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1699111 
Journal Article 
OXIDES OF NITROGEN EMISSIONS FROM TURBULENT JET FLAMES .2. FUEL DILUTION AND PARTIAL PREMIXING EFFECTS 
Turns, , SR; Myhr, FH; Bandaru, RV; Maund, ER 
1993 
Yes 
Combustion and Flame
ISSN: 0010-2180 
93 
255-269 
WOS:A1993KY52300005 
Measurements of NO(x) emission indices, flame radiant fractions, and visible flame length were made for turbulent, nonpremixed, jet flames for which various amounts of inert diluent or air were mixed with the fuel. The objective of the study was to explore further the role of flame radiation in NO(x) production in jet flames. Vertical free jet flames were stabilized on a 4.12 mm diameter straight-tube burner. Four fuels, CH4, C2H4, C3H8, and a 95% CO/5% H-2 Mixture (by mass); three inert diluents, N2, Ar, and CO2; and air premixing were employed in parametric tests. Complementary dilution experiments were run with laminar jet flames using the three hydrocarbon fuels and N2. For the turbulent flames, the results showed that the effects of dilution and premixing were strongly dependent on fuel type. Flame temperatures and NO(x) emissions increased when the more sooting fuels (C3H8 and C2H4) were diluted or partially premixed, resulting in increased NO(x) emissions. The opposite trend was observed for the nonluminous CO/H-2 flames. Using the results reported here and from Part I [1] of this study, the effects of residence time, flame temperature, and departure from equilibrium on NO(x) emissions, regardless of what parameter affected the change, were well characterized by regressing characteristic NO(x) production rates as a function of nonadiabatic characteristic flame temperatures and global residence times. Separate regressions for the hydrocarbon and CO/H-2 flames showed a weaker dependence of NO(x) on temperature for the hydrocarbons, suggesting that the prompt NO mechanism is quite active in these flames. The laminar flame experiments demonstrated the importance of the relative locations of NO(x)-producing regions and soot-containing (strongly radiating) regions of the flame.