Jump to content

Four-engined jet aircraft

From Wikipedia, the free encyclopedia
(Redirected from Quadjet)

The de Havilland Comet, the first commercial jetliner, used four jet engines.

A four-engined jet, sometimes called a quadjet, is a jet aircraft powered by four engines. The presence of four engines offers increased power and redundancy, allowing such aircraft to be used as airliners, freighters, and military aircraft. Many of the first purpose-built jet airliners had four engines, among which stands the De Havilland Comet, the world's first commercial jetliner.[1] In the decades following their introduction, their use has gradually declined due to a variety of factors, including the approval of twin-engine jets to fly farther from diversion airports as reliability increased, and an increased emphasis on fuel efficiency.[2]

Design

[edit]
Podded engines mounted under the wings of a Boeing 747-8I.

Podded engines

[edit]

The engines of a 4-engined aircraft are most commonly found in pods hanging from pylons underneath the wings.[3] This can be observed in the Airbus A340, Airbus A380, and Boeing 747. Many military airlifters also feature this design, including the Antonov An-124, Boeing C-17 Globemaster, and Lockheed C-5 Galaxy. In this location, the engines can act as a relieving load and reduce the structural weight of the wing by 15%. They are also in a more accessible location for maintenance or replacement. However, disadvantages include a higher risk of the engines ingesting foreign objects as they have a lower ground clearance, and a larger yawing moment during an engine failure.[4] The supersonic airliner Concorde had its engines mounted in rectangular pods conformal to the underside of the wing, without any pylons. The omission of pylons reduces drag and eliminates the risk of them being overstressed.[5]

Rear view of a Vickers VC10, showing its four podded engines mounted on the rear fuselage

The four podded engines can also be attached to the rear fuselage, necessitating a T-tail.[3] This reduces cabin noise and frees up more space on the wings for high-lift devices and fuel storage. The airflow over the wings is also undisturbed due to the absence of pylons. However, the rear-mounted engines shift the centre of gravity aft, and are located further from the fuel supply.[4] The Ilyushin Il-62 and Vickers VC10 both have their four engines mounted in this configuration.[6][7]

Buried engines

[edit]
Intakes leading into the buried engines of a de Havilland Comet 4

Jet aircraft can also be designed with engines buried within the aircraft structure.[3] The de Havilland Comet incorporated four turbojets buried inside its wing roots, the most common location for buried engines. This design reduces both drag and the risk of ingesting foreign objects, but increases the difficulty of maintenance and complicates the wing structure.[4] The Northrop Grumman B-2 Spirit stealth strategic bomber has all four turbofans buried within its wing (as a flying wing, the wing is the main structural component). This reduces the heat signature of the engines by concealing the fans and minimizing the exhaust signature.[8]

Other

[edit]

The Hawker Siddeley Trident 3B not only has two engines in rear fuselage external nacelles, but also has other two engines mounted vertically in the tail. The aircraft was initially designed as trijet, but the Trident 3B added a fourth engine as additional power was required by the stretched fuselage, increased wing chord and raised gross weight.

Advantages and drawbacks

[edit]

Advantages

[edit]

A major advantage of having four engines is the redundancy offered, leading to increased safety.[2] A single engine failure is much less significant as the three remaining engines can usually provide sufficient power to comfortably reach a diversion airport or continue the journey, depending on factors such as the severity of the malfunction, altitude, fuel load, and weather conditions.[9] With the increased reliability of jet engines, engine failures rates can be as low as 1 in-flight shutdown per 100,000 engine-hours,[10] reducing the significance of this advantage.

During a single-engine failure, the amount of power lost with four engines is proportionately lower than three or two engines. This is because three of the four engines will still be functioning, constituting a 25% reduction in thrust, compared to 33% for trijets and 50% for twinjets. This can be observed in the following example involving the Boeing 747-400 quadjet, McDonnell Douglas MD-11 trijet, and Boeing 767-300ER twinjet. With all engines operative at maximum takeoff weight, all three aircraft have the power to weight ratios of approximately 1 to 3.4. Following the failure of one engine, the power to weight ratio drops to 1 to 4.7 (747-400), 1 to 5.5 (MD-11), and 1 to 6.6 (767-300ER).[11] The Boeing 747-400 experiences the least degradation in performance, making it safer during an engine failure.

