Ambient temperature strongly influences gas turbine power output causing a reduction of around 0.50% to 0.90% for every 1°C of temperature rise. There is also a significant increase in the gas turbine heat rate as the ambient temperature rises, resulting in an increased operating cost. As the increase in power demand is usually coincident with high ambient temperature, power augmentation during the hot part of the day becomes important for independent power producers, cogenerators, and electric utilities. Evaporative and overspray fogging are simple, proven, and cost effective approaches for recovering lost gas turbine performance. A comprehensive review of the current understanding of the analytical, experimental, and practical aspects including climatic and psychrometric aspects of high-pressure inlet evaporative fogging technology is provided. A discussion of analytical and experimental results relating to droplets dynamics, factors affecting droplets size, and inlet duct configuration effects on inlet evaporative fogging is covered in this paper. Characteristics of commonly used fogging nozzles are also described and experimental findings presented.

1.
Bhargava
,
R. K.
, 2003, “
Global Energy Resources, Power Generation and Gas Turbine Market - Recent Trends
,”
Proceedings of the International Conference on Power Engineering
, Nov.
9
13
,
Kobe
, Japan.
2.
Bhargava
,
R.
, and
Meher-Homji
,
C. B.
, 2005, “
Parametric Analysis of Existing Gas Turbines with Inlet Evaporative and Overspray Fogging
,”
ASME J. Eng. Gas Turbines Power
0742-4795,
127
, pp.
145
-
158
).
3.
Bhargava
,
R. K.
,
Meher-Homji
,
C. B.
,
Chaker
,
M. A.
,
Bianchi
,
M.
,
Melino
,
F.
,
Peretto
,
A.
, and
Ingistov
,
S.
, 2007, “
Gas Turbine Fogging Technology: A State-of-the-Art Review—Part II: Overspray Fogging—Analytical and Experimental Aspects
,”
ASME J. Eng. Gas Turbines Power
0742-4795,
129
, pp.
454
460
.
4.
Bhargava
,
R. K.
,
Meher-Homji
,
C. B.
,
Chaker
,
M. A.
,
Bianchi
,
M.
,
Melino
,
F.
,
Peretto
,
A.
, and
Ingistov
,
S.
, 2007, “
Gas Turbine Fogging Technology: A State-of-the-Art Review—Part III: Practical Considerations and Operational Experience
,”
ASME J. Eng. Gas Turbines Power
0742-4795,
129
, pp.
461
472
.
5.
Meher-Homji
,
C. B.
, and
Mee
,
T. R.
, III
, 1999, “
Gas Turbine Power Augmentation by Fogging of Inlet Air
,”
Proceedings of the 28th Turbomachinery Symposium
,
Houston
, TX.
6.
Tawney
,
R.
,
Pearson
,
C.
, and
Brown
,
M.
, 2001, “
Options to Maximize Power Output for Merchant Plants in Combined Cycle Applications
,” ASME Paper No. 2001-GT-0409.
7.
Jones
,
C.
, and
Jacobs
,
J. A.
, 2000, “
Economic and Technical Considerations for Combined-Cycle Performance-Enhancement Options
,” GE Power Systems, GER-4200.
8.
Bhargava
,
R.
,
Bianchi
,
M.
,
Melino
,
F.
, and
Peretto
,
A.
, 2003, “
Parametric Analysis of Combined Cycles Equipped With Inlet Fogging
,” ASME Paper No. GT-2003-38187.
9.
Lefebvre
,
A. H.
, 1989,
Atomization and Spray
,
Taylor & Francis
, New York, Chap. 6.
10.
Chaker
,
M.
,
Meher-Homji
,
C. B.
,
Mee
,
T. R.
, III
, and
Nicolson
,
A.
, 2001, “
Inlet Fogging of Gas Turbine Engines—Detailed Climatic Analysis of Gas Turbine Evaporative Cooling Potential
,” ASME Paper No. 2001-GT-526.
