate the required lift at a lower speed and reduces stalling speed.

Physics explanation

The general airplane lift equation demonstrates these relationships:[1]

L = \tfrac12 \rho V^2 S C_L

where:

Here, it can be seen that increasing the area (S) and lift coefficient (C_L) allow a similar amount of lift to be generated at a lower airspeed (V).

The three orange pods are flap track fairings streamlining the flap mechanisms. The flaps (two on each side, on the Airbus A319) lie directly above these.

Extending the flaps also increases the drag coefficient of the aircraft. Therefore, for any given weight and airspeed, flaps increase the drag force. Flaps increase the drag coefficient of an aircraft due to higher induced drag caused by the distorted spanwise lift distribution on the wing with flaps extended. Some flaps increase the wing area and, for any given speed, this also increases the parasitic drag component of total drag.[1]

Flaps during takeoff

Depending on the aircraft type, flaps may be partially extended for takeoff.[1] When used during takeoff, flaps trade runway distance for climb rate—using flaps reduces ground roll and the climb rate. The amount of flap used on takeoff is specific to each type of aircraft, and the manufacturer will suggest limits and may indicate the reduction in climb rate to be expected. The Cessna 172S Pilot Operating Handbook generally recommends 10° of flaps on takeoff, especially when the ground is rough or soft.[2]

Flaps during landing

North American T-6 trainer showing its split flaps

Flaps may be fully extended for landing to give the aircraft a lower stall speed so the approach to landing can be flown more slowly, which also allows the aircraft to land in a shorter distance. The higher lift and drag associated with fully extended flaps allows a steeper and slower approach to the landing site, but imposes handling difficulties in aircraft with very low wing loading (the ratio between the wing area and the weight of the aircraft). Winds across the line of flight, known as crosswinds, cause the windward side of the aircraft to generate more lift and drag, causing the aircraft to roll, yaw and pitch off its intended flight path, and as a result many light aircraft land with reduced flap settings in crosswinds. Furthermore, once the aircraft is on the ground, the flaps may decrease the effectiveness of the brakes since the wing is still generating lift and preventing the entire weight of the aircraft from resting on the tires, thus increasing stopping distance, particularly in wet or icy conditions. Usually, the pilot will raise the flaps as soon as possible to prevent this from occurring.[2]

Maneuvering flaps

Some gliders not only use flaps when landing, but also in flight to optimize the camber of the wing for the chosen speed. When thermalling, flaps may be partially extended to reduce the stalling speed so that the glider can be flown more slowly and thereby reduce the rate of sink, which lets the glider use the rising air of the thermal more efficiently, and to turn in a smaller circle to make best use of the core of the thermal. At higher speeds a negative flap setting is used to reduce the nose-down pitching moment. This reduces the balancing load required on the horizontal stabilizer, which in turn reduces the trim drag associated with keeping the glider in longitudinal trim. Negative flap may also be used during the initial stage of an aerotow launch and at the end of the landing run in order to maintain better control by the ailerons.

Like gliders, some fighters such as the Nakajima Ki-43 also use special flaps to improve maneuverability during air combat, allowing the fighter to create more lift at a given speed, allowing for much tighter turns.[3] The flaps used for this must be designed specifically to handle the greater stresses and most flaps have a maximum speed at which they can be deployed. Control line model aircraft built for precision aerobatics competition usually have a type of maneuvering flap system that moves them in an opposing direction to the elevators, to assist in tightening the radius of a maneuver.

Flap track fairings

Fairings streamline the airflow over the flap support mechanisms to help reduce cruise drag - the smaller the fairing the lower the drag.[4]

Thrust gates

Thrust gates, or gaps, in the trailing edge flaps may be required to minimise interference between the engine flow and deployed flaps. In the absence of an in-board aileron, which provides a gap in many flap installations, a modified flap section may be needed. The thrust gate on the Boeing 757 was provided by a single-slotted flap in between the inboard and outboard double-slotted flaps.[5] The A320,A330,A340 and A380 have no in-board aileron. No thrust gate is required in the continuous, single-slotted flap. Interference in the go-around case while the flaps are still fully deployed can cause increased drag which must not compromise the climb gradient.[6]


Types

Plain flap at nearly full deflection on an Akaflieg München Mu 30 Schlacro aerobatic aircraft
Flaps and high lift devices. Gurney flap exaggerated for clarity. Blown flap skipped as it is modified from any other type. Pale lines indicate line of movement, and green indicates flap setting used during dive.

