Analytical method for evaluation of gas turbine inlet air cooling in combined cycle power plant

Gas turbine inlet air cooling technologies (GTIAC), mainly including chilling with LiBr/water absorption chiller and fogging as well, are being used during hot seasons to augment the power output. To evaluate the general applicability of inlet air cooling for gas-steam combined cycle power plant (GTCCIAC), parameters such as efficiency ratio, profit ratio and relative payback period were defined and analyzed through off-design performances of both gas turbine and inlet air cooling systems. An analytical method for applicability evaluation of GTCCIAC with absorption chiller (inlet chilling) and saturated evaporative cooler (inlet fogging) was presented. The applicability study based on typical off-design performances of the components in GTCCIAC shows that, the applicability of GTCCIAC with chilling and fogging depends on the design economic efficiency of GTCC power plant. In addition, it relies heavily on the climatic data and the design capacity of inlet air cooling systems. Generally, GTCCIAC is preferable in the zones with high ambient air temperature and low humidity. Furthermore, it is more appropriate for those GTCC units with lower design economic efficiency. Comparison of the applicability between chilling and fogging shows that, inlet fogging is superior in power efficiency at ta = 15-20 °C though it gains smaller profit margin than inlet chilling. GTCC inlet chilling with absorption chiller is preferable in the zones with ta > 25 °C and RH > 0.4.

[1]  Yang Cheng Realization of the economical evaluation system for GTCC inlet air cooling based on numerical integration , 2005 .

[2]  Jinyue Yan,et al.  Humidified gas turbines—a review of proposed and implemented cycles , 2005 .

[3]  Cyrus B. Meher-Homji,et al.  Inlet Fogging of Gas Turbine Engines Detailed Climatic Analysis of Gas Turbine Evaporation Cooling Potential in the USA , 2003 .

[4]  Hiwa Khaledi,et al.  Effect of Inlet Air Cooling by Absorption Chiller on Gas Turbine and Combined Cycle Performance , 2005 .

[5]  Giovanna Barigozzi,et al.  Inlet Air Cooling Applied to Combined Cycle Power Plants: Influence of Site Climate and Thermal Storage Systems , 2007 .

[6]  Luis M. Romeo,et al.  Methodology for the economic evaluation of gas turbine air cooling systems in combined cycle applications , 2004 .

[7]  Tek Sutikno Optimizing inlet air chillers for combined-cycle operation , 2001 .

[8]  A. Doukelis,et al.  Inlet Air Cooling Methods for Gas Turbine Based Power Plants , 2006 .

[9]  R. Sullivan,et al.  Validation studies of the DOE-2 Building Energy Simulation Program. Final Report , 1998 .

[10]  Ryohei Yokoyama,et al.  Evaluation of Operational Performance of Gas Turbine Cogeneration Plants Using an Optimization Tool: OPS-Operation , 2004 .

[11]  Richard J Goldstein,et al.  Film cooling effect of rotor-stator purge flow on endwall heat/mass transfer , 2010 .

[12]  Na Zhang,et al.  Analytical solutions and typical characteristics of part-load performances of single shaft gas turbine and its cogeneration , 2002 .

[13]  Madjid Soltani,et al.  Performance improvement of gas turbines of Fars (Iran) combined cycle power plant by intake air cooling using a media evaporative cooler , 2007 .

[14]  Hsiao-Wei Chiang,et al.  Power Augmentation Study of a Combined Cycle Power Plant Using Inlet Fogging , 2006 .

[15]  Cheng Yang,et al.  Economic Evaluation on GTCC Inlet Air Cooling With Absorption Chiller , 2005 .