Bell P-59 Airacomet

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P-59 Airacomet
Bell P-59B Airacomet at the National Museum of the United States Air Force.jpg
Bell P-59B Airacomet at the National Museum of the United States Air Force, Dayton, Ohio
RoleFighter/Jet Trainer
National originUnited States
Manufacturer Bell Aircraft
DesignerRobert A. Wolf and Herbert L. Bower
First flight1 October 1942
Primary users United States Army Air Forces
Number built66

The Bell P-59 Airacomet is a single-seat, twin jet-engine fighter aircraft that was designed and built by Bell Aircraft during World War II. It was the first jet produced in the United States. As the British were further along in jet engine development, they donated an engine for the United States to copy in 1941 that became the basis for the General Electric J31 jet engine used by the P-59 a year later. Because the plane was underpowered, the United States Army Air Forces (USAAF) was not impressed by its performance and canceled half of the original order for 100 fighters, using the completed aircraft as trainers. The USAAF would instead go on to select the Lockheed P-80 Shooting Star as its first operational jet fighter. Although no P-59s entered combat, the aircraft paved the way for later generations of U.S. turbojet-powered aircraft.

Contents

Design and development

The Power Jets W.1 engine that was later to be produced by GE as the General Electric J31 PowerJetsW.1.JPG
The Power Jets W.1 engine that was later to be produced by GE as the General Electric J31

Major General Henry H. "Hap" Arnold became aware of the UK's jet program when he attended a taxiing demonstration of the Gloster E.28/39 in April 1941. The subject had been mentioned, but not in-depth, as part of the Tizard Mission the previous year. He requested and was given, the plans for the aircraft's powerplant, the Power Jets W.1, which he took back to the U.S. He also arranged for an example of the engine, the Whittle W.1X turbojet, to be flown to the U.S. on 1 October in a Consolidated B-24 Liberator, [1] along with drawings for the more powerful W.2B/23 engine and a small team of Power Jets engineers. On 4 September, he offered the U.S. company General Electric a contract to produce an American version of the engine, which subsequently became the General Electric I-A. On the following day, he approached Lawrence Dale Bell, head of Bell Aircraft Corporation, to build a fighter to utilize it. Bell agreed and set to work on producing three prototypes. As a disinformation tactic, the USAAF gave the project the designation P-59A, to suggest it was a development of the unrelated Bell XP-59 fighter project which had been canceled. The design was finalized on 9 January 1942, and construction began. In March, long before the prototypes were completed, an order for 13 YP-59A pre-production aircraft was added to the contract. [2]

Details of fuselage and undercarriage of a P-59B, showing the nose armament Details of P-59B Armament, 1x 37mm canon and 3x .50 cal machine guns.jpg
Details of fuselage and undercarriage of a P-59B, showing the nose armament

The P-59A had an oval cross-section, all-metal stressed skin semi-monocoque fuselage that housed a single pressurized cockpit. The mid-mounted, straight wing had two spars plus a false spar in the inner panel. The electrically powered tricycle landing gear was attached to the center spar. The pair of General Electric J31 turbojets were positioned under the wing roots in streamlined nacelles. The armament was located in the nose of the aircraft; two of the three XP-59As and most of the YP-59As had a pair of 37-millimeter (1.5 in) M10 autocannon. Later aircraft, including the production models, had one M10 autocannon and three 0.5-inch (12.7 mm) AN/M2 Browning heavy machine guns. The aircraft carried a total of 290 US gallons (1,100 L; 240 imp gal) of fuel in four self-sealing tanks in the inner wing panels. Both production models could carry 1,590-US-gallon (6,000 L; 1,320 imp gal) drop tanks under the wings. In addition, the P-59B was provided with a 66-US-gallon (250 L; 55 imp gal) fuel tank in each outer wing panel. [3] [4]

