Nacelle Explained

A nacelle is a streamlined container for aircraft parts such as engines, fuel or equipment.[1] When attached entirely outside the airframe, it is sometimes called a pod, in which case it is attached with a pylon or strut and the engine is known as a podded engine.[2] In some cases—for instance in the typical "Farman" type "pusher" aircraft, or the World War II-era P-38 Lightning—an aircraft cockpit may also be housed in a nacelle, rather than in a conventional fuselage.

Etymology

Like many aviation terms, the word comes from French, in this case from a word for a small boat.[3]

Development

thumb|The development of the Arado Ar 234, merging the four nacelles into two

The Arado Ar 234 was one of the first operational jet aircraft with engines mounted in nacelles. During its development, the four engines had four distinct nacelles. They once had their own landing gear wheel, but they were later combined to two nacelles with two engines each.

Around 2010, General Electric and NASA have developed nacelles with chevron-shaped trailing edges to reduce the engine noise of commercial aircraft, using an experimental Boeing 777 as a test platform.[4]

Applications

Usually, multi-engined aircraft use nacelles for housing the engines.[5] Combat aircraft (such as the Eurofighter Typhoon) usually have the engines mounted within the fuselage. Some engines are installed in the aircraft wing, as in the De Havilland Comet and Flying Wing type aircraft. Engines may be mounted in individual nacelles, or in the case of larger aircraft such as the Boeing B-52 Stratofortress (pictured right) may have two engines mounted in a single nacelle. Nacelles can be made fully or partially detachable for holding expendable resources such as fuel and armaments. Nacelles may be used to house equipment that will only function remote from the fuselage, for example the Boeing E-3 Sentry radar is housed in a nacelle called a radome.

Other uses

Design considerations

The primary design issue with aircraft-mounted nacelles is streamlining to minimise drag so nacelles are mounted on slender pylons. This can cause issues with directing the needed conduits mounted within the nacelle to connect to the aircraft through such a narrow space. This is especially concerning with nacelles containing engines, as the fuel, and control, lines for multiple engine functions must all go through the pylons. It is often necessary for nacelles to be asymmetrical, but aircraft designers try to keep asymmetrical elements to a minimum to reduce operator maintenance costs associated with having two sets of parts for either side of the aircraft.

Notes and References

  1. The Cambridge Aerospace Dictionary, Bill Gunston,
  2. Book: Wragg, David W. . A Dictionary of Aviation . 9780850451634 . first . Osprey . 1973 . 199.
  3. Web site: Online Etymology Dictionary. 5 December 2013.
  4. Web site: NASA Helps Create a More Silent Night . . December 13, 2010 . September 21, 2019 . January 18, 2017 . https://web.archive.org/web/20170118110405/https://www.nasa.gov/topics/aeronautics/features/bridges_chevron_events_prt.htm . dead .
  5. Web site: Nacelle Design and Sizing . Ilan Kroo, Professor of Aeronautics and Astronautics . https://web.archive.org/web/20010307121417/http://adg.stanford.edu/aa241/propulsion/nacelledesign.html . dead . March 7, 2001 . Aircraft Aerodynamics and Design Group at Stanford University . April 13, 1999 . April 22, 2011.
  6. p 107, Davies, Ivor It's A Triumph (Haynes Foulis 1980, 1990 edit.)
  7. https://www.facebook.com/AmericanWindEnergyAssociation/videos/10152872502493775/ American Wind Energy Association (AWEA) video on construction of an individual wind turbine.