Pratt & Whitney JT3D

JT3D/TF33

JT3D-3B on a Royal Australian Air Force Boeing 707
Type	Turbofan
Manufacturer	Pratt & Whitney
First run	1958
Major applications	B-52H Stratofortress Boeing 707 C-141 Starlifter Douglas DC-8
Number built	ca. 8,600
Developed from	Pratt & Whitney J57/JT3C

The Pratt & Whitney JT3D is an early turbofan aircraft engine derived from the Pratt & Whitney JT3C turbojet. It was first run in 1958 and was first flown in 1959 under a B-45 Tornado test aircraft. Over 8,000 JT3Ds were produced between 1959 and 1985. Most JT3D engines still in service today are used on military aircraft, where the engine is referred to by its USAF designation of TF33.

Design and development

Aware of the competition from the Rolls-Royce Conway turbofan, Pratt&Whitney decided to develop the JT3D turbofan from the JT3C turbojet for later deliveries of the Boeing 707 and the Douglas DC-8, then nearing entry into service. A 2-stage fan replaced the first 3 stages of the 9-stage JT3C LP compressor. On the LP turbine, the second stage was enlarged and a third stage added.

Unlike GE with the CJ805-23, Pratt & Whitney had not undertaken any transonic fan research prior to designing the JT3D, so they were unable to incorporate a single stage unit into the specification.^[1] Instead P&W designed a 2-stage unit based on some research they had done to support the J91 nuclear turbojet.

Nevertheless, the overall P&W engine design was quite an elegant solution to produce a turbofan to compete with the Rolls-Royce Conway in a very short timescale. Indeed, 55 years later, the basic architecture of the JT3D can still be seen in modern large American civil turbofans, such as the GE90, PW4000, etc..

On the Boeing 707 the JT3D fan nacelle was relatively short, whereas the Douglas DC-8 installation had a full length fan cowl. Pratt & Whitney provided a kit whereby JT3C's could be converted to the JT3D standard in an overhaul shop.^[2]

In 1959, important orders for the engine were the Boeing 707-120B and Boeing 720B when American Airlines ordered one 707 powered by JT3D turbofans and KLM ordered a JT3D powered Douglas DC-8. The earlier 707s had been powered by the turbojet JT3C and the improved efficiency of the turbofan soon attracted the airlines. A JT3D powered 707-123B and 720-023B (the suffix B was to indicate a turbofan powered aircraft) entered service with American Airlines on the same day, March 12, 1961.

The Boeing KC-135 Stratotankers were all originally powered by turbojet engines. With the demise of many airline 707s the United States Air Force took the opportunity to buy the surplus airframes and use the engines to re-engine the KC-135As used by the Air National Guard and reserve squadrons with the civilian JT3D (designated TF33-PW-102). Over 150 aircraft were modified and the former KC-135A were re-designated the KC-135E.^[3]

JT3Ds from Boeing 707s are used to re-engine USAF KC-135As, 1984.

After long service for both airlines and air forces the number of JT3D powered aircraft is steadily decreasing. 135 KC-135s use the JT3D while 354 were fitted with CFM International CFM56 engines which provide greater thrust and increased operational flexibility due to their lower noise footprint. The noise of the JT3D is one of the reasons NATO has debated re-engining their E-3 Sentry AWACS fleet, since the aircraft are subject to restrictions that modern-engined aircraft are not. Operational flexibility would be further increased due to the ability of higher power engines to increase the ceiling of the aircraft, extending the horizon for radar surveillance; for instance, RAF, French and Saudi E-3s routinely fly higher than NATO/USAF counterparts.

Another well known aircraft which is fitted with the JT3D (in TF33 form) is the Boeing B-52H Stratofortress. The 'H' model of the B-52 was the only production variant of the famous bomber to be fitted with turbofan engines, and the only model remaining in US Air Force service. It is expected to remain as a mainstay of the USAF heavy bomber fleet until at least 2040.

