Lumped Kinetic Simulation Of Hydrodenitrogenation For Full-Range Middle-Low Temperature Coal Tar

With the increasingly prominent environmental problems and depletion of light petrochemical resources, the clean utilization of heavy oil has become the research focal area. The hydrodenitrogenation (HDN) experiments and kinetics of full-range middle-low temperature coal tar (MLCT) was studied on a fixed-bed reactor with a Ni-Mo/gamma-Al2O3 catalyst. Two kinds of three-lumped kinetic models (K-1 and K-1.24) based on different reaction orders and high-middle-low reactivities were established and fitted by a simulated annealing algorithm for coal tar HDN reactions. The results presented good correspondence with experimental data following an average relative error of less than 0.3%. The effect of temperature, pressure, and liquid hourly space velocity (LHSV) on HDN of different reactivity nitrogen compounds (NCs) of MLCT was studied using the lumped kinetic models. Also, the difference between K-1 and K-1.24 models on the embodiment ability for HDN laws was also discussed from multiple perspectives. It has been observed that the HDN reactions of low and middle reactivity NCs are more influenced by LHSV; high temperature and pressure are more critical for the removal of low reactivity NCs, and low-temperature or -pressure zone have larger effects on coal tar HDN reactions, especially at high LHSV; temperature has much more influence than pressure on the HDN effect, particularly towards the low reactivity NCs. The results of HDN laws for high reactivity NCs are concordant with K-1 and K-1.24 models. The K-1.24 model is a bit more reasonable to reveal the HDN law of middle to low reactivity NCs.