NO_x REDUCTION OF A 165 MW WALL-FIRED BOILER UTILIZING AIR AND FUEL FLOW MEASUREMENT AND CONTROL

摘要

As a result of increasingly stringent emissions limitations being imposed on coal-fired power plants today, electric utilities are faced with having to make major compliance related modifications to their existing power plants. While many utilities have elected to implement expensive post-combustion NO_x reduction programs on their largest generating units, in-furnace NO_x reduction offers a less expensive alternative suitable to any size boiler - to reduce NO_x while also improving overall combustion. In-furnace NO_x reduction strategies have proven that, when used with other less expensive approaches (Overfire air, fuel switching, and/or SNCR), levels less than 0.15 lb./MM Btu can be economically achieved. Furthermore, when implemented in conjunction with an expensive post-combustion SCR program, initial capital requirements and ongoing operating costs can be cut to save utilities millions of dollars. For the purpose of developing a system-wide NO_x reduction strategy, Santee Cooper, a southeastern U.S. utility applied pulverized coal flow and individual burner airflow measurement systems to Unit 3 at its Jefferies plant, a 165 MW, 16-burner wall-fired boiler. The airflow measurement system, in service for many years, applied a well-proven averaging Pitot tube technology to measure individual burner secondary airflow. The coal flow measurement system utilized low energy microwaves to accurately measure coal density and coal velocity in individual coal pipes. The combination of these two systems provided the accurate measurements necessary for precise control of both air and coal flow to the individual burners, giving the plant the ability to increase burner combustion optimization, yielding a reduction in NO_x levels approaching 20%. Optimized burner combustion also resulted in a leveling of the O_2 profile, which will enable the plant to pursue further reductions in excess air as well as staged combustion, thus allowing for further NO_x reductions in the future. How this program produced a significant NO_x reduction will be presented in detail in this paper. The paper will also discuss the affects on O_2, opacity, and unburned carbon. In addition, this program will allow for future system-wide planning with regard to possible SCR implementation.