Conceptional Design Modeling of Gas Turbine Cycle for Maximum Work Output, First Law and Second Law Efficiency

The present paper discusses gas turbine operating ranges of values of controlling cycle parameters for maximum first law efficiency η_I, second law efficiency η_II, and work output w_net. Three cycles have been studied: simple cycle, recuperative cycle and general open cycle. Correlation equations relating maximum values of η_I, η_II, and w_net to the controlling parameters (compressor and turbine efficiencies, maximum cycle temperature, isentropic temperature ratio, fuel/air ratio, heat exchanger effectiveness and pressure drops in combustion chamber and heat exchanger) have been determined and discussed.

The present paper reveals that the cycle performance parameters η_I, η_II, and w_net drastically depend on cycle controlling parameters. There is no narrow region of values of controlling parameters that produce concurrent optimum values of η_I, η_II, and wnet. The maximum cycle temperature for the three cycles considered has a linear effect on η_I, while other controlling parameters have nonlinear effects on η_I, η_II, and w_net. For the general open cycle, the pressure drops ΔP_cc and ΔP_ex have equal decreasing effects on η_I, η_II, and w_net, while both fuel-air ratio ƒ and heat exchanger effectiveness η_X have equal increasing effect on these performance parameters. The present correlation equations, augmented with other experimental and detailed design studies for each of the cycle units, could provide a good basis for the realistic design process of actual turbines.