Napier Oryx

Last updated

Oryx
NapierOryx.JPG
Napier Oryx at the Science Museum (London)
Type Gas turbine gas generator
Manufacturer Napier & Son
First runNovember 1953
Major applications Percival P.74

The Napier Oryx was a British gas-turbine engine designed and built by Napier in the early 1950s for the Percival P.74 tip jet-powered helicopter project. The P.74 was unsuccessful and it and the Oryx were cancelled. [1]

Contents

Design and development

The engine was developed by the Aero Gas Turbine Division of Napier in conjunction with Percival, later Hunting Percival. Funding came from the Ministry of Supply.

The Percival P.74 was a design for a tipjet-powered helicopter. The jet power was to be supplied from engines within the helicopter and piped to the rotor tips. Napier developed the Oryx specifically to power the P.74. [2]

The output gas temperature from the engines had to be below 400 °C for the helicopter's stainless steel rotor ducts, so a bypass design was used. This also blew "cold" air from the compressor, rather than purely hot turbine exhaust gas. In order to give a compact installation, rather than using an oversized compressor with a bypass around the turbine (as commonly used in the turbofan engine), the Oryx used an auxiliary compressor coupled to the turbine. This was mounted behind the turbine, with its gas flow in the opposite direction to the main engine core. [2] The two gas streams were deflected through 90° in a collector chamber, then exited vertically upwards. Gas flow through this collector was arranged so that each stream remained separate, the cold air from the auxiliary compressor passing through a bifurcated duct, so as to wrap around the hotter turbine outlet. By this means, the duct was further protected from the hot exhaust. Separator plates inside each duct split the stream into a number of flows and deflected each one separately, thus preserving the flows approximately constant across the whole duct. When the flows finally merged, they were flowing parallel and at approximately the same velocity, thus reducing turbulence and energy loss.

A starting valve, consisting of a Corliss non-throttling rotating valve in combination with a butterfly valve (closed in flight), [2] [note 1] could divert individual engine output to the outside of the aircraft, permitting engine starting and ground running with the rotor stationary. Without the valve, back pressure in the duct and rotor system would prevent the starting of the engine. [2] In the P.74 the two Oryx engines fed their outputs to a common duct that took the thrust to the rotor head.

Development of the engine began in 1951. [2] The engine was designed with a 12-stage axial flow compressor less than nine inches (19 cm) in diameter and a set of nine tie rods around the periphery of the compressor discs linking them together. [2] Air from the compressor was fed to an array of five tubular combustion chambers, with the resulting hot gas driving a two-stage turbine connected to the four-stage auxiliary compressor via geared couplings. The first Oryx prototype engine was started for the first time in November 1953 and about 1,400 hours of test running had been achieved by the end of July 1955. The Oryx was expected to be used for the planned commercial P.105 development of the P.74. In the P.105 the two engines would have been fitted back to front on either side of the rotor mast, feeding their outputs to the rotor hub. It was anticipated that 900 "gas horsepower" could be produced in its developed form. [2]

The Percival P.74 with the port Oryx engine cover removed Percival p-74.jpg
The Percival P.74 with the port Oryx engine cover removed

Variants

E.146 Oryx
Company designation.
NOr.1
Ministry of Supply (MoS) designation for the first variant.
NOr.5
MoS designation for the fifth variant; 950 hp (710 kW) gas hp at 22,600 rpm for take-off at sea level. [3]

Engines on display

A preserved Napier Oryx is on display at the Science Museum (London).

Specifications (Oryx N.Or.1)

Data from Flight and Aircraft Engines of the World 1957. [2] [3]

General characteristics

Components

Performance

See also

Notes

  1. A typical "butterfly" valve restricts flow somewhat, even when completely open

Related Research Articles

Napier Nomad

The Napier Nomad was a British diesel aircraft engine designed and built by Napier & Son in 1949. They combined a piston engine with a turbine to recover energy from the exhaust and thereby improve fuel economy. Two versions were tested, the complex Nomad I which used two propellers, each driven by the mechanically independent stages, and the Nomad II, using the turbo-compound principle, coupled the two parts to drive a single propeller. The Nomad II had the lowest specific fuel consumption figures seen up to that time. Despite this the Nomad project was cancelled in 1955 having spent £5.1 million on development, as most interest had passed to turboprop designs.

Pratt & Whitney Canada PT6 Turboprop aircraft engine family by Pratt & Whitney Canada

The Pratt & Whitney Canada PT6 is a turboprop aircraft engine produced by Pratt & Whitney Canada. Its design was started in 1958, it first ran in February 1960, first flew on 30 May 1961, entered service in 1964 and has been continuously updated since. It consists of two basic sections: a gas generator with accessory gearbox and a free power turbine with reduction gearbox, and is often seemingly mounted backwards in an aircraft in so far as the intake is at the rear and the exhaust at the front. Many variants of the PT6 have been produced, not only as turboprops but also for helicopters, land vehicles, hovercraft, boats, as auxiliary power units and for industrial uses. By November 2015, 51,000 had been produced, had logged 400 million flight hours from 1963 to 2016. It is known for its reliability with an in-flight shutdown rate of 1 per 651,126 hours in 2016. The PT6A covers the power range between 580 and 1,940 shp while the PT6B/C are turboshaft variants for helicopters.