The crated prototype had been built on the second floor of a disused Pierce-Arrow factory, but its components were too big to fit through any elevator and required a hole to be broken in the brick outer wall to remove the first XP-59A. It was shipped to Muroc Army Air Field (today, Edwards Air Force Base) in California on 12 September 1942 by train for flight testing. The aircraft first became airborne during high-speed taxiing tests on 1 October with Bell test pilot Robert Stanley at the controls, although the first official flight was made by Colonel Laurence Craigie the next day. While being handled on the ground, the aircraft was fitted with a dummy propeller to disguise its true nature. When heavy rains flooded Rogers Dry Lake at Muroc in March 1943, the second prototype was towed 35 mi (56 km) to Hawes Field, an auxiliary airfield of Victorville Army Airfield, later George Air Force Base, over a public road. After one flight on 11 March, security concerns caused the jet to be transferred to nearby Harper Lake where it remained until 7 April. [5] [6]

Five of the Airacomets, a pair of XP-59As, two YP-59As, and a P-59B had open-air flight observer cockpits (similar to those of biplanes) fitted in the nose with a small windscreen, replacing the armament bay. The XP-59As were used for flight demonstrations and testing, but one of the latter pair was used as a "mother ship" for the other modified YP-59A during remote control trials in late 1944 and early 1945. After the drone crashed during take-off on 23 March, a P-59B was modified to serve as its replacement. [7] [8] During diving trials in 1944, one YP-59A was forced to make a belly landing and another crashed when its entire empennage broke away. [9]

Over the following months, tests on the prototypes and pre-production P-59s revealed a multitude of problems including poor engine response and reliability (common shortcomings of all early turbojets), poor lateral and directional stability at speeds over 290 mph (470 km/h), so that it tended to "snake" and was a poor gunnery platform. The performance was greatly hampered by the insufficient thrust from its engines that was far below expectations. The Army Air Force conducted combat trials against propeller-driven Lockheed P-38J Lightning and Republic P-47D Thunderbolt fighters in February 1944 and found that the older aircraft outperformed the jet. It, therefore, decided that the P-59 was best suited as a training aircraft to familiarize pilots with jet-engine aircraft. [10] [11]

Even as deliveries of the YP-59As began in July 1943, the USAAF had placed a preliminary order for 100 production machines as the P-59A Airacomet, the name having been chosen by Bell employees. This was confirmed on 11 March 1944 but was later cut to 50 aircraft on 10 October after the procurement bureaucracy had digested the earlier evaluation. [12] [13]

Operational service

The first production P-59A with a Bell P-63 Kingcobra behind Bell P-59 Airacomet 060913-F-1234P-013.jpg
The first production P-59A with a Bell P-63 Kingcobra behind

The 13 service test YP-59As had a more powerful engine than their predecessor, the General Electric J31, but the performance improvement was negligible, with top speed increased by only 5 mph and a reduction in the time they could be used before an overhaul was needed. One of these aircraft, the third YP-59A (S/n: 42-108773) was supplied to the Royal Air Force (receiving British serial RJ362/G), in exchange for the first production Gloster Meteor I, EE210/G. [14] British pilots found that the aircraft compared very unfavorably with the jets that they were already flying. Two YP-59A Airacomets (42-108778 and 42-100779) were also delivered to the U.S. Navy where they were evaluated as the "YF2L-1" but were quickly found completely unsuitable for carrier operations. Three P-59Bs were transferred to the Navy in 1945–1946, although they kept their designations. The Navy used all five of its jets as trainers and for flight testing. [15]

Faced with their own ongoing difficulties, Bell eventually completed 50 production Airacomets, 20 P-59As and 30 P-59Bs; deliveries of P-59As took place in the fall of 1944. [16] The P-59Bs were assigned to the 412th Fighter Group to familiarize AAF pilots with the handling and performance characteristics of jet aircraft. [17] While the P-59 was not a great success, the type did give the USAAF and the USN experience with the operation of jet aircraft, in preparation for the more advanced types that would shortly become available. [12]

