Low NOx Oxy-Gas Burner

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as well as air-gas fired furnaces minimizing costs and maximizing energy savings, production rate, and N O x reduction. High Luminosity Burner A conceptual drawing of the High Luminosity Burner is presented in Figure 1. The burner features a Fuel Preheating Zone and a Combustion (Flame) Zone. Each of the burner system Zones consists of several sections as presented in the figure and described below. The Fuel Preheating Zone is designed to preheat the natural gas in such a way as to maximize the formation of soot precursors. The Combustion Zone consists of a fuel-rich combustion section where the soot precursors are converted to soot particles followed by a ftiel-lean combustion section with a highly luminous flame that extends into the furnace and provides the energy input into the furnace and load. All of the soot is burned out in the second combustion section of the Combustion Zone. 0 2 Natural Gas | I n A_ Natural Gas T - g = Fuel Preheat Figure 1. HIGH-LUMINOSITY B U R N E R C O N C E PT Significant work by IGT and others supports the concept of this innovative IGT burner. Recent work by Factory Mutual indicates methane needs to be preheated to 1000°C (1830°F) and above to create significant amounts of soot in the flame.3 Figure 2 shows high methane preheat temperature significantly increases flame radiation. Older work of Wolanin indicates the optimum methane preheating temperature is in the range 1150° to 1180°C (2100° to 2160°F).4 Wolanin shows the heat transfer to the load is increased by 6 3 % when 26.5% of the natural gas is decomposed and the gas is preheated to 1190°C (2174°F). To have a practical high luminosity burner with soot generated in the flame, these results indicate the natural gas must be preheated to between 1000° and 1180°C (1830° and 2160°F) without cracking and then mixed with oxygen. The desired soot should be formed during the oxygen-hot natural gas combustion, and 3