Fitting an aircraft with four engines also increases power, enabling more passengers, heavier payloads, and increased performance.[12] This was especially important for early jet airliners, as the low-bypass turbofans and turbojets of the time were much weaker compared to modern high-bypass turbofans. The Pratt & Whitney JT3D from 1958 had a thrust output of 76 kilonewtons (17,000 lbf),[13] while modern engines like the General Electric GE90 can produce over 440 kilonewtons (100,000 lbf) of thrust,[14] making this advantage less significant nowadays as larger airliners no longer necessarily need four engines.

The largest four-engined jet airliners are distinguished with having the highest passenger capacities—the Airbus A380 can carry up to 853 passengers in a single class layout.[15] This allows them to satisfy demand on extremely busy routes, and when filled with passengers to distribute the cost, they can be very profitable.[12]

Drawbacks

[edit]

Four smaller engines consume more fuel than two larger ones, driving up operational costs. Specifically, the Boeing 747 quadjet consumes[clarification needed] 2.5 litres (0.66 US gallons) more fuel per kilogram (2.2 pounds) of payload compared to the Boeing 787 twinjet.[16] With jet fuel a large part of total costs, this makes quadjets less attractive to airlines and many are shifting their attention towards more efficient aircraft types.[17]

Four engines also incur higher maintenance costs, as each one needs to undergo regular inspections and servicing. Approximately half of the airliner maintenance costs are derived from routine engine maintenance, so the additional expense in maintaining four engines is significant.[18]

The ability of a very large aircraft to carry a large number of passengers can be a drawback when the seats are not filled. This is an emerging trend, particularly because the airline industry has been transitioning from a spoke-hub model to a point-to-point model.[12] In the spoke-hub model, passengers are moved from smaller outlying points and concentrated at large hubs. This introduces a need for high-capacity aircraft.[19] Conversely, the point-to-point model transports passengers directly from origin to destination, spreading them out across different routes and requiring fewer seats on the servicing aircraft.[19] Especially with the recent[when?] appearance of low-cost carriers which operate many point-to-point flights, it is more difficult to fill the seats of the largest airliners.[12] For this reason, the wide-body fleets of these airlines are dominated by lower capacity, long range twinjets such as the A330 and 787.[20]

History

[edit]
A Boeing 707-120B, the earliest production variant of the 707

Early history

[edit]

Prior to the Jet Age, airliners were powered by piston engines. Engine failures were relatively common, so providing redundancy with four engines was important for long range flights.[21] This need extended into the beginning of the Jet Age, and combined with the limited thrust available from early jet engines, it was most practical to design large jet airliners with four engines.[4][22] The first commercial jet aircraft was the four-engined De Havilland Comet, which first flew in 1949.[1] However, due to a series of fatal metal fatigue accidents between 1953 and 1954, the Comet was grounded.[23] This greatly tarnished its reputation and it was the later airliners that truly benefited from the subsequent improvements. In 1958, Boeing introduced the 707 and a year later, Douglas rolled out its DC-8, both types also with four engines.[24][25] Both were very successful and the 707 in particular is credited with advancing the Jet Age.[26] The large airliners flourished during this period, frequently operating on both domestic and international routes.[27]

Later decades and gradual decline

[edit]

By the 1960s it became apparent that having four engines reduced fuel efficiency. This was not an issue for long-haul routes which carried 300 or more passengers for 8 to 12 hours, allowing for a high cost-to-passenger-mile ratio. On the other hand, the large four-engined types were less suited for frequent short-haul services, which demanded multiple take-offs and landings daily, costing more fuel while also typically carrying fewer passengers per flight. This prompted the development of large trijets and twinjets. Due to limitations in engine technology, twinjets of this era were small and had relatively short range. The FAA's 60-Minute Rule also prevented them from flying farther than 60 minutes away from diversion airports due to their lower engine redundancy.[28] Trijets represented a compromise between fuel efficiency and redundancy. In 1969, Boeing launched the 747. Nicknamed the "Jumbo Jet", it was the first wide-body airliner, able to carry significantly more passengers than any other aircraft.[29] Its capacity and performance were unmatched, even after the launch of wide-body trijet competition in the form of the McDonnell Douglas DC-10 and Lockheed L-1011 TriStar.

