Dry low emission (DLE) systems employing lean, premixed combustion have been successfully used with natural gas in combustion turbines to meet stringent emission standards. However, the burning of liquid fuels in DLE systems is still a challenging task due to the complexities of fuel vaporization and air premixing. Lean, premixed, and prevaporized (LPP) combustion has always provided the promise of obtaining low pollutant emissions while burning liquid fuels, such as kerosene and fuel oil. Because of the short ignition delay times of these fuels at elevated temperatures, the autoignition of vaporized higher hydrocarbons typical of most practical liquid fuels has been proven difficult to overcome when burning in a lean, premixed mode. To avoid this autoignition problem, developers of LPP combustion systems have focused mainly on designing premixers and combustors that permit rapid mixing and combustion of fuels before spontaneous ignition of the fuel can occur. However, none of the reported works in the literature has looked at altering fuel combustion characteristics in order to delay the onset of ignition in lean, premixed combustion systems. The work presented in this paper describes the development of a patented low LPP system for combustion of liquid fuels, which modifies the fuel rather than the combustion hardware in order to achieve LPP combustion. In the initial phase of the development, laboratory-scale experiments were performed to study the combustion characteristics, such as ignition delay time and formation, of the liquid fuels that were vaporized into gaseous form in the presence of nitrogen diluent. In the second phase, a LPP combustion system was commissioned to perform pilot-scale tests on commercial turbine combustor hardware. These pilot-scale tests were conducted at typical compressor discharge temperatures and at both atmospheric and high pressures. In this study, vaporization of the liquid fuel in an inert environment has been shown to be a viable method for delaying autoignition and for generating a gaseous fuel stream with characteristics similar to natural gas. Tests conducted in both atmospheric and high pressure combustor rigs utilizing swirl-stabilized burners designed for natural gas demonstrated an operation similar to that obtained when burning natural gas. Emission levels were similar for both the LPP fuels (fuel oils 1 and 2) and natural gas, with any differences ascribed to the fuel-bound nitrogen present in the liquid fuels. An extended lean operation was observed for the liquid fuels as a result of the wider lean flammability range for these fuels compared to natural gas.
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September 2008
Research Papers
A Novel Low Lean, Premixed, and Prevaporized Combustion System for Liquid Fuels
P. Gokulakrishnan,
e-mail: gokul@csefire.com
P. Gokulakrishnan
Combustion Science and Engineering, Inc.
, 8940 Old Annapolis Road, Suite L, Columbia, MD 21045
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M. J. Ramotowski,
M. J. Ramotowski
Combustion Science and Engineering, Inc.
, 8940 Old Annapolis Road, Suite L, Columbia, MD 21045
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G. Gaines,
G. Gaines
Combustion Science and Engineering, Inc.
, 8940 Old Annapolis Road, Suite L, Columbia, MD 21045
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C. Fuller,
C. Fuller
Combustion Science and Engineering, Inc.
, 8940 Old Annapolis Road, Suite L, Columbia, MD 21045
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R. Joklik,
R. Joklik
Combustion Science and Engineering, Inc.
, 8940 Old Annapolis Road, Suite L, Columbia, MD 21045
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L. D. Eskin,
L. D. Eskin
Combustion Science and Engineering, Inc.
, 8940 Old Annapolis Road, Suite L, Columbia, MD 21045
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M. S. Klassen,
M. S. Klassen
Combustion Science and Engineering, Inc.
, 8940 Old Annapolis Road, Suite L, Columbia, MD 21045
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R. J. Roby
R. J. Roby
Combustion Science and Engineering, Inc.
, 8940 Old Annapolis Road, Suite L, Columbia, MD 21045
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P. Gokulakrishnan
Combustion Science and Engineering, Inc.
, 8940 Old Annapolis Road, Suite L, Columbia, MD 21045e-mail: gokul@csefire.com
M. J. Ramotowski
Combustion Science and Engineering, Inc.
, 8940 Old Annapolis Road, Suite L, Columbia, MD 21045
G. Gaines
Combustion Science and Engineering, Inc.
, 8940 Old Annapolis Road, Suite L, Columbia, MD 21045
C. Fuller
Combustion Science and Engineering, Inc.
, 8940 Old Annapolis Road, Suite L, Columbia, MD 21045
R. Joklik
Combustion Science and Engineering, Inc.
, 8940 Old Annapolis Road, Suite L, Columbia, MD 21045
L. D. Eskin
Combustion Science and Engineering, Inc.
, 8940 Old Annapolis Road, Suite L, Columbia, MD 21045
M. S. Klassen
Combustion Science and Engineering, Inc.
, 8940 Old Annapolis Road, Suite L, Columbia, MD 21045
R. J. Roby
Combustion Science and Engineering, Inc.
, 8940 Old Annapolis Road, Suite L, Columbia, MD 21045J. Eng. Gas Turbines Power. Sep 2008, 130(5): 051501 (7 pages)
Published Online: May 30, 2008
Article history
Received:
September 24, 2007
Revised:
October 5, 2007
Published:
May 30, 2008
Citation
Gokulakrishnan, P., Ramotowski, M. J., Gaines, G., Fuller, C., Joklik, R., Eskin, L. D., Klassen, M. S., and Roby, R. J. (May 30, 2008). "A Novel Low Lean, Premixed, and Prevaporized Combustion System for Liquid Fuels." ASME. J. Eng. Gas Turbines Power. September 2008; 130(5): 051501. https://doi.org/10.1115/1.2904889
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