See also

Wikimedia Commons has media related to Trailing-edge flaps.

References

  1. 1 2 3 Perkins, Courtland; Hage, Robert (1949). Airplane performance, stability and control, Chapter 2, John Wiley and Sons. ISBN 0-471-68046-X.
  2. 1 2 Cessna Aircraft Company. Cessna Model 172S Nav III. Revision 3 - 12, 2006, p. 4-19 to 4-47.
  3. Windrow, 1965, p.4
  4. http://ntrs.nasa.gov/archive/nasa/casi.ntrs.nasa.gov/19960052267.pdf p.39
  5. http://ntrs.nasa.gov/archive/nasa/casi.ntrs.nasa.gov/19960052267.pdf p.40,54
  6. http://citeseerx.ist.psu.edu/viewdoc/download?doi=10.1.1.602.7484&rep=rep1&type=pdf p.7
  7. Gunston, Bill, The Cambridge Aerospace Dictionary Cambridge, Cambridge University Press 2004, ISBN 978-0-521-84140-5/ISBN 0-521-84140-2 p.452
  8. 1 2 3 Taylor, 1974, pp.8-9
  9. Toelle, Alan (2003). Windsock Datafile Special, Breguet 14. Hertfordshire, Great Britain: Albatros Productions. ISBN 1-902207-61-0.
  10. Gunston, Bill, The Cambridge Aerospace Dictionary Cambridge, Cambridge University Press 2004, ISBN 978-0-521-84140-5/ISBN 0-521-84140-2 p.584
  11. Gunston, Bill, The Cambridge Aerospace Dictionary Cambridge, Cambridge University Press 2004, ISBN 978-0-521-84140-5/ISBN 0-521-84140-2 p.569
  12. Smith, Apollo M. O. (1975). "High-Lift Aerodynamics" (PDF). Journal of Aircraft 12 (6): 518–523. doi:10.2514/3.59830. ISSN 0021-8669. Retrieved 12 July 2011.
  13. Gunston, Bill, The Cambridge Aerospace Dictionary, Cambridge, Cambridge University Press 2004, ISBN 978-0-521-84140-5/ISBN 0-521-84140-2 p.249-250
  14. Flight 1942
  15. National Aeronautics and Space Administration. Wind and Beyond: A Documentary Journey Into the History of Aerodynamics.
  16. Gunston, Bill, The Cambridge Aerospace Dictionary, Cambridge, Cambridge University Press 2004, ISBN 978-0-521-84140-5/ISBN 0-521-84140-2 p.331
  17. Gunston, Bill, The Cambridge Aerospace Dictionary, Cambridge, Cambridge University Press 2004, ISBN 978-0-521-84140-5/ISBN 0-521-84140-2 p.270
  18. C.M. Poulsen, ed. (27 July 1933). ""The Aircraft Engineer - flight engineering section" Supplement to Flight". Flight Magazine. pp. 754a–d.
  19. NASA on High-Lift Systems
  20. Virginia Tech – Aerospace & Ocean Engineering
  21. Gunston, Bill, The Cambridge Aerospace Dictionary Cambridge, Cambridge University Press 2004, ISBN 978-0-521-84140-5/ISBN 0-521-84140-2 p.335
  22. from German wiki page on Krüger flaps @ http://wikipedia.qwika.com/de2en/Kr%C3%BCgerklappe (accessed 18 October 2011)
  23. Gunston, Bill, The Cambridge Aerospace Dictionary Cambridge, Cambridge University Press 2004, ISBN 978-0-521-84140-5/ISBN 0-521-84140-2 p.191
  24. http://naca.central.cranfield.ac.uk/reports/arc/cp/0209.pdf page 1 accessdate=11 Jan 2016
  25. American Military Training Aircraft' E.R. Johnson and Lloyd S. Jones, McFarland & Co. Inc. Publishers, Jefferson, North Carolina
  26. "Shape-shifting flap takes flight". Retrieved 19 November 2014.

Further reading

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