NOx emission and thermal performances studies on premixed ammonia-oxygen combustion in a CO2-free micro-planar combustor

Unlike hydrocarbon fuel, ammonia is a carbon-free and renewable energy source. It is also regarded as one of the potential energy carriers. However, ammonia combustion for power generation is not well studied under microscale conditions, especially concerning nitrogen oxides (NOx) emission. For this, thermal performances and NO emission characteristics of premixed ammonia/oxygen combustion are numerically investigated on a microplanar combustor. The effects of 1) the equivalence ratio phi, 2) inlet temperature T-in and 3) inlet pressure P-in are examined. The outer wall mean temperature (OWMT) is found to vary non-monotonically, as the mixture varies from lean to rich conditions, with the peak occurring at phi = 0.9 mainly due to the optimal heat transfer performance. However, a low phi could lead to the high nitric oxides (NO) concentrations because of the high flame temperature as well as phi atom concentrations. Up to 75.5% of NO reduction could be achieved, as is optimized. Furthermore, increasing T-in is shown to be associated with a low OWMT and NO concentration. In addition, varying P-in is shown to lead to not only OWMT being changed but also NO formation being mitigated. The decrease in NO concentration for a high P-in is mostly attributable to the short residence time of a high flame temperature in the channel and low OH concentrations. This work reveals that optimizing the operating thermodynamic parameters is an effective means to reduce NO emissions and to improve thermal performances.