Variants

TF33-P-7 engine of a C-141B

JT3D-1: 17,000 lbf (75.62 kN) thrust civil version, (Water injection optional)^[4]
JT3D-2: (TF33-P-3) 17,000 lbf (75.62 kN)^[4]
JT3D-3: 18,000 lbf (80.07 kN), (Water injection optional)^[4]
JT3D-3A: (TF33-P-5) 18,000 lbf (80.07 kN)^[4]
JT3D-3B: 18,000 lbf (80.07 kN) thrust civil version
JT3D-5A: (TF33-P-7) 18,000 lbf (80.07 kN), (Water injection optional)^[4]
JT3D-8A: (TF33-P-7) 18,000 lbf (80.07 kN), (Water injection optional)^[4]
JT3D-7: 19,000 lbf (84.52 kN) thrust civil version
JT3D-15: 22,500 lbf (100.08 kN) thrust civil version for the unbuilt 707-820
TF33-P-3: 17,000 lbf (75.62 kN) thrust for the Boeing B-52H Stratofortress^[4]
TF33-P-5: 18,000 lbf (80.07 kN) thrust for the Boeing KC-135 Stratotanker^[4]
TF33-P-7: 21,000 lbf (93.41 kN) thrust for the Lockheed C-141 Starlifter^[4]
TF33-P-11: 16,000 lbf (71.17 kN) thrust for the Martin RB-57F Canberra

Aircraft applications

JT3D on a Douglas DC-8

Civilian (JT3D)

TF33/JT3D on Boeing VC-137B at Seattle Museum of Flight

Military (TF33)

B-52 Stratofortress
Boeing C-18
C-135B Stratolifter
E-3 Sentry
E-8 Joint STARS
KC-135E Stratotanker (JT3Ds from surplus civil 707 airliners)
VC-137B/C Stratoliner
C-141 Starlifter
Martin RB-57F

Specifications (JT3D-1)

General characteristics

Type: Turbofan
Length: ≈138 in (3505 mm)flange-to-flange
Diameter: ≈ 51.57 in (1310 mm) fan tip
Dry weight: ≈4361 lb (1978kg) bare engine

Components

Compressor: Axial flow, 2-stage fan, 6-stage IP compressor and 7-stage HP compressor
Combustors: cannular, 8 flame tubes
Turbine: Axial flow, single stage HP turbine and 3-stage LP turbine

Performance

Maximum thrust: 17,000 lbf (76 kN) Take-off (flat-rated to ISA); partial thrust restoration with water injection
Overall pressure ratio: ≈12.5:1; bypass ratio 1.42:1
Air mass flow: 432 lb/s (196 kg/s)
Turbine inlet temperature: ≈1150 K @Take-off, SLS, ISA
Specific fuel consumption: ≈0.78 lb/(lbf·h) (22 g/(kN·s)) @ 4000 lbf thrust, M 0.82, 35000 ft, ISA
Thrust-to-weight ratio: 3.9 bare engine

Specifications (TF33-P-7)

^[5]

General characteristics

Type: Turbofan
Length: 142 in (3607 mm)
Diameter: 54 in (1371.6 mm)
Dry weight: 4650 lb (2109 kg)

Components

Compressor: Axial flow, 2-stage fan, 7-stage IP compressor and 7-stage HP compressor
Combustors: cannular, 8 flame tubes
Turbine: Axial flow, single stage HP turbine and 3-stage LP turbine

Performance

Maximum thrust: 21,000 lbf (93 kN) Maximum Rating, SLS, ISA
Overall pressure ratio: ≈16:1
Air mass flow: 498 lb/s (226 kg/s)
Turbine inlet temperature: ≈1227K
Specific fuel consumption: 0.56 lb/(lbf·h) (16 g/(kN·s)) Maximum Rating, SLS, ISA
Thrust-to-weight ratio: 4.516

References

↑ Smith, George E.; Mindell, David A. (2000), "The Emergence of the Turbofan Engine", Atmospheric Flight in the Twentieth Century, Kluwer Academic Publishers, pp. 107–155
↑ based on article in Flight magazine 19 December 1958
↑ Tony Pither, The Boeing 707 720 and C-135, Air-Britain (Historians), 1998, ISBN 0-85130-236-X
1 2 3 4 5 6 7 8 9 Taylor, John W.R. FRHistS. ARAeS (1962). Jane's All the World's Aircraft 1962-63. London: Sampson, Low, Marston & Co Ltd.
↑ http://www.aircraftenginedesign.com/TableB2.html

Taylor, John W.R. FRHistS. ARAeS (1962). Jane's All the World's Aircraft 1962-63. London: Sampson, Low, Marston & Co Ltd.

