Nihon Kikai Gakkai ronbunshu (Nov 2015)
NOx reduction effect of two-stage combustion using tubular flame
Abstract
The recuperative burner and the regenerative burner that applied exhaust heat recirculation are proposed as energy-saving technology in furnaces in a practical use. Although, heating efficiency has the proportional to the rate of the exhaust heat recirculation, the burned gas temperature and NOx emission increases in the conditions of high exhaust heat recirculation. The newly developed two-stage combustion method was proposed in this research for improving NOx reduction. The two-stage combustion method is often applied as low NOx technology with using exhaust heat recirculation. This research proposed a tubular flame for the first stage of two-stage combustion. Since the tubular flame can sustain a stable premixed flame in rich mixture in the first stage, NOx generated in the primary burner suppresses due to low flame temperature in this proposed system. In addition, the inlet gas temperature in the secondary burner can be adjusted by intermediate cooling section that placed between the primary burner and secondary burner. This reduction of the inlet gas temperature is also contributed to reduction of NOx in the secondary burner. Results show that the first flame was successfully formed until equivalence ratio 1.7 by using tubular flame in the primary burner. The smallest NOx emission appeared in the condition that the adiabatic flame temperature become equilibrium to the amount of heat reduction calculated from the intermediate cooling section. The NOx emission is reduced to 16.3 ppm (O2=0%) at the equivalence ratio of 1.67 in the primary burner without intermediate cooling tube. This value is about 1/6 of the single-stage combustion with Bunsen flame, and about 1/4 of the two-stage combustion with partially premixed flame in the primary burner.
Keywords
