Due to its low volatile characteristics of lean coal, it is difficult to catch fire and burn out. Therefore, high temper-ature is needed to maintain combustion efficiency, while, this leads to high nitrogen oxide emission. For power plant boilers burning lean coal, stable combustion with lower nitrogen oxide emission is a challenging task.This study applied the 3D numerical simulation on the analysis of a novel de-coupling burner for low-volatile coal and its structure and operation parameters optimization. Results indicate that although it was more difficult for lean coal decoupling burner to ignite lean coal than high volatile coal, the burner formed a stepwise ignition trend, which promoted the rapid ignition of lean coal. Comparison of three central partition plate structure shows that in terms of characteristics of the flow field distribution, rich and lean separation and combustion, the struc-ture with an inclination of 0° showed good performance, with its rich-lean air ratio being 0.85 and concentration ratio being 22.94, and there was an apparent decoupling combustion characteristic Finally, the structure of the selected burner was optimized for its operational conditions. The optimal operating parameters was determined as the primary air velocity of 24.9 m?s-1 and the mass flow rate of pulverized coal of 2.5 kg?s-1, in which the pyrolysis products were utilized as reductive agent more fully. Eventually, the nitrogen oxide was efficiently re-duced to nitrogen, which emission concentration was 61.88％ lower than that in the design condition.