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Title	The Influence of Mixing on NOx Reduction by Coal Fuel Staging
Creator	Knill, K. J.; Morgan, M. E.
Publisher	Digitized by J. Willard Marriott Library, University of Utah
Date	1990
Spatial Coverage	presented at San Francisco, California
Abstract	This study was conducted to evaluate the influence of reburn fuel mixing with primary combustion products on NOx reduction by coal fuel staging. Furnace experiments were conducted in a 2.5 MW furnace to determine the NOx emissions possible under conditions simulating a fuel staged boiler. NOx emissions were measured for cases when the mixing of the reburn fuel and primary combustion products at the end of the reburn zone was complete and incomplete. Reburn zone experiments were conducted in a 80 KW laboratory reactor to determine the NOx reduction possible in the reburn zone under rapid mixing conditions. In the furnace experiments, reburn zone stoichiometry was the most important variable and NOx emissions could be reduced from 1000 ppm to 350 ppm as reburn stoichiometry decreased from 1.0 to 0.8. Complete reburn fuel mixing with primary combustion products only lowered NOx emissions in the tests with reburn stoichiometry less than 0.9. In the reburn zone experiments, NOx could be reduced from 1000 ppm to 30 ppm in 0.3 s. The extent of reduction was independent of the reburn fuel fraction and primary stoichiometry as long as the reburn stoichiometry was less than 0.85. The total volatile fixed nitrogen concentration (TVFN; sum of NOx, HCN and NH3) at the end of the reburn zone could not be reduced to less than 350 ppm. The TVFN concentration was independent of the reburn zone stoichiometry less than 0.9. Comparison of the results of the two experiments indicated that NOx reduction was partly limited by mixing of the reburn fuel and primary combustion products. However, the NOx emissions in the 2.5 MW furnace equaled the TVFN in the laboratory reactor and suggested that NOx emissions were also limited by the ability to reduce HCN and NH3 in the reburn zone.
Type	Text
Format	application/pdf
Language	eng
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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/s6p271pf
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ID	5998
Reference URL	https://collections.lib.utah.edu/ark:/87278/s6p271pf

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Title	Page 7
Format	application/pdf
OCR Text	Show 3.0 ~ c ".2§ 2.0 C Q.I u § 0 1.0 u 0 ~ 3.0 .~ ~ ~ 2.0 u ~ u o U to - 7 - 2.0 AD = axial distance AD 0.6m 1.0 0 60 80 100 120 140 50 2.0 0 to 60 80 100 120 1L.0 50 elevatia'l (eml horizontal positioo (eml 0 Figure 4: CO2 concentration profiles at high mixing 60 80 100 120 1L.O 50 horizontal position leml AD = axial distance i..0 T"""'--------1----.- -so ele'vOticn (em) ~ 3.0 c .2 '0 L.. C ~ 2.0 § a u 1.0 60 00 100 120 1L.O 50 t-aizootal position (eml Figure 5: CO2 concentration profiles at low mixing AD 1.0Sm 0 AD 1.l.m AD 1.1. m
Setname	uu_afrc
ID	5985
Reference URL	https://collections.lib.utah.edu/ark:/87278/s6p271pf/5985