General Electric TF39 Turbofan aircraft engine

The General Electric TF39 was a high-bypass turbofan engine that was developed to power the Lockheed C-5 Galaxy. The TF39 was the first high-power, high-bypass jet engine developed. The TF39 was further developed into the CF6 series of engines, and formed the basis of the General Electric LM2500 marine and industrial gas turbine. On September 7, 2017, the last active C-5A powered with TF39 engines made its final flight to Davis-Monthan Air Force Base for retirement. The TF39 was effectively retired, and all remaining active C-5 Galaxys are now powered by General Electric F138-GE-100 (CF6) engines.

The Soloviev D-25V is a Soviet gas-turbine turboshaft engine for use in large helicopters. Designed and originally manufactured by the Soloviev Design Bureau the engine has been in production since May 1960. The power unit consists of two engines coupled to a gearbox weighing 3,200 kg (7,050 lb).

Rolls-Royce Gnome

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.

Bristol Siddeley Nimbus

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.

Allison Model 250 Turboshaft aircraft engine

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.

Napier Eland

The Napier Eland was 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.

Percival P.74

The Percival P.74 was a British experimental helicopter designed in the 1950s that was based on the use of tip-jet powered rotors. Although innovative, the tip-rotor concept literally failed to get off the ground in the P.74, doomed by its inadequate power source. Rather than being modified, the P.74 was towed off the airfield and scrapped.

General Electric T64 Turboshaft engine

The General Electric T64 is a free-turbine turboshaft engine that was originally developed for use on helicopters, but which was later used on fixed-wing aircraft as well. General Electric introduced the engine in 1964. The original engine design included technical innovations such as corrosion resistant and high-temperature coatings. The engine features a high overall pressure ratio, yielding a low specific fuel consumption for its time. Although the compressor is all-axial, like the earlier General Electric T58, the power turbine shaft is coaxial with the HP shaft and delivers power to the front of the engine, not rearwards. Fourteen compressor stages are required to deliver the required overall pressure ratio. Compressor handling is facilitated by 4 rows of variable stators. Unlike the T58, the power turbine has 2 stages.

Lycoming T55

The Lycoming T55 is a turboshaft engine used on American helicopters and fixed-wing aircraft since the 1950s. It was designed at the Lycoming Turbine Engine Division in Stratford, Connecticut, as a scaled-up version of the smaller Lycoming T53. Both engines are now produced by Honeywell Aerospace. The T55 also serves as the core of the Lycoming ALF 502 turbofan. Since the T55 was first developed, progressive increases in airflow, overall pressure ratio, and turbine inlet temperature have more than tripled the power output of the engine.

Boeing T50

The Boeing T50 was a small turboshaft engine produced by Boeing. Based on Boeing's earlier Model 500 gas generator, the T50's main application was in the QH-50 DASH helicopter drone of the 1950s. An up-rated version designated Model 550 was developed to power the QH-50D and was given the military designation T50-BO-12.

Turbomeca Palouste

The Turbomeca Palouste is a French gas turbine engine, first run in 1952. Designed purely as a compressed air generator, the Palouste was mainly used as a ground-based aircraft engine starter unit. Other uses included rotor tip propulsion for helicopters.

The Fiat 4700 was an Italian turbo-generator developed by Fiat Aviazione under contract to the Italian Defence Ministry and used to power the experimental Fiat 7002 tip jet helicopter.

Sud-Ouest Ariel

The Sud-Ouest Ariel is a French two-seat light helicopter designed and built by Sud-Ouest. The helicopter rotors were driven by compressed-air jets at the end of each blade.

Klimov GTD-350

The Klimov GTD-350 is a Soviet gas-turbine turboshaft engine intended for helicopter use. Designed in the early 1960s by the Isotov Design Bureau the engine was later produced by Klimov and PZL, production ending in the late 1990s.

The Daimler-Benz DB 007,, was an early German jet engine design stemming from design work carried out by Karl Leist from 1939. This was a complex design featuring contra-rotating stages and a bypass fan, making it one of the earliest turbofan designs to be produced. The end result of the design work was built as the DB 007 and began testing on a test-bed on 27 May 1943. Due to the expected low performance, complexity and the good results achieved by much simpler designs, work was halted on the DB 007 in May 1944 by order of the RLM.

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.

Free-turbine turboshaft

A free-turbine turboshaft is a form of turboshaft or turboprop gas turbine engine where the power is extracted from the exhaust stream of a gas turbine by an independent turbine, downstream of the gas turbine and is not connected to the gas turbine. This is opposed to the power being extracted from the power spool via a gear box.

The Turbomeca Turmo I is a turboshaft engine designed and built in France during the 1950s, which was developed into the Turbomeca Turmo III series of turboshaft / turboprop engines.

References

  1. Gunston, Bill (1989). World Encyclopedia of Aero Engines. Cambridge: Patrick Stephens. p. 107. ISBN   1-85260-163-9. The less said about the Oryx the better
  2. 1 2 3 4 5 6 7 8 "Napier Oryx". Flight and Aircraft Engineer. 68 (2428): 189–193.
  3. 1 2 Wilkinson, Paul H. (1957). Aircraft Engines of the World 1957 (15th ed.). London: Sir Isaac Pitman & Sons Ltd. p. 59.