Wide body jet

A narrow-body Boeing 737 of Lufthansa in front of a wide-body Boeing 777 of Emirates

A wide-body aircraft, also known as a twin-aisle aircraft and in the largest cases as a jumbo jet, is an airliner with a fuselage wide enough to accommodate two passenger aisles with seven or more seats abreast.[1] The typical fuselage diameter is 5 to 6 m (16 to 20 ft).[2] In the typical wide-body economy cabin, passengers are seated seven to ten abreast,[3] allowing a total capacity of 200 to 850[4] passengers. Seven-abreast aircraft typically seat 160 to 260 passengers, eight-abreast 250 to 380, nine- and ten-abreast 350 to 480.[5] The largest wide-body aircraft are over 6 m (20 ft) wide, and can accommodate up to eleven passengers abreast in high-density configurations.

By comparison, a typical Narrow-body aircraft has a diameter of 3 to 4 m (10 to 13 ft), with a single aisle,[1][6] and seats between two and six people abreast.[7]

Wide-body aircraft were originally designed for a combination of efficiency and passenger comfort and to increase the amount of cargo space.[8] However, airlines quickly gave in to economic factors, and reduced the extra passenger space in order to insert more seats and increase revenue and profits.[citation needed] Wide-body aircraft are also used by commercial cargo airlines,[9] along with other specialized uses.

By the end of 2017, nearly 8,800 wide-body airplanes had been delivered since 1969, production peaking at 412 per year in 2015.[10]

History

A Boeing 747, the first wide-body passenger aircraft, operated by Pan Am
Three widebodies: KLM's Airbus A330 twinjet, McDonnell Douglas MD-11 trijet and Boeing 747-400 quadjet

Following the success of the Boeing 707 and Douglas DC-8 in the late 1950s and early 1960s, airlines began seeking larger aircraft to meet the rising global demand for air travel. Engineers were faced with many challenges as airlines demanded more passenger seats per aircraft, longer ranges and lower operating costs.

Early jet aircraft such as the 707 and DC-8 seated passengers along either side of a single aisle, with no more than six seats per row. Larger aircraft would have to be longer, higher (double-deck aircraft), or wider in order to accommodate a greater number of passenger seats.

Engineers realized having two decks created difficulties in meeting emergency evacuation regulations with the technology available at that time. During the 1960s, it was also believed that supersonic airliners would succeed larger, slower planes. Thus, it was believed that most subsonic aircraft would become obsolete for passenger travel and would be eventually converted to freighters. As a result, airline manufacturers opted for a wider fuselage rather than a taller one (the 747, and eventually the McDonnell Douglas DC-10 and Lockheed L-1011 TriStar). By adding a second aisle, the wider aircraft could accommodate as many as 10 seats across, but could also be easily converted to a freighter and carry two eight-by-eight freight pallets abreast.[11]

The engineers also opted for creating "stretched" versions of the DC-8 (61, 62 and 63 models), as well as longer versions of Boeing's 707 (-320B and 320C models) and 727 (-200 model); and Douglas' DC-9 (-30, -40, and -50 models), all of which were capable of accommodating more seats than their shorter predecessor versions.

The wide-body age began in 1970 with the entry into service of the first wide-body airliner, the four-engined, partial double-deck Boeing 747.[12] New trijet wide-body aircraft soon followed, including the McDonnell Douglas DC-10 and the L-1011 TriStar. The first wide-body twinjet, the Airbus A300, entered service in 1974. This period came to be known as the "wide-body wars".[13]

L-1011 TriStars were demonstrated in the USSR in 1974, as Lockheed sought to sell the aircraft to Aeroflot.[14][15] However, in 1976 the Soviet Union launched its own first four-engined wide-body, the Ilyushin Il-86.[16]

After the success of the early wide-body aircraft, several subsequent designs came to market over the next two decades, including the Boeing 767 and 777, the Airbus A330 and Airbus A340, and the McDonnell Douglas MD-11. In the "jumbo" category, the capacity of the Boeing 747 was not surpassed until October 2007, when the Airbus A380 entered commercial service with the nickname "Superjumbo".[17] Both the Boeing 747 and Airbus A380 "jumbo jets" have four engines each (quad-jets), but the upcoming Boeing 777X ("mini jumbo jet") is a twinjet.[18][19]