Concorde on landing, showing its four underwing mounted engines.

Within its own category in commercial aviation, the supersonic airliner Concorde began service in 1976.[30] Its four Rolls-Royce/Snecma Olympus 593 turbojets allowed it to cruise at twice the speed of sound.[5] At the time of inception it was regarded as the future of air transportation. However, in large part due to high operating costs and noise issues, Concorde never achieved the predicted level of success.[31]

When the BAe 146 was introduced in 1983, it was unusual because it was a four-engined short range regional airliner.[32] Its design ultimately enabled quieter operation and short take off and landing capabilities.[33]

In the 1980s, the increased reliability and available power of jet engines enabled twinjets to safely fly on one engine. This prompted the introduction of ETOPS ratings for twinjets, allowing them to circumvent the 60-Minute Rule and fly on transoceanic routes previously serviced by four-engined types.[28][34] The advantage of redundancy brought by four engines was no longer necessary and they could no longer compete with the lower fuel consumption and maintenance costs of twinjets with higher-powered engines. All but the largest four-engined types, such as the Boeing 747, became uneconomical and this led to the retirement of the ageing 707 and DC-8 fleets for passenger service. Nonetheless, Boeing rolled out the 747-400 in 1989, which enjoyed high capacities (over 300 passengers) and long range, a combination still unmatched by twinjets at the time, making this the most commercially successful 747 variant.[35] Airbus, after ending collaboration talks with McDonnell Douglas who went on to produce the MD-11 long-range trijet, instead launched the A340 quadjet in 1993 as a long-range derivative of the A330 twinjet as their initial variants shared the same fuselage and wing.[36]

Large twins such as this Boeing 777-300ER can almost match the capacity of the largest four-engined types.

Between the 1970 and the 1990s, twinjets, trijets, and quadjets shared engines of similar output, such as when the DC-10, MD-11, Boeing 767, and Airbus A300, A310, and A330, and Boeing 747 all had variants powered by the widespread General Electric CF6, so at the time additional engines were needed for larger capacities and longer range. The major advantages of three and four engines became much less significant when the twin-engined Boeing 777 was introduced in 1995, equipped with the purpose-designed General Electric GE90 engine developed from further advancements in high-bypass turbofan technology.[37] The original 777-200 could seat upwards of 300 passengers, a significant increase upon existing twinjets such as the 767, which could typically only seat 200-300 passengers.[38] The subsequent development of the 777-300ER pushed the passenger capacity to just under 400, approaching the 747 and superseding the A340, while being more efficient and incurring lower engine maintenance costs. Airbus, not seeing much success with updated A340-500/600 variants powered by the Rolls-Royce Trent 500, went for the all-new A350XWB to compete against the 777 and upcoming 787 Dreamliner.

By the early 2000s, the only remaining advantage of the largest types was their ability to carry more passengers than the largest twinjets. In the years following the September 11 attacks, the increase in fuel prices and decline in the aviation industry heightened the need to minimise operating costs and expenditures. Production of the 747-400 passenger variant ceased by 2005 and deliveries of the A340 dropped to 11 per year, as they faced competition from more efficient and comparably capable twinjets.[39][40]

Current status

[edit]
The Airbus A380 is currently the world's largest airliner

The use of four engines was invigorated in 2005 when Airbus introduced the A380, currently the world's largest airliner.[41] It was designed for routes with ultra-high demand, typically seating 575 passengers in two full-length decks. However, as of 2018, Airbus has only fulfilled a quarter of its initial projected figure of 1,200 sales over two decades.[42] This can be attributed to a modern trend towards point-to-point travel using smaller but highly efficient twinjets such as the Airbus A350 and Boeing 787, as opposed to a spoke-hub model which favours massive aircraft such as the A380.[12] The largest operator of the A380, Emirates, profits from its fleet because its primary hub is situated at Dubai International Airport, where many long-haul routes have their stopovers. This makes it easier for Emirates to fill the seats of its A380s.[12] After Emirates reduced its last order in February 2019, Airbus announced that A380 production would end in 2021.

