Record Display for the EPA National Library Catalog

RECORD NUMBER: 3 OF 8

OLS Field Name OLS Field Data
Main Title Control of Utility Boiler and Gas Turbine Pollutant Emissions by Combustion Modification--Phase II.
Author Manny, E. H. ; Crawford, A. R. ;
CORP Author Exxon Research and Engineering Co., Florham Park, NJ.;Industrial Environmental Research Lab., Research Triangle Park, NC.
Year Published 1981
Report Number EE.5E.81; EPA-68-02-1415; EPA-600/7-81-039;
Stock Number PB81-222267
Additional Subjects Air pollution control ; Boilers ; Gas turbines ; Nitrogen oxides ; Electric power plants ; Revisions ; Industrial wastes ; Combustion products ; Particles ; Performance evaluation ; Coal fired power plants
Holdings
Library Call Number Additional Info Location Last
Modified
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Status
NTIS  PB81-222267 Most EPA libraries have a fiche copy filed under the call number shown. Check with individual libraries about paper copy. NTIS 06/23/1988
Collation 178p
Abstract
The report gives results of Phase II of a field study to assess the applicability of combustion modification (CM) techniques to control NOx and other pollutant emissions from utility boilers and gas turbines without causing deleterious side effects. Comprehensive, statistically designed tests were used to evaluate the effect of CM. The most extensively studied CM for utility boilers was staged firing at low excess air, which can reduce NOx emissions by up to about 50%, based on results of short-term tests. Tests of B and W's low-NOx, dual-fired utility boilers, special attention was paid to the determination of potentially adverse side effects: increased combustible emissions, unwanted changes in particulate mass loading and size distribution, reduced boiler efficiency, increased furnace slagging, and tube wall corrosion. Short-term tests indicate that staged combustion may be applied to coal-fired utility boilers. The extent of furnace tube wall corrosion and slagging could not be determined conclusively, based on results of short-term (300-hour) corrosion probing runs under low NOx and baseline operating conditions. It was found, however, that corrosion probes exposed for longer periods (300-1000 hours) may more effectively correlate with actual furnace tube corrosion rates.