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Gas Power Cycle - Jet Propulsion Technology, A Case Study

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Presentation on theme: "Gas Power Cycle - Jet Propulsion Technology, A Case Study"— Presentation transcript:

1 Gas Power Cycle - Jet Propulsion Technology, A Case Study

2 Ideal Brayton Cycle Fuel Combustor 1-2 Isentropic compression
2-3 Constant pressure heat addition 3-4 Isentropic expansion 4-1 Constant pressure heat rejection 3 2 Compressor 4 Air 1 Turbine Products P 3 3 2 T 2 4 1 4 1 v s

3 Ideal Brayton Cycle - 2

4 Jet Propulsion Cycle T 4 P=constant qin
1-2, inlet flow decelerates in the diffuser; pressure and temperature increase 5-6, outlet flow accelerates in the nozzle section, pressure and temperature decrease 3 5 6 2 qout 1 P=constant s

5 Propulsive Power Jet Engine Action force, FA Mass flow out
Mass flow in Inlet velocity, Vin Exit velocity, Vexit Reaction force, FR

6 Gas Turbine Improvements
Increase the gas combustion temperature (T3) before it enters the turbine since hth = 1 - (T4/T3) Limited by metallurgical restriction: ceramic coating over the turbine blades Improved intercooling technology: blow cool air over the surface of the blades (film cooling), steam cooling inside the blades. Modifications to the basic thermodynamic cycle: intercooling, reheating, regeneration Improve design of turbomachinery components: multi-stage compressor and turbine configuration. Better aerodynamic design on blades (reduce stall).

7 PW8000 Geared Turbofan Engine
Twin-spool configuration: H-P turbine drives H-P compressor L-P turbine drives L-P compressor, on separated shafts Gearbox to further decrease the RPM of the fan More fuel efficiency Less noise Fewer engine parts From Machine Design Magazine Nov. 5, 1998

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