A three-dimensional simulation study is performed to provide a design basis for maximum performance operation of the stoker-type incinerator. The model equations consider turbulent flows and gaseous chemical reactions to investigate the flow field, the amount of CO and NO emissions and the residence time in the furnace and boiler parts among the incinerator systems. Results show that the concentrations of CO and NO emitted decrease with the increase of the secondary excess air under given conditions. However, the residence times in the temperature cone above 1,123K(850℃) are less than 2 seconds, when the primary excess air of 100% is supplied with the secondary excess air of 100% and 150%. Based on the simulation results, the emission of air pollutants would be minimized for the primary excess air of 100% and the secondary air of 50% when considering chemical reactions and residence time in the incinerator. Comparison of characteristic times of the chemical reactions and the turbulent mixing of gases shows that the mixing effect is dominant. However, in the cases of the total excess air of 200% and 250%, the effect of chemical reactions on the incineration efficiency could not be neglected because of the relatively long characteristic time of the combustion reactions. The methodology suggested in the study would be applied to obtain the design parameters of new incinerators and determine the operating ranges of incinerators for the maximum performance.