This paper describes models for the transient analysis of heavy duty gas turbines, and presents dynamic simulation results of a modern gas turbine for electric power generation. Basic governing equations have been derived from integral forms of unsteady conservation equations. Mathematical models of each component are described with the aid of unsteady one-dimensional governing equations and steady-state component characteristics. Special efforts have been made to predict compressor characteristics including the effect of movable vanes, which govern the operating behavior of a whole engine. The derived equation sets are solved numerically by a fully implicit method. A controller model that maintains constant rotational speed and target temperature (turbine inlet or exhaust temperature) is used to simulate practical operations. Component models, especially those of the compressor, are validated through comparison with test data. The dynamic behavior of a 150 MW class engine is simulated. The time-dependent variations of engine parameters such as power, rotational speed, fuel, temperature, and guide vane angles are compared with field data. Simulated results are fairly close to the operation data.

Issue Section:
Gas Turbines: Controls, Diagnostics, and Instrumentation
Keywords:
gas turbines, transient analysis, electric power generation, controllers, conservation laws, integral equations
Topics:
Compressors, Design, Engines, Exhaust systems, Flow (Dynamics), Gas turbines, Simulation, Temperature, Transients (Dynamics), Turbines, Fuels, Pressure, Steady state, Control equipment, Stress, Electric power generation, Transient analysis, Model development
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Copyright © 2001
 by ASME
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