Bristol Siddeley Orpheus

Orpheus
	Orpheus on display at the Flugausstellung Hermeskeil
Type	Turbojet
National origin	United Kingdom
Manufacturer	Bristol Siddeley
First run	1957
Major applications	Fiat G.91 ; Folland Gnat ; Fuji T-1 ; HAL HF-24 Marut
Developed into	Rolls-Royce Pegasus

Last updated March 09, 2024

The Bristol Siddeley Orpheus is a single-spool turbojet developed by Bristol Siddeley for various light fighter/trainer applications such as the Folland Gnat and the Fiat G.91. Later, the Orpheus formed the core of the first Bristol Pegasus vectored thrust turbofan used in the Harrier family.

Design and development

The engine had its genesis in a 1952 request by Teddy Petter of Folland for an engine in the 5,000 pounds (22 kN) class to power a new trainer and lightweight fighter-bomber they were developing.^[1] Stanley Hooker, relatively new to the company after an earlier career at Rolls-Royce, took the project under his wing. He delivered a relatively simple and easy to maintain engine, which was put into use in the Folland Gnat, flying in 1955.

The Orpheus incorporated the novel feature of a large-diameter shaft for its single spool which then needed only two bearings. The weight savings from deleting a bearing and associated parts listed below gave an engine with a thrust of 5,000 lbf but weighing only 800 lb.^[2]^{[lower-roman 1]} Eliminating the usual centre support bearing for the shaft joining the compressor and turbine meant the shaft would whirl, assuming a bowed shape, and damage the engine. Whirling was prevented by using a large diameter tube in place of the usual small diameter shaft. The large-diameter thin-walled tube, more than 8 inches in diameter was stiff enough to raise the whirling speed beyond the engine running range using only two bearings instead of the usual three.^[4] Two bearings gave a further advantage: previous engines had also needed a coupling in the shaft to allow for any misalignment between the static parts of the three bearings. With two bearings, the shaft simply followed the straight line between them. So the introduction of the large diameter tube allowed the removal of a bearing, a coupling, the engine's support structure for that bearing together with its lubrication system and cooling air supply.^[4]

A cannular combustor was used with seven flame tubes.^[5] This was a recent development in jet engines and the Orpheus also included the innovation of incorporating the turbine entry duct and its stator vanes into the flame tube outlet, each flame tube providing one seventh of the overall duct.^[5] This had two advantages, it simplified the manufacture of a complicated and unreliable component, also the segmented design allowed easier allowance for thermal expansion.^[5]

Developing a Sea Level Static thrust of 4,520 lbf (20.1 kN ), the Orpheus 701 had a 7-stage axial compressor driven by a single stage turbine.

In 1957 NATO ran a competition for a light fighter design. All three finalists chose the Bristol Orpheus and as a result a substantial contribution towards the cost of the initial engine development was made available from the Mutual Weapons Development Program.^[3] The winner of the competition, the Fiat G.91R and G.91T, used Fiat-built versions of the engine. Other users, mostly trainers, soon followed, including the Fuji T-1, HAL HF-24 Marut, HA-300, and the experimental Hunting H.126 and Short SB5.

For later civilian applications, the Orpheus was chosen, after use of two each on the prototypes, as an option on the Lockheed JetStar, Lockheed's Vice President and head of the famous Skunk Works, Clarence "Kelly" Johnson stating; "These Orpheus engines ... have been the best engines the writer has ever used in a prototype aircraft. They were and are so good that it was decided at an early date to make all Jetstars from serial number two up capable of using two Orpheus engines (as an alternative to four American units). The Orpheus version ... is fully competitive in performance (except with one engine out) and will be offered to those who want its lower cost, simplicity, and - at least for some time - reliability".^[6]

Many companies in the 1950s were looking at ways of producing a vertical take off and landing aircraft. Michel Wibault had the idea of using a turboshaft engine to drive four large centrifugal blowers which could be swivelled to vector the thrust. Hooker's engineers decided on using the Orpheus gas generator to drive a single large fan that would supply air to a pair of rotating nozzles, while the exhaust flow from the Orpheus was split into two and would supply another pair of nozzles at the rear of the engine. This experimental system developed into the Pegasus.

Licences to produce the Orpheus were obtained by Fiat S.p.A., SNECMA and - as the TJ37 - Curtiss-Wright.^[7]

Variants

Data from Jane's All the World's Aircraft 1962-63.,^[8] Aircraft engines of the World 1957^[9]

BOr.1: First run on 17 December 1954, rated at 3,285 lbf (14.61 kN) by Spring 1955, with 4,050 lbf (18.0 kN) for take-off later;powered the prototype Folland Gnat.
BOr.2: 4,520 lbf (20.1 kN) for take-off
BOr.3: 4,850 lbf (21.6 kN) for take-off
BOr.4: 4,230 lbf (18.8 kN) for take-off (de-rated)
BOr.6
BOr.11: Upflowed compressor enabled the BOr.11 to develop 5,760 lbf (25.62 kN)
BOr.12: With a simplified reheat system the BOr.12 was rated at 6,810 lbf (30.29 kN) dry and 8,170 lbf (36.34 kN) with afterburning.
Mk.100: Derated to 4,230 lbf (18.82 kN)
Mk.101
Mk.701: Rated at 4,520 lbf (20.11 kN), the Mk.701 was used in the production Folland Gnat F Mk.1 for Finland and India.
Mk.703: Rated at 4,850 lbf (21.57 kN) ; powered the Hindustan HF-24 Marut Mk.1.
Mk.703R: Reheated Mk.703 rated at 5,720 lbf (25.44 kN) powered the production version of the Hindustan HF-24 Marut. Reheat system developed by Hindustan Aeronautics Limited
Mk.801: Rated at 4,520 lbf (20.11 kN), powering G.91s. The Mk.801 was identical to the BOr.2 engine except for accessories.
Mk.803: With improvements to the compressor, rated at 5,000 lbf (22.24 kN), replaced earlier marks used in G.91s.
Mk.805: de-rated to 4,000 lbf (17.79 kN), powered Fuji T1F1 prototype and T-1A production aircraft, as well as the Hunting H.126 jet-flap research aircraft.
FIAT 4023: Mk.803 engines Licence built by FIAT.
FIAT 4023: Mk.803 engines Licence built by FIAT with added fire detection system.