In the mid-2000s, rising oil costs in a post-9/11 climate caused airlines to look towards newer, more fuel-efficient aircraft. Two such examples are the Boeing 787 Dreamliner and Airbus A350 XWB. The proposed Comac C929 and C939 may also share this new wide-body market.[citation needed]

A cross-section comparison of Airbus A380 (double-deck the full length) and Boeing 747-400 (double-deck only in the front section)

The production of the large Boeing 747-8 and Airbus A380 four-engine, long-haul jets has come to an end as airlines are now preferring the smaller, more efficient Airbus A350, Boeing 787 and Boeing 777 twin-engine, long-range airliners.[20]

Design

Fuselage

An Airbus A300's cross-section, showing cargo, passenger, and overhead areas

Although wide-body aircraft have larger frontal areas (and thus greater form drag) than narrow-body aircraft of similar capacity, they have several advantages over their narrow-body counterparts, such as:

  • Larger cabin space for passengers, giving a more open feeling.
  • Lower ratio of surface area to volume, and thus lower drag per passenger or cargo volume. The only exception to this would be with very long narrow-body aircraft, such as the Boeing 757 and Airbus A321.
  • Twin aisles that accelerate loading, unloading, and evacuation compared to a single aisle (wide-body airliners typically have 3.5 to 5 seats abreast per aisle, compared to 5–6 on most narrow-body aircraft).[21]
  • Reduced overall aircraft length for a given capacity, improving ground manoeuvrability and reducing the risk of tail strikes.
  • Greater under-floor freight capacity.
  • Better structural efficiency for larger aircraft than would be possible with a narrow-body design.

British and Russian designers had proposed wide-body aircraft similar in configuration to the Vickers VC10 and Douglas DC-9, but with a wide-body fuselage. The British BAC Three-Eleven project did not proceed due to lack of government backing, while the Russian Ilyushin Il-86 wide-body proposal eventually gave way to a more conventional wing-mounted engine design, most likely due to the inefficiencies of mounting such large engines on the aft fuselage.

Engines

The General Electric GE90 is the most powerful turbofan engine.

As jet engine power and reliability have increased over the last decades, most of the wide-body aircraft built today have only two engines. A twinjet design is more fuel-efficient than a trijet or quadjet of similar size.[citation needed] The increased reliability of modern jet engines also allows aircraft to meet the ETOPS certification standard, which calculates reasonable safety margins for flights across oceans. The trijet design was dismissed due to higher maintenance and fuel costs compared to a twinjet.[citation needed] Most modern wide-body aircraft have two engines, although the heaviest wide-body aircraft, the Airbus A380 and the Boeing 747-8, are built with four engines. The upcoming Boeing 777X-9 twinjet is approaching the capacity of the earlier Boeing 747.[18][19]

The Boeing 777 twinjet features the most powerful jet engine, the General Electric GE90.[22] The early variants have a fan diameter of 312 centimetres (123 in), and the larger GE90-115B has a fan diameter of 325 centimetres (128 in).[23] This is almost as wide as the 3.30 metres (130 in) Fokker 100 fuselage. Complete GE90 engines can only be ferried by outsize cargo aircraft such as the Antonov An-124, presenting logistics problems if a 777 is stranded in a place due to emergency diversions without the proper spare parts. If the fan is removed from the core, then the engines may be shipped on a Boeing 747 Freighter.[24] The General Electric GE9X, powering the Boeing 777X, is wider than the GE90 by 15 centimetres (6 in).

The 560 tonnes (1,230,000 lb) maximum takeoff weight of the Airbus A380 would not have been possible without the engine technology developed for the Boeing 777 such as contra-rotating spools.[25] Its Trent 900 engine has a fan diameter of 290 centimetres (116 in), slightly smaller than the GE90 engines on the Boeing 777. The Trent 900 is designed to fit into a Boeing 747-400F freighter for easier transport by air cargo.[26]

Interior

The interiors of aircraft, known as the aircraft cabin, have been undergoing evolution since the first passenger aircraft. Today, between one and four classes of travel are available on wide-body aircraft.

