Burner emissions associated with lobed and non-lobed fuel injectors

The present experimental study examines NOx and CO emissions associated with three alternative fuel-injector geometries. These injectors mix fuel and air and strain their interfaces to differing extents and thus create different local equivalence ratios within flow regions upstream of flame ignition and stabilization. Two of the devices studied are lobed fuel injectors, in which molecular mixing of reactants is associated with streamwise vorticity generation, while die third one is a non-lobed fuel injector Results show that rapid mixing allowed both lobed injector geometries to produce very lean premixed flame structures, with a lower achievable turn-down or fuel/air mass flux ratio than for the analogous non-lobed injector, which largely produced distinct diffusion flames. All three injectors exhibited some level of sooting near walls and in the far-field region, with the non-lobed injector sooting to the greatest extent. At low fuel flow rates, in which die lobed injectors created locally very lean premixed conditions, there resulted lower NOx emissions as compared with non-lobed injector emissions. Yet at higher fuel-air mass flux ratios, NOx emissions from the lobed injectors were actually higher than for the non-lobed injector, likely due to reduced sooting and hence reduced radiative heal losses associated with enhanced mixing. For both lobed injector geometries examined here, CO emissions became high for low values of the fuel-air mass flux ratio, again consistent with locally premixed combustion behavior, despite the fact that fuel was injected separately from air, directly into die burner test section. The present study demonstrates that, for fuel-air mixing enhancement devices, control of the local equivalence ratio is critical in order to optimize burner emissions.