Rolls-Royce Olympus

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The Olympus is a high-powered axial-flow turbojet aircraft engine, originally developed and produced by Bristol Aero Engines (hence the name from Greek mythology, a long time tradition of the company), later passed to Bristol Siddeley, and finally to Rolls-Royce. The original design was used as the powerplant for the Avro Vulcan V Bomber. It was later developed for sustained supersonic performance as part of the TSR-2 program, and when this was cancelled was used as the powerplant for Concorde. The engine is still in production for industrial and naval power. Curtiss-Wright in the USA built a licensed version as the J67.

Contents 1 Bristol Siddeley Olympus (Vulcan) 2 Bristol Siddeley Olympus Versions 3 Rolls-Royce Olympus TM3B marine turbine 4 Rolls-Royce/Snecma Olympus 593 4.1 Specifications 5 Rolls-Royce/Snecma Olympus Versions 6 References 7 See also

[edit] Bristol Siddeley Olympus (Vulcan)

The Olympus was first run in 1950 reaching 10,000 lbf (44 kN) thrust. In 1953 it was test flown in an English Electric Canberra aircraft. Entering full production in 1955, the Olympus continued to be developed by Bristol Siddeley. The Olympus 101 entered service on the Avro Vulcan Mk.1 in 1956, to be followed by the 102 and 104.

The 106 was a development engine for the 201. The Avro Vulcan Mk.2 was the first to use the Olympus 201.

By modifications to the LP compressor (which included adding an extra LP stage) and the LP turbine, the thrust was increased from the 17,000 lbf (76 kN) of the Olympus 201 to 20,000 lbf (89 kN). The new engine was known as the Olympus 301. Due to the increased air mass, the Vulcan's air intakes had to be widened and, because of the extra compressor stage, the engines were larger and would not fit into the engine bays without extensive modifications

[edit] Bristol Siddeley Olympus Versions

• 201 Series - 17,000 lbf (76 kN)
• 301 Series - 20,000 lbf (89 kN)
• Olympus 22R Mk.320 - 19,610 lb dry, 30,610 lb with reheat for use in the TSR-2

[edit] Rolls-Royce Olympus TM3B marine turbine

A marine version of the Olympus was trialled in the refitted Royal Navy frigate HMS Exmouth which became the first major warship in a western navy to be powered by gas turbine engines - conversion taking from 1966-1968. The Olympus was subsequently used for the Type 21 frigates and the sole Type 82 destroyer, HMS Bristol (TM1A).

The Rolls-Royce Olympus powers the following naval vessels:

• Royal Navy
  • Invincible class aircraft carriers — 4 turbines each
  • Type 42 destroyers — 2 Olympus and 2 Tyne
  • Type 22 frigates Batch 1 and 2; 2 Olympus and 2 Tyne

• French Navy
  • Georges Leygues class destroyer
• Belgian Navy
  • Wielingen class frigates
• Royal Netherlands Navy
  • GW-class frigate (Guided Missile class - De Ruijter class frigate)
  • S-class frigate (Standard - Kortenaer)
  • L-class frigate (Air Defence class - Heemskerk class frigate)
• Finnish Navy
  • Turunmaa class corvettes
• Japan Maritime Self Defense Force
  • Ishikari class destroyer

[edit] Rolls-Royce/Snecma Olympus 593

Until Concorde regular commercial flights ceased the Olympus turbojet was unique in commercial aviation as the only afterburning turbojet powering a commercial aircraft. The Olympus 593 project was started in 1964, using the BAC TSR2's Olympus 320 as a basis for development. Bristol Siddeley of the UK and Snecma Moteurs of France were to share the project. Acquiring Bristol Siddeley in 1966, Rolls-Royce continued as the British partner. The early stages validated the basic design concept but many studies were required to achieve desired specifications, e.g.

• The critical factor – fuel consumption
• Pressure Ratio
• Weight/Size
• Turbine entry temperature

The British carried out the development of the original Bristol Siddeley Olympus and engine accessories, while Snecma had responsibility for variable engine inlet system, the exhaust nozzle/thrust reverser, the afterburner and the noise attenuation system. Britain was to have a larger share in production of the Olympus 593 as France had a larger share in fuselage production.