Variants

XP-59A with the short-lived red-outlined national markings (June 1943 to September 1943) P-59 Airacomet.jpg
XP-59A with the short-lived red-outlined national markings (June 1943 to September 1943)
XP-59
Unrelated piston engine-powered pusher-propeller design developed from the Bell XP-52. Not built. [18]
XP-59A
Prototype of the new jet engine-powered aircraft, three built, serial numbers 42-108784/108786. [19]
YP-59A
Series of test aircraft, 13 built, serial numbers 42-108771/108783. [20]
YF2L-1
Two YP-59A (42-108778/108779) delivered to the US Navy for carrier evaluation as Bu63960/63961. [21]
P-59A
First production version, 20 built, serial numbers 44-22609/22628. Redesignated ZF-59A in June 1948. [22]
XP-59B
Study for a single-engined P-59A. [23]
P-59B
Improved P-59A. 80 aircraft ordered but only 30 built, serial numbers 44-22629/22658, further 50 (44-22659/22708) canceled. Redesignated ZF-59B in June 1948. [24]

Operators

Surviving aircraft

A Bell P-59A Airacomet at the March Field Air Museum in 2013 A Bell P-59A Airacomet at March Field Air Museum in 2013.jpg
A Bell P-59A Airacomet at the March Field Air Museum in 2013

Six P-59s are known to survive today.

On display:

P-59A
P-59B

In storage:

XP-59A

Under restoration:

YP-59A

Specifications (P-59B)

3-view drawing of the P-59 Bell P-59A Airacomet 3-view.svg
3-view drawing of the P-59

Data fromThe American Fighter [33] [34]

General characteristics

Performance

Armament

See also

Bell YP-59A in flight. X and Y aircraft had rounded vertical stabilizers and wingtips while the production A and B models had squared surfaces. The YP-59A can be distinguished from the XP-59A because Ys had nose armament. Bell YP-59A in flight 060913-F-1234P-008.jpg
Bell YP-59A in flight. X and Y aircraft had rounded vertical stabilizers and wingtips while the production A and B models had squared surfaces. The YP-59A can be distinguished from the XP-59A because Ys had nose armament.

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References

Notes

  1. Meher-Homji 2004, p. 306.
  2. Pace 2000, pp. 4–7.
  3. Pace 2000, pp. 40–41.
  4. Air International March 1980, pp. 134, 138.
  5. Air International March 1980, pp. 132–134.
  6. Pace 2000, pp. 6–10, 12.
  7. Air International March 1980, pp. 136–137.
  8. Pace 2000, pp. 32–34.
  9. Pelletier 1992, p. 52.
  10. Air International March 1980, pp. 137.
  11. Pace 2000, pp. 27, 29, 36–38.
  12. 1 2 Air International March 1980, p. 138.
  13. Pace 2000, pp. 22, 27.
  14. "Gloster Meteor." Flight, 27 May 1955, p. 727.
  15. Pace, pp. 64, 75.
  16. "P-59A Airacomet". March Field Air Museum. Retrieved 19 November 2017.
  17. "Bell XP-59A Airacomet." Archived 4 January 2012 at the Wayback Machine Smithsonian National Air and Space Museum. Retrieved: 15 December 2011.
  18. Pace 2000, p. 5.
  19. Pelletier 1992, pp. 50–51.
  20. Pelletier 1992, p. 51.
  21. Pelletier 1992, pp. 51–52.
  22. Pace 2000, pp. 22–23.
  23. Pace 2000, pp. 25–26.
  24. Pace 2000, pp. 23–24.
  25. Pace 2000, p. 75.
  26. Pace 2000, p. 28.
  27. "P-59A Airacomet/44-22614" Archived 23 December 2005 at the Wayback Machine March Field Air Museum Retrieved: 10 April 2012.
  28. Pace 2000, p. 80.
  29. Pace 2000, p. 79.
  30. "P-59B Airacomet/44-22650" Archived 26 August 2007 at the Wayback Machine National Museum of the United States Air Force Retrieved: 10 April 2012.
  31. "Bell XP-59A Airacomet". National Air and Space Museum. Retrieved 13 September 2023.
  32. "Restoration Projects". Planes of Fame Air Museum. Retrieved 24 November 2020.
  33. Angelucci and Bowers 1987, p. 50.
  34. AN 01-110FF-2 "Erection and Maintenance Instructions for Army Models P-59A and P-59B Airplanes"
  35. Lednicer, David. "The Incomplete Guide to Airfoil Usage". m-selig.ae.illinois.edu. Retrieved 16 April 2019.

Bibliography

Further reading

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