Bar and lounge areas which were once installed on wide-body aircraft have mostly disappeared, but a few have returned in first class or business class on the Airbus A340-600,[27] Boeing 777-300ER,[28] and on the Airbus A380.[29] Emirates has installed showers for first-class passengers on the A380; twenty-five minutes are allotted for use of the room, and the shower operates for a maximum of five minutes.[30][31]

Depending on how the airline configures the aircraft, the size and seat pitch of the airline seats will vary significantly.[32] For example, aircraft scheduled for shorter flights are often configured at a higher seat density than long-haul aircraft. Due to current economic pressures on the airline industry, high seating densities in the economy class cabin are likely to continue.[33]

In some of the largest single-deck wide-body aircraft, such as the Boeing 777, the extra space above the cabin is used for crew rest areas and galley storage.

Jumbo jets

The term "jumbo jet" usually refers to the largest variants of wide-body airliners; examples include the Boeing 747 (the first wide-body and original "jumbo jet"), Airbus A380 ("superjumbo jet"), Boeing 777X and Boeing 777 ("mini jumbo jet").[18][19] The phrase "jumbo jet" derives from Jumbo, a circus elephant in the 19th century.[34][35]

Wake turbulence and separation

A NASA study on wingtip vortices, which illustrates wake turbulence

Aircraft are categorized by ICAO according to the wake turbulence they produce. Because wake turbulence is generally related to the weight of an aircraft, these categories are based on one of four weight categories:[36] light, medium, heavy, and super.[37]

Due to their weight, all current wide-body aircraft are categorized as "heavy", or in the case of the A380 in U.S. airspace, "super".

The wake-turbulence category also is used to guide the separation of aircraft.[38] Super- and heavy-category aircraft require greater separation behind them than those in other categories. In some countries, such as the United States, it is a requirement to suffix the aircraft's call sign with the word heavy (or super) when communicating with air traffic control in certain areas.

Special uses

A U.S. Space Shuttle mounted on a modified Boeing 747

Wide-body aircraft are used in science, research, and the military. Some wide-body aircraft are used as flying command posts by the military like the Ilyushin Il-80[citation needed] or the Boeing E-4, while the Boeing E-767 is used for airborne early warning and control. New military weapons are tested aboard wide-bodies, as in the laser weapons testing on the Boeing YAL-1. Other wide-body aircraft are used as flying research stations, such as the joint German–U.S. Stratospheric Observatory for Infrared Astronomy (SOFIA). Airbus A340,[39] Airbus A380,[40] and Boeing 747[41] four-engine wide-body aircraft are used to test new generations of aircraft engines in flight. A few aircraft have also been converted for aerial firefighting, such as the DC-10-based[42] Tanker 910 and the 747-200-based Evergreen Supertanker.[43]

Some wide-body aircraft are used as VIP transport. To transport those holding the highest offices, Canada uses the Airbus A310, while Russia uses the Ilyushin Il-96. Germany replaced its Airbus A310 with an Airbus A340 in spring 2011. Specially-modified Boeing 747-200s (Boeing VC-25s) are used to transport the President of the United States.

Outsize cargo

Some wide-body aircraft have been modified to enable transport of oversize cargo. Examples include the Airbus Beluga, Airbus BelugaXL and Boeing Dreamlifter. Two specially modified Boeing 747s were used to transport the U.S. Space Shuttle, while the Antonov An-225 was initially built to carry the Buran shuttle.