External links

Wikimedia Commons has media related to Pratt & Whitney TF33.

Pratt & Whitney JT3D (TF33)

Pratt & Whitney aircraft engines

Radial engines	R-985 R-1340 R-1535 R-1690 R-1830 R-1860 R-2000 R-2060 R-2180-A R-2180-E R-2270 R-2800 R-4360 Double Wasp Hornet (A) Hornet B Twin Hornet Twin Wasp (R-1830) Twin Wasp (R-2000) Twin Wasp E Twin Wasp Junior Wasp series Wasp Wasp Junior Wasp Major Yellow Jacket

H piston engines	X-1800/XH-2600 XH-3130 (XH-3730)

Free-piston gas turbines	PT1

Turbojets	JT3C JT4 JT6 JT7 JT8A JT9 JT11 JT12 J42 J48 J52 J57 J58 J60 J75 J91

Turbofans	GP7000† JT3D JT4D JT8D JT9D JTF10 JTF10A JT10D JTF14 JTF16 JTF17 JTF22 PW1000G PW1120 PW2000 PW4000 PW5000 PW6000 STF200 SuperFan† V2500† F100 F105 F117 F119 F135 F401 TF30 TF33 RM8

Turboprops/Turboshafts	APW34† JFTD12 PT2 PT3 PT4 PT5 T34 XT45 T52 XT57 T73 T800-APW†

Propfans	578-DX†

Rocket engines	RL10

Aeroderivative gas turbine engines	GG3/FT3 GG4/FT4 FT8

Subsidiaries	Pratt & Whitney Canada Pratt & Whitney Rocketdyne

Key people	Leonard S. Hobbs George J. Mead Wright Parkins Perry Pratt Frederick Rentschler Richard "Dick" Soderberg Andrew Willgoos

† Joint development aeroengines

United States military gas turbine aircraft engine designation system

Turbojets	J30 J31 J32 J33 J34 J35 J36 J37 XJ38 J39 J40 XJ41 J42 J43 J44 J45 J46 J47 J48 XJ49 J51 J52 J53 J54 J55 J56 J57 J58 J59 J60 J61 J63 J65 J67 J69 J71 J73 J75 J79 J81 J83 J85 J87 J89 J91 YJ93 J95 J97 J99 J100 YJ101 J102 J400 J401 J402 J403 J700

Turboprops/ Turboshafts	T30 T31 T33 T34 T35 T36 T37 T38 T39 T40 T41 T42 T43 T44 T45 T46 T47 T48 T49 T50 T51 T52 T53 T54 T55 T56 T57 T58 T60 T61 T62 T63 T64 T65 T66 T67 T68 T69 T70 T71 T72 T73 T74 T76 T78 T80 T100 T101 T400 T405 T406 T407 T408 T700 T701 T702 T703 T706 T708 T800

Turbofans	TF30 TF31 TF32 TF33 TF34 TF35 TF37 TF39 TF41 F100 F101 F102 F103 F104 F105 F106 F107 F108 F109 F110 F112 F113 F117 F118 F119 YF120 F121 F122 F124 F125 F126 F127 F128 F129 F135 F136 F137 F138 F400 F401 F402 F404 F405 F408 F412 F414 F415

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Pratt & Whitney JT3D

Design and development

Variants

Aircraft applications

Specifications (JT3D-1)

General characteristics

Components

Performance

Specifications (TF33-P-7)

General characteristics

Components

Performance

See also

References

External links