Effect of outer secondary-air vane angle on the flow and combustion characteristics and NOx formation of the swirl burner in a 300-MW low-volatile coal-fired boiler with deep air staging

Abstract Small-scale laboratory experiments of airflow through a single burner model and industrial-scale experiments on the centrally fuel-rich, low NO x swirl burner on a 300-MW wall-fired subcritical boiler burning low-volatile coal under deep air staging were performed. The aerodynamic characteristics, flue gas temperature, and gas concentrations were measured for various vane angles of outer secondary air in the burner nozzle region. The results show that a stable, symmetric central reverse-flow zone forms close to the exit of the burner nozzle region under deep air staging. With decreasing vane angle, i) the maximum axial, radial, and tangential velocities and swirl intensity of the airstream increase; ii) the decaying rate of velocity increases between X / D  = 0 and X / D  = 0.8; iii) the maximum diameter, length, and the jet divergence angle of the central reverse-flow zone increase; and iv) the relative reverse-flow rate increases. While the primary air concentration decreases slightly, the maximum primary air concentration decreases rapidly with decreasing vane angle. In contrast, the maximum axial relative mixing rate increases in the initial stage along the airstream direction. A decrease in vane angle increases the flue gas temperature, the rate of increase indicating a closer ignition position of the anthracite and lean coal along the airstream direction of the burner. The O 2 consumption rate and NO x formation rate increase in the initial stage of combustion, whereas in the later stage the CO concentration increases notably and the O 2 concentration remains almost constant below 1%. The CO concentration can exceed 20,000 ppm, which restrains the NO x formation and reduces the NO x concentration notably, but beyond X′  = 0.8 m, the NO x concentration remains almost constant. The flue gas temperature varies slightly for different vane angles in the side-wall region. The O 2 concentration exceeds 4% near the location of the water-cooled wall. The O 2 concentrations are below 2% and the CO concentrations are above 5000 ppm along the radial direction 1.8375 m ≤  R′ ≤2.3375 m from the centerline of the burner in the side-wall region. With decreasing vane angle, the CO concentration increases while the NO x concentration decreases.