11.
Chaker
,
M.
, and
Meher-Homji
,
C. B.
, 2002, “
Inlet Fogging of Gas Turbine Engines—Climatic Analysis of Gas Turbine Evaporative Cooling Potential of International Locations
,” ASME Paper No. 2002-GT-30559.
12.
Parsons
,
R.
, 2001,
ASHRAE Handbook-Fundamentals
,
ASHRAE
, Atlanta, Chap. 6,
Psychrometrics.
13.
Le Coz
,
J. F.
, 1998, “
Comparison of Different Drop Sizing Techniques on Direct Injection Gasoline Sprays
,” 9th
International Symposium on Application of Laser Techniques to Fluid Mechanics
,
Lisbon, July
13
16
.
14.
Mahapatra
,
S.
, and
Gilstrap
,
J. K.
, 2003, “
Gas Turbine Inlet Air Cooling: Determination of Parameters to Evaluate Fogging Nozzle’s Atomizing Performance
,” International Joint Power Generation Conference, Paper No. IJPGC2003-40124.
15.
Chaker
,
M. A.
,
Meher-Homji
,
C. B.
, and
Mee
,
T.
, III
, 2003, “
Inlet Fogging of Gas Turbine Engines—Experimental and Analytical Investigations on Impaction Pin Fog Nozzle Behavior
,” ASME Paper No. GT2003-38801.
16.
Chaker
,
M.
,
Meher-Homji
,
C. B.
, and
Mee
,
T. R.
, III
, 2002, “
Inlet Fogging of Gas Turbine Engines—Part A: Fog Droplet Thermodynamics, Heat Transfer and Practical Considerations; Part B: Fog Droplet Sizing Analysis, Nozzle Types, Measurement and Testing; Part C: Fog Behavior in Inlet Ducts, CFD Analysis and Wind Tunnel Experiments
,” ASME Papers No. 2002-GT-30562, No. 30563, and No. 30564.
17.
Pitch
,
M.
, and
Erdman
,
C. A.
, 1987, “
The Use of Breakup Time Data and Velocity History Data to Predict the Maximum Size of Stable Fragments for Acceleration-Induced Breakup of Liquid Drops
,”
Int. J. Multiphase Flow
0301-9322,
13
, pp.
741
757
.
18.
Schick
,
R. J.
, and
Knasiak
,
K. F.
, 2000, “
Spray Characterization For Wet Compression Gas Cooling Applications
,”
8th International Conference on Liquid Atomization and Spray Systems
,
Pasadena
, CA, July.
19.
Chaker
,
M.
, and
Kippax
,
P.
, 2004, “
Towards a Protocol For the Analysis of the High Fogging Process Using Laser Diffraction Technology
,”
Power Eng.
, Jan., pp.
49
.
20.
Hoffmann
,
J.
, 2002, “
Inlet Air Cooling Performance and Operation
,” CEPSI, Paper No. T1-A-39, Fukuoka, Japan.
21.
Meher-Homji
,
C. B.
, and
Mee
,
T. R.
, III
, 2000, “
Inlet Fogging of Gas Turbine Engines—Part B: Practical Considerations, Control and O&M Aspects
,” ASME Paper No. 2000-GT-308.
22.
Savic
,
S.
,
Mitsis
,
G.
,
Haertel
,
C.
,
Khaidarov
,
S.
, and
Pfeiffer
,
P.
, 2002, “
Spray Interaction and Droplet Coalescence in Turbulent Air-Flow—An Experimental Study with Application to Gas Turbine High Fogging
,” ILASS Europe, Zaragoza, Spain,
9
11
September.
23.
Trewin
,
R. R.
, 2002, “
Inlet-temperature Suppression of Inlet Air for Gas-Turbine Compressors by Evaporative Cooling of Water Spray
,” ASME Paper No. GT-2002-30658.
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