Comparison

Model produced MTOW
(tonnes)
Length Fuselage width Cabin width Economy seats across Seat
width[a]
Number built
767[44] 1981–present 186.9 48.51–61.37 m
(159 ft 2 in – 201 ft 4 in)
5.03 metres
(16 ft 6 in)
4.72 metres
(15 ft 6 in)
7: 2-3-2 (HD, 8: 2-4-2) 18" (16.4") 1263 (October 2022)
A300[45] 1974–2007 171.7 53.61–54.08 m
(175 ft 11 in – 177 ft 5 in)
5.64 m (18 ft 6 in) 5.28 m (17 ft 4 in) 8: 2-4-2 (HD, 9: 3-3-3) 17.2" (16.4") 561 (discontinued)
A310[46] 1983–1998 164 46.66 m
(153 ft 1 in)
8: 2-4-2 17.2" 255 (discontinued)
A330[47] 1994–present 242 58.82–63.67 m
(193 ft 0 in – 208 ft 11 in)
8: 2-4-2 (9: 3-3-3 on 5J and D7[48] and JT) 18" (16.5") 1555 (November 2022)
A340[49] 1993–2011 380 59.40–75.36 m
(194 ft 11 in – 247 ft 3 in)
8: 2-4-2 (9: 3-3-3) 17.8" (16.4") 380 (discontinued)
787[50] 2007–present 252.7 56.72–68.28 m
(186 ft 1 in – 224 ft 0 in)
5.76 m (18 ft 11 in) 5.49 m (18 ft 0 in) 9: 3-3-3 (8: 2-4-2 on JL[51]) 17.2" 1021 (October 2022)
C929[52] 2025- (projected) 245[53] 63.755 m (209 ft 2.0 in)[53] 5.92 m (19 ft 5 in) 5.61 m (18 ft 5 in) 9: 3-3-3 17.9" -
A350[54] 2010–present 316 66.61–73.59 m (218.5–241.4 ft) 5.96 m (235 in) 5.61 m (221 in) 9: 3-3-3 (10: 3-4-3 on BF and TX[55]) 18" (16.5”) 509 (November 2022)
DC-10[56] 1971–1989 259.5 51.97 m (170.5 ft) 6.02 m (237 in) 5.69 m (224 in) 9: 2-4-3, 10: 3-4-3 18", 16.5" 446 (discontinued)
MD-11[57] 1990–2001 286 58.65 m (192.4 ft) 9: 2-5-2, 10: 3-4-3 18", 16.5" 200 (discontinued)
L-1011[58] 1972–1985 231.3 54.17–50.05 m (177.7–164.2 ft) 6.02 m (237 in) 5.77 m (227 in) 9: 3-4-2/2-5-2, 10: 3-4-3 17.7", 16.5" 250 (discontinued)
Il-86 1980–1994 206 60.21 m (197.5 ft) 6.08 m (239 in) 5.70 m (224 in) 9: 3-3-3[59] 18" 106 (discontinued)
Il-96 1992-present 270 55.3–63.94 m (181.4–209.8 ft) 30 (2016)
777[60] 1993–present 247.2-351.5 63.7–73.9 m (209–242 ft) 6.19 m (244 in) 5.86 m (231 in) 9: 3-3-3, 10: 3-4-3 18.5", 17" 1696 (October 2022)
777X[61] 2019–present 351.5 70.87–76.73 m (232.5–251.7 ft) 5.94 m (234 in) 10: 3-4-3 17.2" 4 (January 2021)
747[62] 1968–2022 447.7 56.3–76.25 m (184.7–250.2 ft) 6.50 m (256 in) 6.10 m (240 in)
up: 3.46 m (136 in)
10: 3-4-3 (main)
6: 3-3 (upper)
17.2"/18.5" 1574 (discontinued)
A380[63] 2005–2021 575 72.72 m (238.6 ft) 7.14 m (281 in) 6.54 m (257 in)
up: 5.80 m (228 in)
10: 3-4-3 (HD) (main)
8: 2-4-2 (upper)
18" (18") 246 (discontinued)
  1. ^ with 2" armrests when not otherwise specified

