Ambient temperature strongly influences gas turbine power output causing a reduction of around to for every 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.
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April 2007
Technical Papers
Gas Turbine Fogging Technology: A State-of-the-Art Review—Part I: Inlet Evaporative Fogging—Analytical and Experimental Aspects
R. K. Bhargava,
R. K. Bhargava
22515 Holly Lake Drive, Katy, TX 77450
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C. B. Meher-Homji,
C. B. Meher-Homji
Bechtel Corporation
, 3000 Post Oak Boulevard, Houston, TX 77056
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M. A. Chaker,
M. A. Chaker
Bechtel Corporation
, 3000 Post Oak Boulevard, Houston, TX 77056
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M. Bianchi,
M. Bianchi
University of Bologna
, DIEM, Facolta di Ingegneria, Viale Risorgimento 2, Bologna 40136, Italy
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F. Melino,
F. Melino
University of Bologna
, DIEM, Facolta di Ingegneria, Viale Risorgimento 2, Bologna 40136, Italy
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A. Peretto,
A. Peretto
University of Bologna
, DIEM, Facolta di Ingegneria, Viale Risorgimento 2, Bologna 40136, Italy
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S. Ingistov
S. Ingistov
Watson Cogeneration Co./BP
, 11850 S. Wilmington Avenue, P. O. Box 6203, Carson, CA 90749
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R. K. Bhargava
22515 Holly Lake Drive, Katy, TX 77450
C. B. Meher-Homji
Bechtel Corporation
, 3000 Post Oak Boulevard, Houston, TX 77056
M. A. Chaker
Bechtel Corporation
, 3000 Post Oak Boulevard, Houston, TX 77056
M. Bianchi
University of Bologna
, DIEM, Facolta di Ingegneria, Viale Risorgimento 2, Bologna 40136, Italy
F. Melino
University of Bologna
, DIEM, Facolta di Ingegneria, Viale Risorgimento 2, Bologna 40136, Italy
A. Peretto
University of Bologna
, DIEM, Facolta di Ingegneria, Viale Risorgimento 2, Bologna 40136, Italy
S. Ingistov
Watson Cogeneration Co./BP
, 11850 S. Wilmington Avenue, P. O. Box 6203, Carson, CA 90749J. Eng. Gas Turbines Power. Apr 2007, 129(2): 443-453 (11 pages)
Published Online: February 1, 2006
Article history
Received:
October 1, 2005
Revised:
February 1, 2006
Citation
Bhargava, R. K., Meher-Homji, C. B., Chaker, M. A., Bianchi, M., Melino, F., Peretto, A., and Ingistov, S. (February 1, 2006). "Gas Turbine Fogging Technology: A State-of-the-Art Review—Part I: Inlet Evaporative Fogging—Analytical and Experimental Aspects." ASME. J. Eng. Gas Turbines Power. April 2007; 129(2): 443–453. https://doi.org/10.1115/1.2364003
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