Applications

Aircraft

Other applications

Orpheus engines, numbers 709 (destroyed by FOD in testing) and 711 (running) powered the Bluebird K7 hydroplane in which Donald Campbell was killed whilst attempting the water speed record on Lake Coniston in 1967.^[10]

A dragster powered by an Orpheus, the "Vampire", is the current holder of the British land speed record.

Engines on display

Preserved Bristol Siddeley Orpheus engines are on display at Aerospace Bristol, at the Midland Air Museum, Coventry, and at Solent Sky, Southampton. One is also preserved as a relic in India's first aerospace museum in Hindustan Aerospace Heritage Centre, Bangalore.

Specifications (Orpheus BOr.3 / Mk.803)

Data fromJane's All the World's Aircraft 1962-63.^[8]

General characteristics

Type: Turbojet:single spool
Length: 75.45 in (1,916 mm)intake flange to exhaust cone
Diameter: 32.4 in (823 mm)
Dry weight: 835 lb (379 kg)

Components

Compressor: 7 stage Axial
Combustors: Can-annular with 7 flame tubes
Turbine: Single stage turbine
Fuel type: Aviation kerosene
Oil system: Pressure spray and metered feed to gearbox and rear bearing. Oil from the rear bearing is lost overboard to the jet efflux.

Performance

Maximum thrust: 5,000 lbf (22 kN)
Overall pressure ratio: 4.4:1
Air mass flow: 84 lb/s (38.10 kg/s)
Turbine inlet temperature: 1,184 °F (640 °C) maximum continuous
Specific fuel consumption: 1.08 lb/(lbf h) (110.1 kg/(kN h))
Thrust-to-weight ratio: 5.988

Notes

↑ This was a design thrust/weight ratio of 6.25:1, whilst earlier engines such as the Derwent and Avon gave 3:1 and the contemporary and lightweight Armstrong Siddeley Viper could only offer 4.9.^[3]

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References

↑ Hooker, Stanley (2002) [1985]. Not much of an engineer. An autobiography. Shrewsbury: Airlife Publishing. p. 161. ISBN 1-85310-285-7.
↑ Hooker (1985) , pp. 162–163
1 2 Hooker (1985) , p. 164
1 2 Hooker (1985) , p. 162
1 2 3 Hooker (1985) , p. 163
↑ "Orpheus: A Versatile and Lightweight Turbojet". Flight . 13 February 1959. pp. 219–223.
↑ "Bristol Orpheus "The Heart of the Gnat"". Flight . 22 November 1957. pp. 809–812.
1 2 Taylor, John W.R. FRHistS. ARAeS (1962). Jane's All the World's Aircraft 1962-63. London: Sampson, Low, Marston & Co.
↑ Wilkinson, Paul H. (1957). Aircraft engines of the World 1957 (15th ed.). London: Sir Isaac Pitman & Sons Ltd. pp. 136–137.
↑ Holter, Steve (2002). Leap Into Legend. Sigma Press. pp. plates facing 119, 135. ISBN 1-85058-794-9.

External links

Flight Global online archive - Detailed description of the Orpheus, November 1957.
"Orpheus" a 1959 Flight article

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Text is available under the CC BY-SA 4.0 license; additional terms may apply.
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[4] This was a design thrust/weight ratio of 6.25:1, whilst earlier engines such as the Derwent and Avon gave 3:1 and the contemporary and lightweight Armstrong Siddeley Viper could only offer 4.9.^[3]

[1] Hooker, Stanley (2002) [1985]. Not much of an engineer. An autobiography. Shrewsbury: Airlife Publishing. p. 161. ISBN 1-85310-285-7.

[2] Hooker (1985) , pp. 162–163

[Hooker,_164-3] 1 2 Hooker (1985) , p. 164

[Hooker,_162-5] 1 2 Hooker (1985) , p. 162

[Hooker,_163-6] 1 2 3 Hooker (1985) , p. 163

[7] "Orpheus: A Versatile and Lightweight Turbojet". Flight . 13 February 1959. pp. 219–223.

[8] "Bristol Orpheus "The Heart of the Gnat"". Flight . 22 November 1957. pp. 809–812.

[JAWA62-63-9] 1 2 Taylor, John W.R. FRHistS. ARAeS (1962). Jane's All the World's Aircraft 1962-63. London: Sampson, Low, Marston & Co.

[AEotW57-10] Wilkinson, Paul H. (1957). Aircraft engines of the World 1957 (15th ed.). London: Sir Isaac Pitman & Sons Ltd. pp. 136–137.

[11] Holter, Steve (2002). Leap Into Legend. Sigma Press. pp. plates facing 119, 135. ISBN 1-85058-794-9.

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