Rolls-Royce Clyde

RB.39 Clyde
	Rolls-Royce Clyde on display at the Rolls-Royce Heritage Trust, Derby
Type	Turboprop
Manufacturer	Rolls-Royce Limited
First run	5 August 1945
Number built	9

Last updated January 19, 2024

The Rolls-Royce RB.39 Clyde was Rolls-Royce's first purpose-designed turboprop engine and the first turboprop engine to pass its civil and military type-tests.^[2]^[3]

Design and development

The Clyde used a two-shaft design, with an axial compressor based on that of the Metrovick F.2 ^[4]^[5] for the low-pressure section, and a single-sided centrifugal compressor scaled up from the Merlin 46 supercharger^[6] as the high-pressure stage, both mounted on the HP shaft and driven by a single stage HP turbine. A single stage power turbine drove the front mounted propeller reduction gearbox via the concentric LP shaft. A fairly novel feature of this compact gearbox was the power output to contra-rotating propellers.^[7]

The Clyde was a long engine with the axial LP compressor in front of what was, in effect, a scaled-down Derwent engine. Accessories were grouped around the axial compressor which conveniently narrowed towards the rear. Cooling for turbines and turbine bearings came from a small impeller on the main shaft as well as air taken from the axial and centrifugal compressors. Testing of the development engines exceeded expectations with the engine soon being rated at 4,030 eshp.^[5]^[1] During testing potentially destructive vibrations were found originating in the straight-cut spur gears in the reduction gearbox.^[1]

The engine was selected as the main engine of the Westland Wyvern TF Mk.2 strike aircraft.^[2] However, despite the promising performance of the test engines Ernest Hives felt that pure-jets such as the Avon were the future and the Clyde programme was terminated, forcing Westland to use the less than satisfactory Armstrong Siddeley Python on the production Wyverns.^[2] and so Rolls-Royce's first production turboprop would be the Dart.

Engines on display

A part sectioned example is on display at the Rolls-Royce Heritage Trust, (Derby).

Specifications (Clyde)

Data fromTurbojet History and Development 1930-1960 vol.1.^[1]

General characteristics

Type: Two-Shaft Turboprop
Length: 121.2 in (3,080 mm)
Diameter: 46.8 in (1,190 mm)
Dry weight: 2,800 lb (1,300 kg) (dry)

Components

Compressor:LP - 9 stage axial, HP - Single centrifugal stage
Combustors: Eleven can-type combustion chambers
Turbine:'HP - single stage axial, Power - single stage axial
Fuel type: Kerosene (jet fuel grade)e
Oil system: Pressure spray scavenge system

Performance

Maximum power output: 4,030 eshp (3,006 kW)
Overall pressure ratio: 6:1
Air mass flow: 41.5 lb (18.8 kg)/s
Specific fuel consumption: 0.71 lb/hp/hr (0.432 kg/kW/hr)
Power-to-weight ratio: 1.439 eshp/lb (2.09 kW/kg)

Related Research Articles

<span class="mw-page-title-main">Bristol Theseus</span> 1940s British turboprop aircraft engine

The Theseus was the Bristol Aeroplane Company's first attempt at a gas-turbine engine design. A turboprop delivering just over 2,000 hp (1,500 kW) was chosen rather than compete with companies that were already developing turbojets. A heat exchanger to transfer waste heat from the exhaust to the compressor exit was necessary to meet a requirement for a fuel consumption comparable to a piston engine. However, the heat exchanger was abandoned after tests showed that it had a high pressure loss and only produced a fuel saving of 8%. Furthermore overall performance was reduced

<span class="mw-page-title-main">Bristol Proteus</span> 1940s British turboprop aircraft engine

The Bristol Proteus was the Bristol Engine Company's first mass-produced gas turbine engine design, a turboprop that delivered just over 4,000 hp (3,000 kW). The Proteus was a reverse-flow gas turbine. Because the second turbine drove no compressor stages, but only the propeller, this engine was classified as a free-turbine. It powered the Bristol Britannia airliner, small naval patrol craft, hovercraft and electrical generating sets. It was also used to power a land-speed record car, the Bluebird-Proteus CN7. After the merger of Bristol with Armstrong Siddeley the engine became the Bristol Siddeley Proteus, and later the Rolls-Royce Proteus. The Proteus was to have been superseded by the Bristol Orion which would have given a Britannia a 75% increase in power for cruising faster.

