A yaw damper (sometimes referred to as a stability augmentation system[1]) is a system used to reduce (or damp) the undesirable tendencies of an aircraft to oscillate in a repetitive rolling and yawing motion, a phenomenon known as the Dutch roll. A large number of modern aircraft, both jet-powered and propeller-driven, have been furnished with such systems.

The use of a yaw damper provides superior ride quality by automatically preventing uncomfortable yawing and rolling oscillations and reduces pilot workload. On some aircraft, it is mandatory for the yaw damper to be operational at all times during flight above a specified altitude; several airliners were deemed to be unsafe to fly without an active yaw damper.[1]

Design

The yaw damper system consists of a series of accelerometers and sensors that monitor the aircraft rate of yaw; these are electronically interconnected to a flight computer that processes these inputs and automatically controls actuators connected to the rudder.[2] In effect, these actions are akin to movements of the rudder pedals by the pilot, except that these are automated. The rudder motions produced by the yaw damper act to calm the aircraft, assisting the flight crew in maintaining stable flight.[2] The overarching purpose of the yaw damper is to make an aircraft easier to fly by eliminating the necessity for the pilot to actively act against such tendencies.[1] An effective yaw damper may remove the necessity for a pilot to make any contact with the rudder pedals during turns on a range of aircraft, including jet-powered ones.[2][3] Some aircraft, such as the Boeing 727 and Vickers VC10 airliners, are fitted with multiple yaw damper systems due to their operation having been deemed critical to flight safety.[1][4]

Despite what may be implied by its name, the yaw damper does not inhibit or reduce intentional (e.g. commanded by the pilot) yaw, as this would interfere with conventional turns and other common maneuvers that an aircraft would be expected to perform. Rather, the system is intended to counteract incidental and undirected yawing motions, which can be characterised as skids or slips.[1][5] On a single-engine aircraft, the system is particularly useful at addressing the tendency to 'fishtail', smoothing out the left-right movements of the vertical stabilizer, increasing ride comfort.[2] It is also particularly useful on swept wing aircraft, particularly those using a T-tail arrangement; without an active yaw damper system, these types of aircraft are susceptible to the Dutch roll phenomenon, where yawing motions can result in repetitive corkscrew-like oscillations that could potentially escalate to excessive levels if not effectively counteracted.[2]

The yaw damper is typically disengaged at ground level and turned on shortly after takeoff; an active yaw damper during the takeoff run could potentially mask serious issues such as engine failure.[2][1] Equally, the system is commonly disengaged prior to landing, as it could inhibit the available control authority to the pilot at the critical moment of touchdown. On several modern aircraft that are outfitted with a yaw damper, these systems become engaged automatically once the aircraft has surpassed a pre-set altitude (e.g. 200 feet); older aircraft typically have this function manually selected by the flight crew.[2][1] Pilots who are used to flying aircraft with yaw dampers need to be particularly aware when transitioning to aircraft that lack such systems. It has become common for such systems to be interfaced with other elements of an aircraft's avionics, enabling it to work with other functions such as the autopilot.[2][6] Yaw damper functionality can be readily simulated by various software packages, such as Matlab.[7]

See also

References

  1. 1 2 3 4 5 6 7 Schiff, Barry (1 December 2010). "Yaw dampers: The name is a misnomer". aopa.org. Archived from the original on 30 June 2020. Retrieved 29 June 2020.
  2. 1 2 3 4 5 6 7 8 Mark, Rob (6 October 2017). "How It Works: Yaw Damper". Flying. Archived from the original on 30 June 2020. Retrieved 29 June 2020.
  3. Calvin R. Jarvis; Paul C. Loschke; Einar K. Enevoldson (July 1970). "Evaluation of the effect of a yaw-rate damper on the flying qualities of a light twin-engine airplane" (PDF). NASA.
  4. "VC10 Triple Yaw Damper Indicator". rochesteravionicarchives.co.uk. Archived from the original on 29 June 2020. Retrieved 29 June 2020.
  5. Edward F. Gallaghiit; Robert L. Jungklas; William D. Spiegel (19 May 1950). "Investigation of a Yaw Damper for Aircraft" (PDF). Massachusetts Institute of Technology. Archived (PDF) from the original on 19 April 2019. Retrieved 25 January 2022.
  6. "Yaw Damper". centuryflight.com. Archived from the original on 29 June 2020. Retrieved 29 June 2020.
  7. "Yaw Damper Design for a 747® Jet Aircraft". Mathworks. Archived from the original on 1 July 2020. Retrieved 29 June 2020.
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