Some airlines, such as Lufthansa, have opted to use both the Airbus A380 and Boeing 747.

As engine power continued to grow and capacity demands decreased, twinjet aircraft such as the Boeing 787 Dreamliner and Airbus A350 XWB ate into the markets that traditionally demanded four engines.

In response to the A380, Boeing introduced the 747-8 in 2011 as a successor to the 747-400.[43] The 747-8I passenger variant has only received 50 orders as of 2018, while the 747-8F freighter variant has been more successful with over 100 orders.[44] As of 2018 the 747-8F is unmatched in range and payload,[45] making it an option for cargo carriers.

After the Airbus A380 ended production, the Boeing 747-8 also stopped production with the last delivery taking place on January 31 2023,[46] meaning no double-deck passenger jets were any longer in production. Boeing attributed the retirement of their 747 fleets to the effect of the COVID-19 pandemic.[47]

Types currently in production

[edit]

Airliners

[edit]

Military

[edit]

References

[edit]
  1. ^ a b Hollingham, Richard (2017-04-05). "The British airliner that changed the world". BBC Future. Retrieved 2018-10-18.
  2. ^ a b Mutzabaugh, Ben (2017-10-09). "For airlines, two engines are better than four". USA Today. Retrieved 2018-11-08.
  3. ^ a b c Raymer, Daniel (1992). Aircraft Design: A Conceptual Approach. pp. 207.
  4. ^ a b c d Tulapurkara, E.G. (2013-10-15). "Fuselage and tail sizing - 7". Airplane Design (Aerodynamic).
  5. ^ a b Freudenrich, Craig (2001-01-29). "How Concordes Work". HowStuffWorks. Retrieved 2018-10-27.
  6. ^ "Ilyushin IL-62 Passenger Airliner - Aerospace Technology". Aerospace Technology. Retrieved 2018-10-18.
  7. ^ "Vickers VC10". BAE Systems | International. Retrieved 2018-10-26.
  8. ^ "B-2 Stealth Bomber – How It Works". How It Works. 2011-03-22. Retrieved 2018-10-26.
  9. ^ "14 CFR 121.565 - Engine inoperative: Landing; reporting". LII / Legal Information Institute. Retrieved 2018-10-18.
  10. ^ Ekstrand, Chet (2003). "New ETOPS Regulations" (PDF). Flight Operations.
  11. ^ Williams, David J. (2015-06-25). "Four Engines vs. Two: The Surprising Mathematical Guarantee of Safety - NYCAviation". NYCAviation. Retrieved 2018-10-26.
  12. ^ a b c d e f Mentour Pilot (2018-08-10). Why are the Jumbo-jets disappearing?. Retrieved 2018-10-18.
  13. ^ "Pratt & Whitney JT3D-1 Production Prototype Turbofan Engine". National Air and Space Museum. 2016-03-16. Retrieved 2018-10-19.
  14. ^ "The GE90 Engine | GE Aviation". www.geaviation.com. Retrieved 2018-10-19.
  15. ^ Smith, Oliver (2018-01-16). "Why is the world's largest passenger plane facing the scrap heap?". The Telegraph. Retrieved 2018-10-30.
  16. ^ "How time flies, a year of 787 flying". Qantas News Room. Retrieved 2018-10-26.
  17. ^ "How Are Airlines Adjusting to Higher Jet Fuel Prices? - Avionics". Avionics. 2018-08-24. Retrieved 2018-10-19.
  18. ^ "Maintenance Costs for Aging Aircraft" (PDF). IATA. 2018.
  19. ^ a b "Airline Networks: from hub-and-spoke to point-to-point networks". MS&E 135 Networks @ Stanford. 2016-04-09. Retrieved 2018-10-26.