The Rolls-Royce RB.44 Tay is a British turbojet engine of the 1940s, an enlarged version of the Rolls-Royce Nene designed at the request of Pratt & Whitney. It saw no use by British production aircraft but the design was licence built by Pratt & Whitney as the J48, and by Hispano-Suiza as the Verdon.

The Rolls-Royce RB.37 Derwent is a 1940s British centrifugal compressor turbojet engine, the second Rolls-Royce jet engine to enter production. It was an improved version of the Rolls-Royce Welland, which itself was a renamed version of Frank Whittle's Power Jets W.2B. Rolls-Royce inherited the Derwent design from Rover when they took over their jet engine development in 1943.

The Klimov VK-1 was the first Soviet jet engine to see significant production. It was developed by Vladimir Yakovlevich Klimov and first produced by the GAZ 116 works. Derived from the Rolls-Royce Nene, the engine was also built under licence in China as the Wopen WP-5.

The General Electric J31 was the first jet engine to be mass-produced in the United States.

The Bristol Orion aero engine is a two-shaft turboprop intended for use in later marks of the Bristol Britannia and the Canadair CL-44. Although the engine was built and underwent a development program, the BE.25 Orion project was cancelled in 1958 by the British Ministry of Supply in favour of the Rolls-Royce Tyne. In addition, interest in turboprop-powered aircraft was beginning to wane, because of the successful introduction of the Boeing 707 and Douglas DC-8 jetliners into airline service.

<span class="mw-page-title-main">Rolls-Royce Gnome</span> 1950s British turboshaft aircraft engine

The Rolls-Royce Gnome is a British turboshaft engine originally developed by the de Havilland Engine Company as a licence-built General Electric T58, an American mid-1950s design. The Gnome came to Rolls-Royce after their takeover of Bristol Siddeley in 1968, Bristol having absorbed de Havilland Engines Limited in 1961.

<span class="mw-page-title-main">Bristol Siddeley Nimbus</span> 1950s British turboshaft aircraft engine

The Bristol Siddeley Nimbus, later known as the Rolls-Royce Nimbus, was a British turboshaft engine developed under license by Blackburn Aircraft Ltd. from the Turbomeca Turmo in the late 1950s. It was used on the Westland Scout and Westland Wasp helicopters.

The Rolls-Royce Gem is a turboshaft engine developed specifically for the Westland Lynx helicopter in the 1970s. The design started off at de Havilland Engine division and passed to Bristol Siddeley as the BS.360. Rolls-Royce bought out Bristol Siddeley in 1966 and after it dropped the Bristol Siddeley identity the engine became the RS.360.

<span class="mw-page-title-main">Armstrong Siddeley Python</span>

The Armstrong Siddeley Python was an early British turboprop engine designed and built by the Armstrong Siddeley company in the mid-1940s. Its main use was in the Westland Wyvern, a carrier-based heavy fighter. The prototypes had used the Rolls-Royce Eagle piston engine, but Pythons were used in production aircraft. In this application, the Python was rated at 4,110 equivalent shaft horsepower (eshp).

The Allison Model 250, now known as the Rolls-Royce M250, is a highly successful turboshaft engine family, originally developed by the Allison Engine Company in the early 1960s. The Model 250 has been produced by Rolls-Royce since it acquired Allison in 1995.

<span class="mw-page-title-main">Rolls-Royce RB.50 Trent</span> 1940s British turboprop aircraft engine

The Rolls-Royce RB.50 Trent was the first Rolls-Royce turboprop engine.

The Turbomeca Astazou is a highly successful series of turboprop and turboshaft engines, first run in 1957. The original version weighed 110 kg (243 lb) and developed 240 kW (320 shp) at 40,000 rpm. It was admitted for aviation service on May 29, 1961, after a 150-hour test run. The main developing engineer was G. Sporer. It was named after two summits of the Pyrenees.