See also

References

  1. ^ a b Ginger Gorham; Ginger Todd; Susan Rice (2003). A Guide to Becoming a Travel Professional. Cengage Learning. p. 40. ISBN 9781401851774.
  2. ^ Paul J. C. Friedlander (1972-03-19). "the traveler's world; Test of a New Wide-Bodied Airbus". New York Times.
  3. ^ Doganis, Rigas (2002). Flying Off Course: The Economics of International Airlines. Routledge. p. 170. ISBN 9780415213240.
  4. ^ "Dimensions & key data | Airbus, a leading aircraft manufacturer". Airbus.com. 2012-09-27. Archived from the original on 2012-07-08. Retrieved 2012-10-01.
  5. ^ Ajoy Kumar Kundu (12 April 2010). Aircraft Design. Cambridge University Press. ISBN 978-1139487450.
  6. ^ "narrowbody aircraft". Archived from the original on 2017-06-18. Retrieved 2009-03-18.
  7. ^ Royal Aero Club (Great Britain), Royal Aero Club of the United Kingdom (1967). Flight International. IPC Transport Press Ltd. p. 552.
  8. ^ Eric Pace (1981-05-24). "How Airline Cabins are Being Reshaped". New York Times.
  9. ^ "Wide body cargo screening still a challenge". Impact Publications. 2008-11-18. Retrieved 2009-02-17.
  10. ^ Javier Irastorza Mediavilla (Feb 1, 2018). "Commercial wide-body airplanes' deliveries per year, 1969-2017".
  11. ^ Irving, Clive (1994). Wide Body: The Making of the Boeing 747. Coronet. ISBN 0-340-59983-9.
  12. ^ Rumerman, Judy. "The Boeing 747" Archived October 7, 2012, at the Wayback Machine, U.S. Centennial of Flight Commission. Retrieved: 30 April 2006.
  13. ^ "The Airbus A300". CBC News. 2001-11-12. Retrieved 2009-08-24.
  14. ^ "TriStar Flies to Moscow". Flight International. March 21, 1974. p. 358. Archived from the original on 18 June 2015.
  15. ^ Smith, Hedrick (March 13, 1974). "Lockheed's Tristar Is Displayed in Soviet". The New York Times. Archived from the original on 20 February 2021. Retrieved 20 February 2021.
  16. ^ "Russia's New Long-Hauler". Flight International. August 20, 1977. p. 524. Archived from the original on 7 February 2019.
  17. ^ "Business | Airbus unveils 'superjumbo' jet". BBC News. 2005-01-18. Retrieved 2009-12-20.
  18. ^ a b c "Boeing lands US$100B worth of orders for its new 777 mini-jumbo jet, its biggest combined haul ever | Financial Post". Financial Post. Business.financialpost.com. 2013-11-18. Retrieved 2014-04-27.
  19. ^ a b c Tina Fletcher-Hill (2011-11-23). "BBC Two – How to Build..., Series 2, A Super Jumbo Wing". Bbc.co.uk. Retrieved 2014-04-27.
  20. ^ Pallini, Thomas (30 July 2020). "Double-decker planes are going extinct as Airbus and Boeing discontinue their largest models. Here's why airlines are abandoning 4-engine jets". Business Insider. Retrieved 3 March 2021.
  21. ^ Bor, Robert (2003). Passenger Behaviour. Ashgate Publishing, Ltd. p. 170. ISBN 9780754609360.
  22. ^ "Record Year For The World's Largest, Most Powerful Jet Engine" (Press release). GE Aviation. January 19, 2012.
  23. ^ "GE90-115B Fan Completing Blade Testing; On Schedule For First Engine To Test" (Press release). GE Aviation. June 17, 2001.
  24. ^ "GE strives to identify Air France engine fault". Flight International. January 3, 2006.
  25. ^ Guy Norris; Mark Wagner (2005). Airbus A380: superjumbo of the 21st century. Zenith Imprint. pp. 105–115. ISBN 9780760322185.
  26. ^ Guy Norris; Mark Wagner (2005). Airbus A380: superjumbo of the 21st century. Zenith Imprint. p. 111. ISBN 9780760322185.
  27. ^ [1] Archived November 20, 2008, at the Wayback Machine
  28. ^ "International Business Class". Vaustralia.com.au. 2010-08-18. Archived from the original on 2011-11-09. Retrieved 2011-05-21.
  29. ^ "A380 First Class Social Area & onboard Lounge | Emirates A380 First Class | The Emirates A380 | Our Fleet | Flying with". Emirates. 2009-06-02. Retrieved 2009-12-20.
