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Title	Combustion Aerodynamics of a Pulverized-Coal, Low NOx Swirl Burner: Influence of Flow Types on NOx Emissions
Creator	Sharifi, Reza; Scaroni, Alan W.
Publisher	Digitized by J. Willard Marriott Library, University of Utah
Date	1996
Spatial Coverage	presented at Baltimore, Maryland
Abstract	The combustion aerodynamics of a pulverized-coal, 10w-NOx swirl burner firing an industrial boiler were determined experimentally. Measurements of gas temperature, velocity, particle speed and number density were used to classify the flow type for two different swirl numbers (2.1 and 1.9). The swirl number was changed by adjusting the damper settings on the three combustion air streams of the burner. The measurements indicated that a flame based on Type II flow was associated with the high swirl number (2.1), which produced a high combustion efficiency (98%) and high NOx emissions (700 ppm at 3% 02). The lower swirl number (1.9) produced a Type III flow, which resulted in a flame with high combustion efficiency (97%) and lower NOx emissions (380 ppm at 3% 02). Therefore, a 10% change in the overall swirl number for this burner in the specified boiler, resulted in a major change in the flame type and a significant change in NOx emissions. Lower NOx emissions emanated from the Type III flow.
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Format	application/pdf
Language	eng
Rights	This material may be protected by copyright. Permission required for use in any form. For further information please contact the American Flame Research Committee.
Conversion Specifications	Original scanned with Canon EOS-1Ds Mark II, 16.7 megapixel digital camera and saved as 400 ppi uncompressed TIFF, 16 bit depth.
Scanning Technician	Cliodhna Davis
ARK	ark:/87278/s6g163fj
Setname	uu_afrc
ID	10922
Reference URL	https://collections.lib.utah.edu/ark:/87278/s6g163fj

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Title	Page 16
Format	application/pdf
OCR Text	Show Maier, H., Spliethoff, H., Fingerle, A., & Hein, K. R. G. (1993). Effect of Coal Blending and Particle Size on NO Emission and Burnout. filla, 1l(9), 1447-1452. x Marsh, 1. S. (1951). Significance of Air Temperature in Open Hearth Operation. In American Iron and Steel Institute. Year Book (pp. 185-207). Mullikin, H. F. (1941). Gas-Temperature Measur 'nt and the High-Velocity Thellllocouple. In N. R. C. American Institute of Physics with National But t Standards (Eds.), Temperature: Its Measurement and Control In Science and Industr. .p. 775-829). New York: Reinhold Publishing Corp. Mullikin, H. F., & Osborn, W . . 1941). Accuracy Tests of the High-Velocity Thermocouple. In A. 1. o. P. w. N. B. o. S. N. R. Council (Eds.), Temperature: Its Measurement and Control In Science and Industty (pp. 805-829). New York: Reinhold Publishing ( p. Orfanoudakis, N. G., & Taylor, A. M. K. P. (19YJ). Evaluation of an Amplitude Sizing Anemometer and Application to Pulverized Coal Burner. Combust. Sci. and Tech., 108,255-277. Schack, A. (1939). The Theory and Application of the Suction Pyrometer. Journal of the Institute of Fuel, 12, S30-S38. Sharifi, R. (1996) The Numerical and Experimental Investigation of a Retrofitted Industrial Boiler Firing Dry Micronized Coal. Ph. D., The Pennsylvania State University, University Park, PA. Sharifi, R., & Scaroni, A. W. (1995). Comparative Analysis of Two Commercial, Low NOx Pulverized ':oal Swirl Burners. In Joint Meeting of the Central StateslWestern StateslMexican National Sections of the Combustion Institute and the American Research Committeee, (pp. 7-13). San Antonio, Texas: The Combustion Institute. Smoot, L. D. (Ed.), (1993). Fundamentals of Coal Combustion. Amsterdam, The Netherlands: Elsevier. Truelove, 1. S. (1984). The Modeling of Flow and Combustion in Swirled, Pulverized-Coal Burners. In Twentieth Symposium (International) on Combustion, (pp. 523-530). The Combustion Institute, Pittsburgh, P A. Truelove, J. S. (1986). Prediction of the Near-Burner Flow and Combustion in Swirling Pulverized-Coal Flames. In Twenty-First Symposium (International) on Combustion, (pp. 275-284). The Combustion Institute, Pittsburgh, P A. Truelove, J. S., & Holcombe, D. (1990). Measurement and Modelling of Coal Flame Stability in a PilotScale Combustor. In Twenty-Third Symposium (International) on Combustion, (pp. 963-971). The Combustion Institute, Pittsburgh, P A. Truelove, J. S., Wall, T. F., Dixon, T. F., & Stewart, M. (1982). Flow, Mixing and Combustion Within the Quarl of a Swirled, Pulverized-Coal Burner. In Nineteenth Symposium (International) on Combustion, (pp. 1181-1187). The Combustion Institute, Pittsburgh, PA. Truelove, J. S., & Williams, R. G. (1988). Coal Combustion Models for Flame Scaling. In Twenty-Second Symposium (International) on Combustion, (pp. 155-164). The Combustion Institute, Pittsburgh, PA. Weber, R., & Dugue, J. (1992). Combustion Acclerated Swirling Flows in High Confinements. ftQg.. Energy Combust. Sci ., 18., 349-367. Weber, R. , Dugue, 1., Sayre, A., & Visser, B. M. (1992). Quarl Zone Flow Field and Chemistry of Swirling Pulverized Coal Flames: Measurements and Computations. In Twenty-Fourth Symposium (International) on Combustion, (pp. 1373-1380). The Combustion Institute, Pittsburgh, P A. Wendt, 1. O. L. (1995). Mechanisms Governing the Formation and Destruction of NO x and Other Nitrogenous Species in Low NO Coal Combustion Systems. , 108, 323-344. x Yoon, H. K. (1982) Five-Hole Pitot Prove Time-Mean Velocity Measurements in Confined Swirling Flows. ~: ., Oklahoma State University, OK.
Setname	uu_afrc
ID	10921
Reference URL	https://collections.lib.utah.edu/ark:/87278/s6g163fj/10921