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Title	Designing Air Staging Systems with Mathematical Modeling
Creator	Latham, C. E.; LaRue, Albert D.; LaRose, J. A.
Publisher	Digitized by J. Willard Marriott Library, University of Utah
Date	1994
Spatial Coverage	presented at Maui, Hawaii
Abstract	Combustion systems that include air staging ports are being applied to utility boilers to meet legislated NOx emission limits. The systems must be designed for effective emission control while minimizing the impact on combustion efficiency and boiler performance. Traditional methods for applying overfire air have worked well in the past and continue to work well in some cases. However, as low NOx retrofits are applied to a more diverse range of boiler sizes and configurations, these traditional methods cannot be extrapolated readily. A design tool - mathematical modeling - has been developed for extending current and developing new methodologies for applying overfire air systems. The applications include single wall-fired, opposed wall-fired, roof-fired, cyclone-fired, and cell-fired boilers. At Babcock & Wilcox, mathematical modeling is playing a vital role in the design and application of air staging systems. Three-dimensional models have been developed to accurately predict flow, combustion, and heat transfer in a wide variety of fossil-fuel fired furnaces. The models provide the means to evaluate alternate designs and to optimize system performance. Consequently, tuning a system to match the unique requirements of a specific boiler can be accomplished rapidly with confidence. This paper discusses the role that mathematical modeling played in the sorting of options for low NOx retrofit designs that included air staging ports.
Type	Text
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/s6cv4mb0
Setname	uu_afrc
ID	8724
Reference URL	https://collections.lib.utah.edu/ark:/87278/s6cv4mb0

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Title	Page 19
Format	application/pdf
OCR Text	Show 18 higher than those experienced with the original cell burners. The results of this demonstration are also contained in Yagiela, et al. (1994). Air Port - Normal Operation Righi Side Wall ~ to II> a: 20,000 - Air Port Bumer Air Port - Bumer - 100,000 -120,000 ppmV Air Port Dampers 20 degrees Down Measured CO Concentrations 130,000 ppmV Lower Row Burner Stoichiometry 0.8 50,000 - 60,000 ppmV Figure 17 Predicted CO Concentrations Near the Right Side Wall 0 0 •0 • • 0 0 • •0 • Original Installation 0 0 •0 • • 0 • 0 • Right Side Wall 0 • o Air Ports • Burners Figure 18 Burner and Air Port Arrangements Alternating Lower Cells Inverted 0 •0 •0 •0 ••0 • 0 • 0 0 • •0 0 • 0 • (ppm) <10,000 10,000 20,000 30,000 40,000 50,000 60,000 70,000 80,000 90,000 100,000 110,000 120,000 0 •
Setname	uu_afrc
ID	8721
Reference URL	https://collections.lib.utah.edu/ark:/87278/s6cv4mb0/8721