  30. ^ "Emirates A380 First Class cabin features". Emirates. Retrieved 27 February 2022.
  31. ^ Kingsley-Jones, Max (1 September 2008). "Double luxury — how the airlines are configuring their A380s". FlightGlobal. Archived from the original on 2 September 2008.
  32. ^ "Airline Seat Pitch". UK-Air.net. Archived from the original on 2009-02-18. Retrieved 2009-02-17.
  33. ^ "Flying through a storm". Economist.com. 2008-10-22. Retrieved 2009-03-16.
  34. ^ Henry Nicholls, "Jumbo the Elephant goes large", The Guardian (November 7, 2013).
  35. ^ Eric Partridge, Tom Dalzell, Terry Victor, The New Partridge Dictionary of Slang and Unconventional English: J-Z (2006), p. 1128.
  36. ^ "EUROCONTROL — Revising wake turbulence categories to gain capacity (RECAT)". Eurocontrol.int. 2008-11-21. Archived from the original on 2009-05-25. Retrieved 2009-12-20.
  37. ^ B. N. Sullivan (2008-08-04). "Professional Pilot News: Airbus A380 requires new 'super' wake separation category". Propilotnews.com. Retrieved 2009-12-20.
  38. ^ [2] Archived September 5, 2009, at the Wayback Machine
  39. ^ "PICTURES: Airbus prepares A340-600 testbed for GTF ground runs". Flightglobal.com. 2008-09-29. Retrieved 2009-12-20.
  40. ^ "R-R prepares to ground-test Trent XWB ahead of A380 trials next year". Flightglobal.com. Retrieved 2011-05-21.
  41. ^ "GE — Aviation: GE90-115B Prepares For Flight Aboard GE's 747 Flying Testbed". Geae.com. 2002-02-26. Archived from the original on 2011-06-14. Retrieved 2009-12-20.
  42. ^ "Firefighting DC-10 available to lease". Flightglobal.com. Retrieved 2009-12-20.
  43. ^ "Evergreen International Aviation – Supertanker Services Inc". Evergreenaviation.com. Retrieved 2011-05-21.
  44. ^ "767 Airplane Characteristics for Airport Planning" (PDF). May 2011.
  45. ^ "A300-600 Airplane Characteristics for Airport Planning" (PDF). December 1, 2009.
  46. ^ "A310 Airplane Characteristics for Airport Planning" (PDF). December 1, 2009.
  47. ^ "A330 Airplane Characteristics for Airport Planning" (PDF). July 1, 2018.
  48. ^ "AirAsia X A330-300". Seatguru.com. Retrieved 2012-10-01.
  49. ^ "A340-200/300 Airplane Characteristics for Airport Planning" (PDF). July 1, 2018.
  50. ^ "787 Airplane Characteristics for Airport Planning" (PDF). Boeing. March 2018.
  51. ^ "SeatGuru Seat Map Japan Airlines Boeing 787-8 (788) V1". www.seatguru.com.
  52. ^ Bradley Perrett (12 Oct 2015). "Treading Carefully" (PDF). Aviation Week & Space Technology. Full-scale development of a Chinese and Russian 787-10 competitor looks imminent.
  53. ^ a b Bradley Perrett (Nov 9, 2018). "CR929 Schedule May Be Optimistic, UAC Says". Aviation Week & Space Technology.
  54. ^ "A350 Airplane Characteristics for Airport Planning" (PDF). June 1, 2018. Archived from the original (PDF) on May 31, 2019. Retrieved July 24, 2018.
  55. ^ Bruno Trévidic (28 Feb 2017). "Visite du 1er A350 d'Air Caraïbes : la classe éco".
  56. ^ "DC-10 Airplane Characteristics for Airport Planning" (PDF). MCDONNELL DOUGLAS CORPORATION. May 2011.
  57. ^ "MD-11 Airplane Characteristics for Airport Planning" (PDF). McDonnell Douglas. May 2011.
  58. ^ "L-1011-500 TriStar technical profile" (PDF). Lockheed. Archived from the original (PDF) on 2017-12-08. Retrieved 2018-07-24.
  59. ^ "Ilyushin IL-96-300 Cutaway". Flightglobal.
  60. ^ "777-200LR/300ER Airplane Characteristics for Airport Planning" (PDF). Boeing. March 2015.
  61. ^ "777-9 Airplane Characteristics for Airport Planning" (PDF). Boeing. March 2018.
  62. ^ "747 Airplane Characteristics for Airport Planning" (PDF). Dec 2012.
  63. ^ "A380 Airplane Characteristics for Airport Planning" (PDF). Dec 1, 2016. Archived from the original (PDF) on July 11, 2018. Retrieved July 24, 2018.

External links