Pressure gain combustion advantage in land-based electric power generation
Copyright policy )Pressure gain combustion advantage in land-based electric power generation
AbstractThis article evaluates the improvement in gas turbine combined cycle power plant efficiency and output via pressure gain combustion (PGC). Ideal and real cycle calculations are provided for a rigorous assessment of PGC variants (e.g., detonation and deflagration) in a realistic power plant framework with advanced heavy-duty industrial gas turbines. It is shown that PGC is the single-most potent knob available to the designers for a quantum leap in combined cycle performance.
gas turbine, TJ1-1570, TL1-4050, Electrical engineering. Electronics. Nuclear engineering, Mechanical engineering and machinery, pressure gain combustion, combined cycle, electric power generation, TK1-9971, Motor vehicles. Aeronautics. Astronautics
gas turbine, TJ1-1570, TL1-4050, Electrical engineering. Electronics. Nuclear engineering, Mechanical engineering and machinery, pressure gain combustion, combined cycle, electric power generation, TK1-9971, Motor vehicles. Aeronautics. Astronautics
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