Abstract

Cold-modeling gas/particle flow experiments and numerical simulations on coal combustion were performed for evaluating the furnace throat effect on the flow-field deflection and asymmetric combustion in a 600MWe supercritical down-fired boiler. At the furnace design setting (CW=0.529), a severely deflected gas/particle flow field appears, corresponding to a badly asymmetric combustion pattern with poor burnout and high NOx emissions. Shrinking the furnace throat from CW=0.529 to CW=0.500 apparently aggravates both the experimental and simulated flow-field deflection and meanwhile deteriorates asymmetric combustion. In contrast, expanding the furnace throat space to CW=0.558 improves greatly the above problems and the flow-field symmetries are generally acceptable, accompanied by improved burnout rate and lowered NOx emissions. Findings in this work suggest that new down-fired boiler designs should be equipped with a larger furnace throat space under the circumstances with a short upper furnace aggravating the asymmetric upper furnace configuration effect.

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