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1. Turbos to Create A Jet P M V Subbarao
Professor
Mechanical Engineering Department
2. The Concept of Turbo Technology A control volume based engine to create Jet.
Turbo-machinery execute -vdp work.
Force or torque is generated with steady flow.
Continuous transfer & conversion of energy is possible at steady flow and steady state.
Basic Architecture is:
3. Open Cycle Using Turbos
4. Necessity is the Mother of Invention !?!?!??!
5. Gas Turbine Technology 1791: A patent was given to John Barber, an Englishman, for the first true gas turbine.
His invention had most of the elements present in the modern day gas turbines.
The turbine was designed to power a horseless carriage.
1872: The first true gas turbine engine was designed by Dr Franz Stikze, but the engine never ran under its own power.
1903: A Norwegian, Ćgidius Elling, was able to build the first gas turbine that was able to produce more power than needed to run its own components, which was considered an achievement in a time when knowledge about aerodynamics was limited.
Using rotary compressors and turbines it produced 11 hp (massive for those days).
He further developed the concept, and by 1912 he had developed a gas turbine system with separate turbine unit and compressor in series, a combination that is now common.
6. 1914: Application for a gas turbine engine filed by Charles Curtis.
1918: One of the leading gas turbine manufacturers of today, General Electric, started their gas turbine division.
1920: The practical theory of gas flow through passages was developed into the more formal (and applicable to turbines) theory of gas flow past airfoils by Dr A. A. Griffith.
7. THE WORLD‘S FIRST INDUSTRIAL GAS TURBINE SET – GT NEUCHÂTEL
8. 4 MW GT for Power Generation
9. Gas Turbine Power Generation Experience gained from a large number of exhaust-gas turbines for diesel engines, a temp. of 538°C was considered absolutely safe for uncooled heat resisting steel turbine blades.
This would result in obtainable outputs of 2000-8000 KW with compressor turbine efficiencies of 73-75%, and an overall cycle efficiency of 17-18%.
First Gas turbine electro locomotive 2500 HP ordered from BBC by Swiss Federal Railways.
The advent of high pressure and temperature steam turbine with regenerative heating of the condensate and air pre-heating, resulted in coupling efficiencies of approx. 25%.
The gas turbine having been considered competitive with steam turbine plant of 18% which was considered not quite satisfactory.
10. A Death Leading to New Life The Gas turbine was unable to compete with “modern” base load steam turbines of 25% efficiency.
There was a continuous development in steam power plant which led to increase of Power Generation Efficiencies of 35%+
This hard reality required consideration of a different application for the gas turbine.
1930: Sir Frank Whittle patented the design for a gas turbine for jet propulsion.
11. Turbojets As invented by Hans Von Ohain &Frank Whittle.
Typical Turbojet
Schematics
12. Turbojets - Basic Operating Features Five basic components:
intake: captures air and efficiently delivers it to compressor.
compressor: increases air pressure and temperature.
combustor: adds kerosene to the air and burns the mixture to increase the temperature and energy levels further.
turbine: extracts energy from the gases to drive the compressor via a shaft.
nozzle: accelerates the gases further.
High levels of engineering required for efficient operation, especially for compressor and turbine - therefore costly compared with rocket.
13. World's first operational jet engine Dimensions: 1.48 m long, 0.93 m diameter
Weight: 360 kg
Thrust: 450 kgf (4.4 kN) @ 13,000 rpm and 800 km/h
Compression ratio: 2.8:1
Specific fuel consumption: 2.16 gal/(lb·h) [18.0 L/(kg·h)]
14. World's first Aircraft : He178 General characteristics
Crew: One
Length: 7.48 m (24 ft 6 in)
Wingspan: 7.20 m (23 ft 3 in)
Height: 2.10 m (6 ft 10 in)
Wing area: 9.1 m˛ (98 ft˛)
Empty weight: 1,620 kg (3,572 lb)
Max takeoff weight: 1,998 kg (4,405 lb)
Powerplant: 1× HeS 3 turbojet, 4.4 kN (992 lbf)
Performance
Maximum speed: 698 km/h (380 mph)
Range: 200 km (125 mi)
15. Present Turbojet Engines The Rolls-Royce/Snecma Olympus 593 was a reheated (afterburning) turbojet which powered the supersonic airliner Concorde.
General characteristics
Type: Turbojet
Length: 4039 mm (159 in)
Diameter: 1212 mm (47.75 in)
Dry weight: 3175 kg (7,000 lb)
16. Components
Compressor: Axial flow, 7-stage low pressure, 7-stage high pressure
Combustors: Nickel alloy construction annular chamber, 16 vapourising burners, each with twin outlets
Turbine: High pressure single stage, low pressure single stage
Fuel type: Jet A1
Performance
Maximum Thrust: 169.2 kN (38,050 lbf)
17. Overall pressure ratio: 15.5:1
Specific fuel consumption: 1.195 (cruise), 1.39 (SL) lb/(h·lbf)
Thrust-to-weight ratio: 5.4
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Turbojets for Guided Weapons
19. Harpoon : General Characteristics Primary function: Air-, surface-, or submarine-launched anti-surface (anti-ship) missile
Contractor: The McDonnell Douglas Astronautic Company - East
Power plant: Teledyne Teledyne J402 turbojet, 660 lb (300 kg)-force (2.9 kN) thrust, and a solid-propellant booster for surface and submarine launches.
Length:
Air launched: 3.8 metres (12 ft) 7 in)
Surface and submarine launched: 4.6 metres (15 ft)
20. Weight:
Air launched: 519 kilograms (1,140 lb)
Submarine or ship launched from box or canister launcher: 628 kilograms (1,380 lb)
Diameter: 340 millimetres (13 in)
Wing span: 914 millimetres (36.0 in)
Maximum altitude: 910 metres (3,000 ft) with booster fins and wings
21. Range: Over-the-horizon (approx 50 nautical miles)
AGM-84D: 220 km (120 nmi)
RGM/UGM-84D: 140 km (75 nmi)
AGM-84E: 93 km (50 nmi)
AGM-84F: 315 km (170 nmi)
AGM-84H/K: 280 km (150 nmi)
Speed: High subsonic, around 850 km/h (460 knots, 240 m/s, or 530 mph)
22. Guidance: Sea-skimming cruise monitored by radar altimeter, active radar terminal homing
Warhead: 221 kilograms (490 lb), penetration high-explosive blast
Unit cost: US$720,000
