The low-swirl injector (LSI) is a simple and cost-effective lean premixed combustion method for natural-gas turbines to achieve ultralow emissions (5 ppm NOx and CO) without invoking tight control of mixture stoichiometry, elaborate active tip cooling, or costly materials and catalysts. To gain an understanding of how this flame stabilization mechanism remains robust throughout a large range of Reynolds numbers, laboratory experiments were performed to characterize the flowfield of natural-gas flames at simulated partial load conditions. Also studied was a flame using simulated landfill gas of 50% natural gas and 50% CO2. Using particle image velocimetry, the nonreacting and reacting flowfields were measured at five bulk flow velocities. The results show that the LSI flowfield exhibits similarity features. From the velocity data, an analytical expression for the flame position as function of the flowfield characteristics and turbulent flame speed has been deduced. It shows that the similarity feature coupled with a linear dependency of the turbulent flame speed with bulk flow velocity enables the flame to remain relatively stationary throughout the load range. This expression can be the basis for an analytical model for designing LSIs that operate on alternate gaseous fuels such as slower burning biomass gases or faster burning coal-based syngases.
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March 2008
Research Papers
Laboratory Studies of the Flow Field Characteristics of Low-Swirl Injectors for Adaptation to Fuel-Flexible Turbines
R. K. Cheng,
R. K. Cheng
Environmental Energy Technologies Division,
Lawrence Berkeley National Laboratory
, Berkeley, CA 94720
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D. Littlejohn,
D. Littlejohn
Environmental Energy Technologies Division,
Lawrence Berkeley National Laboratory
, Berkeley, CA 94720
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W. A. Nazeer,
W. A. Nazeer
Solar Turbines Incorporated
, 2200 Pacific Highway, San Diego, CA 92101
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K. O. Smith
K. O. Smith
Solar Turbines Incorporated
, 2200 Pacific Highway, San Diego, CA 92101
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R. K. Cheng
Environmental Energy Technologies Division,
Lawrence Berkeley National Laboratory
, Berkeley, CA 94720
D. Littlejohn
Environmental Energy Technologies Division,
Lawrence Berkeley National Laboratory
, Berkeley, CA 94720
W. A. Nazeer
Solar Turbines Incorporated
, 2200 Pacific Highway, San Diego, CA 92101
K. O. Smith
Solar Turbines Incorporated
, 2200 Pacific Highway, San Diego, CA 92101J. Eng. Gas Turbines Power. Mar 2008, 130(2): 021501 (10 pages)
Published Online: January 22, 2008
Article history
Received:
April 25, 2007
Revised:
September 6, 2007
Published:
January 22, 2008
Citation
Cheng, R. K., Littlejohn, D., Nazeer, W. A., and Smith, K. O. (January 22, 2008). "Laboratory Studies of the Flow Field Characteristics of Low-Swirl Injectors for Adaptation to Fuel-Flexible Turbines." ASME. J. Eng. Gas Turbines Power. March 2008; 130(2): 021501. https://doi.org/10.1115/1.2795786
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