Abstract
In comparison to methane (CH(4)), ammonia (NH(3)) is considered a potential carbon-free alternative fuel that can reduce greenhouse gas emissions. But a principal concern is the generation of elevated nitrogen oxide (NO(X)) emissions from NH(3) flame. In this study, the detailed reaction mechanisms and thermodynamic data of CH(4) oxidation and NH(3) oxidation were performed using the steady and unsteady flamelet models. After validation of the turbulence model, the combustion and NO(X) emission characteristics of CH(4)/air and NH(3)/air non-premixed flames in a micro gas turbine swirl combustor under a series of identical heat loads were numerically investigated and compared. The present results show that the high-temperature zone of the NH(3)/air flame migrates more rapidly toward the outlet of the combustion chamber than that of the CH(4)/air flame as the heat load increases. The average NO, N(2)O, and NO(2) emission concentrations at all heat loads from NH(3)/air flame are respectively 6.12, 161.05 (given the very low N(2)O emission concentration from CH(4)/air flame), and 2.89 times higher than those from CH(4)/air flame. There are correlation trends between some parameters (e.g. characteristic temperature and OH emissions) with the variation of the heat load, and the relevant parameters can be tracked to predict the emission trends after changing the heat load.