  20. ^ "The world's low cost airline widebody aircraft fleet – a niche that is growing". CAPA - Centre for Aviation. Retrieved 2018-10-26.
  21. ^ "History of flight - The jet enters the civilian world". Encyclopedia Britannica. Retrieved 2018-10-26.
  22. ^ "The First Generation of Jet Airliners | America by Air". airandspace.si.edu. Retrieved 2018-10-18.
  23. ^ Glancey, Jonathan. "The crashes that changed plane designs forever". Retrieved 2018-10-18.
  24. ^ "Boeing 707 | Description, Background, History, & Facts". Encyclopedia Britannica. Retrieved 2018-10-18.
  25. ^ "DOUGLAS DC-8-50 - SKYbrary Aviation Safety". www.skybrary.aero. Retrieved 2018-10-18.
  26. ^ Glancey, Jonathan. "Boeing 707: The aircraft that changed the way we fly". Retrieved 2018-10-26.
  27. ^ "the jet airliner". www.century-of-flight.net. Retrieved 2018-10-18.
  28. ^ a b Hoke, Ken (2015-10-07). "ETOPS - Enhancing Safety On Long Flights - AeroSavvy". AeroSavvy. Retrieved 2018-10-18.
  29. ^ Dowling, Stephen (2018-09-28). "The Boeing 747: The plane that shrank the world". BBC. Retrieved 2018-11-04.
  30. ^ "Concorde | Summary, History, & Facts". Encyclopedia Britannica. Retrieved 2018-10-18.
  31. ^ McFadden, Christopher (2017-03-05). "The Real Reason Why the Supersonic Passenger Jet Concorde Failed". Retrieved 2018-10-27.
  32. ^ "BAE 146 - Aerospace Technology". Aerospace Technology. Retrieved 2018-10-30.
  33. ^ "History of the BAe 146". www.shockcone.co.uk. Archived from the original on 2018-04-27. Retrieved 2018-11-09.
  34. ^ Santiago, JP (2015-12-09). "The Boeing 767 and the Birth of ETOPS". www.tailsthroughtime.com. Archived from the original on 2017-08-11. Retrieved 2018-11-07.
  35. ^ Honig, Zach (2014-08-15). "The death of the original jumbo jet, Boeing's 747-400". Engadget. Retrieved 2018-10-18.
  36. ^ "Airbus A340 History - Modern Airliners". www.modernairliners.com. Retrieved 2018-10-18.
  37. ^ "Boeing 777 - The Triple Seven - Modern Airliners". www.modernairliners.com. Retrieved 2018-10-18.
  38. ^ "Boeing 767 - Aerospace Technology". Aerospace Technology. Retrieved 2018-10-26.
  39. ^ "Size matters for aircraft fuel efficiency. Just not in the way that you think. | International Council on Clean Transportation". www.theicct.org. 27 February 2018. Retrieved 2018-11-09.
  40. ^ "Airbus A340 Production list | Airfleets aviation". www.airfleets.net. Retrieved 2018-11-09.
  41. ^ "The incredible history of the Airbus A380 superjumbo jet, which went from airline status symbol to reject in just 10 years". Business Insider. Retrieved 2018-10-18.
  42. ^ "The days of the A380 look numbered". The Economist. Retrieved 2018-11-05.
  43. ^ Dorman, Clive (2014-09-30). "Boeing 747-8 v Airbus A380: Is the era of the jumbo jet over?". Traveller. Retrieved 2018-10-18.
  44. ^ "Boeing 747 8 Orders and Deliveries - Modern Airliners". www.modernairliners.com. Retrieved 2018-10-26.
  45. ^ Aboulafia, Richard. "Last Call For Quadjets: Will Boeing 747 Outlive Airbus A380?". Forbes. Retrieved 2018-10-26.
  46. ^ "Jumbo jet era ends as Boeing delivers last 747 plane – DW – 01/31/2023". Deutsche Welle.
  47. ^ "747 production to end as Boeing adapts to post COVID-19 reality, says GlobalData". 2 August 2020.