The current study is centered on assessing the benefits of incorporating combustion turbine inlet air-cooling systems into a reference combustion turbine plant, which is based on a simple cycle under base load mode. Actual climatic conditions of a selected site were examined thoroughly to identify the different governing weather patterns. The main performance characteristics of both refrigerative and evaporative cooling systems were explored by examining the effect of several parameters including inlet air temperature, airflow-to-turbine output ratio, coefficient of performance (for refrigerative cooling systems), and evaporative degree hours (for evaporative cooling systems). The impact of these parameters was presented against the annual gross energy increase, average heat rate reduction, cooling load requirements and net power increase. Finally, a feasibility design chart was constructed to outline the economic returns of employing a refrigerative cooling unit against different prescribed inlet air temperature values using a wide range of combustion turbine mass flow rates.

1.
Van Der Linden, S., and Searles, D. E., 1996, “Inlet Conditioning Enhances Performance of Modern Combined Cycle Plants for Cost-Effective Power Generation,” ASME Paper No. 96-GT-298.
2.
Utamura, M., Ishikawa, A., Nishimura, Y., and Ando, N., 1996, “Economics of Gas Turbine Inlet Air Cooling System for Power Enhancement,” ASME Paper No. 96-GT-515.
3.
De Lucia
,
M.
,
Bronconi
,
R.
, and
Carnevale
,
E.
,
1993
, “
Performance and Economic Enhancement of Cogeneration Gas Turbines Through Compressor Inlet Air Cooling
,”
ASME J. Eng. Gas Turbines Power
,
116
, pp.
360
365
.
4.
Loud, R. L., and Slaterpryce, A. A., 1991, “Gas Turbine Inlet Air Treatment,” Technical Report, GE Company, Schenectady, New York, USA, pp. 18–24.
5.
Jolly, S., Nitzken, J., and Shepherd, D., 1998, “Evaluation of Combustion Turbine Inlet Air Cooling Systems,” Presented at the Power-Gen Asia, New Delhi, India.
6.
Stewart, W. E., 1999, Design Guide: Combustion Turbine Inlet Air Cooling System, ASHRAE, Atlanta, GA.
7.
Daryl, R. B., Katipamula, S., and Konynenbelt, H., 1996, “The Impact of TES on the Economics of Combustion Turbine Inlet Air Cooling,” Presented at the EPRI Int. Conf. On Sustainable Thermal Energy Storage, Bloomington, Minnesota, USA.
8.
Chaker
,
M.
,
Meher-Homji
,
C. B.
,
Mee
, III,
T.
, and
Nicholson
,
A.
,
2003
, “
Inlet Fogging of Gas Turbine Engines Detailed Climatic Analysis of Gas Turbine Evaporation Cooling Potential in the USA
,”
ASME J. Eng. Gas Turbines Power
,
125
, pp.
300
309
.
9.
Brown, D. R., Katipamula, S., and Koynenbelt, J. H., 1996, “A Comparative Assessment of Alternative Combustion Turbine Inlet Air Cooling Systems,” Pacific Northwest National Lab., Technical Report No. PNNL-10966, Richland, Washington.
You do not currently have access to this content.