The Turbomeca Turmo is a family of French turboshaft engines manufacturered for helicopter use. Developed from the earlier Turbomeca Artouste, later versions delivered up to 1,300 kW (1,700 shp). A turboprop version was developed for use with the Bréguet 941 transport aircraft.

The Napier Eland is a British turboshaft or turboprop gas-turbine engine built by Napier & Son in the early 1950s. Production of the Eland ceased in 1961 when the Napier company was taken over by Rolls-Royce.

The Allison T40, company designation Allison Model 500, was an early American turboprop engine composed of two Allison T38 power sections driving a contra-rotating propeller via a common gearbox.

The General Electric T31 was the first turboprop engine designed and built in the United States.

The Allison T38 was an early turboprop engine developed by Allison Engine Company during the late 1940s. The T38 became the basis for the very successful family of Allison T56 turboprop engine.

The Power Jets WU was a series of three very different experimental jet engines produced and tested by Frank Whittle and his small team in the late 1930s.

References

Notes

1 2 3 4 Kay, Anthony L. (2007). "14". Turbojet History and Development 1930-1960 vol.1 (1st ed.). Marlborough: The Crowood Press. pp. 105–118. ISBN 978-1-86126-912-6.
1 2 3 4 Gunston, Bill (2006). World Encyclopedia of Aero Engines (5th ed.). Stroud: Sutton Publishing. pp. 194–195. ISBN 0-7509-4479-X.
↑ Flight 1954, p. 582.
↑ McKenzie, A. (2001). Axial Compressor Development at Rolls-Royce Derby, 1946–1962. Rolls-Royce Heritage Trust. pp. 10, 23. ISBN 978-1-872922-42-3. Technical Series Nº11.
1 2 "World Encyclopedia of Aero Engines – 5th edition" by Bill Gunston, Sutton Publishing, 2006, P.195
↑ Feilden, G. B. R. (2005). "Lionel Haworth. 4 August 1912 — 12 April 2000". Biographical Memoirs of Fellows of the Royal Society. 51: 195–220. doi:10.1098/rsbm.2005.0013. S2CID 60786773.
↑ "Not much of an Engineer" by Sir Stanley Hooker, Airlife Publishing Ltd, 1984, P.227

Bibliography

Gunston, Bill. World Encyclopedia of Aero Engines. Cambridge, England. Patrick Stephens Limited, 1989. ISBN 1-85260-163-9
Kay, Anthony L. (2007). "14". Turbojet History and Development 1930-1960 vol.1 (1st ed.). Marlborough: The Crowood Press. pp. 105–118. ISBN 978-1-86126-912-6.
King, H. F. "The Two R's: A Commemorative History of Rolls-Royce Aero Engines. (article and images)." Flight No. 2363, Volume 65, 7 May 1954.

This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.

[Kay-1] 1 2 3 4 Kay, Anthony L. (2007). "14". Turbojet History and Development 1930-1960 vol.1 (1st ed.). Marlborough: The Crowood Press. pp. 105–118. ISBN 978-1-86126-912-6.

[Gunston_WEoAE-2] 1 2 3 4 Gunston, Bill (2006). World Encyclopedia of Aero Engines (5th ed.). Stroud: Sutton Publishing. pp. 194–195. ISBN 0-7509-4479-X.

[3] Flight 1954, p. 582.

[4] McKenzie, A. (2001). Axial Compressor Development at Rolls-Royce Derby, 1946–1962. Rolls-Royce Heritage Trust. pp. 10, 23. ISBN 978-1-872922-42-3. Technical Series Nº11.

[Sutton_Publishing_2006,_P.195-5] 1 2 "World Encyclopedia of Aero Engines – 5th edition" by Bill Gunston, Sutton Publishing, 2006, P.195

[6] Feilden, G. B. R. (2005). "Lionel Haworth. 4 August 1912 — 12 April 2000". Biographical Memoirs of Fellows of the Royal Society. 51: 195–220. doi:10.1098/rsbm.2005.0013. S2CID 60786773.

[7] "Not much of an Engineer" by Sir Stanley Hooker, Airlife Publishing Ltd, 1984, P.227

[1]

[2]

[3]

[4]

[5]

[6]

[7]