A jet engine draws air in at the front and compresses it. The air then combines with fuel and the engine burns the resulting mixture. The combustion greatly increases the volume of the gases which are then exhausted out of the rear of the engine. The Olympus engine takes this gas jet and passes it through straightening vanes - to obtain a laminar flow. This gas jet then enters the afterburning jet pipe where a ring of fuel injectors spray fuel onto the hot exhaust gases. The resulting combustion greatly improves thrust, although it can also lead to excessively high fuel consumption. The afterburning section was longer than the engine itself (as was the case with all early turbojets) but the thrust of the Olympus 302 rose to 30,610 lbf (136 kN).

The variable geometry exhaust nozzle is two "eyelids" which vary their position in the exhaust flow dependent on the flight regime, for example when fully closed (into the exhaust flow) they act as thrust reversers, aiding deceleration from landing to taxi speed.

The variable engine inlet system was vital to the Olympus 593 on Concorde as supersonic airflow at the engine face would create shockwaves that would lead to engine surge and failure. The intake features variable ramps which alter the intake area which slows the intake air from supersonic to subsonic speed. This is achieved by positioning the ramps such that shockwaves are created at the inlet, air passing through these shockwaves is slowed. The inlet air is further decelerated as the intake area increases closer to the engine (speed of air flow decreases as area increases.) Any excess air is expelled through doors on the underside of the nacelle and some intake air bypassed around the engine and mixed with the exhaust - to increase thrust and keep the engine cool. The TSR-2 had used a semicircular design with the shock front adjusted by a translating centrebody.^[1]

In June 1966 a complete Olympus 593 engine and variable geometry exhaust assembly was first run at Melun-Villaroche, Île-de-France, France. At Bristol, flight tests began using a RAF Vulcan bomber with the engine attached to its underside. Due to the Vulcan's aerodynamic limitations the tests were limited to a speed of Mach 0.98 (1,200 km/h). During these tests the 593 achieved 35,190 lbf (157 kN) thrust, which exceeded the requirements of the engine.^[2]

In April 1967 the Olympus 593 ran for the first time in a high altitude chamber, at Saclay Île-de-France, France. In January 1968 the Vulcan flying test bed logged 100 flight hours, and the variable geometry exhaust assembly for the Olympus 593 engine was cleared at Melun-Villaroche for flight in the Concorde prototypes.

At 15:40 on the 2nd March 1969 Concorde prototype 001, captained by chief test pilot Andre Turcat, started its first take off run, with afterburners lit. The four Olympus 593 engines accelerated the aircraft, and after 4,700 feet (1.4 km) of runway and at a speed of 205 knots (380 km/h), captain Turcat lifted the aircraft off for the first time.

[edit] Specifications

General characteristics

• Type: axial flow afterburning turbojet
• Length: 7112 mm
• Diameter: 1212 mm
• Dry weight: 3175 kg

Components

• Compressor: axial 7 low pressure stages, 7 high pressure stages
• Combustors: nickel alloy construction 16 fuel injectors mounted at head, each with twin outlets
• Turbine: high pressure single stage, low pressure single stage

Performance

• Thrust: 169.2 kN
• Overall pressure ratio: 15.5:1
• Specific fuel consumption: 1.195 (cruise), 1.39 SL ^[3]
• Power-to-weight ratio:

Control system

• world's first FADEC control system

Jetpipe

• straight pipe with pneumatically operated convergent nozzle
• single ring afterburner
• 'eyelids' which act as variable divergent nozzles/thrust reversers

[edit] Rolls-Royce/Snecma Olympus Versions

• 593 - Original version designed for Concorde
  • Thrust : 20,000 lbf (89 kN) dry / 30,610 lbf (136 kN) reheat
• 593-22R - Powerplant fitted to prototypes. Higher performance than original engine due to changes in aircraft specification.
  • Thrust : 34,650 lbf (154 kN) dry / 37,180 lbf (165 kN) reheat
• 593-610-14-28 - Final version fitted to production Concorde
  • Thrust : 32,000 lbf (142 kN) dry / 38,050 lbf (169 kN) reheat

[edit] References

1. ^ Ausair power Accessed 19 Feb 2007
2. ^ Testing of Concorde's engine on a Vulcan
3. ^ untitled

• http://www.janes.com/transport/news/jae/jae000725_1_n.shtml

[edit] See also

• List of aircraft engines

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