YAN Zhi, YANG Ziyi, NING Kexiang, LEI Ke, NI Jiwei, ZHANG Jinghao, HUANG Xiangyong, GU Mingyan
Journal of Engineering Thermophysics. 2025, 46(3): 1003-1008.
In the context of national energy conservation and carbon peaking and carbon neutrality, energy conservation, emission reduction and carbon reduction in the cement industry is a very important task. Oxy-fuel combustion is beneficial to increase the temperature in the cement rotary kiln, increase the clinker output, reduce coal consumption and improve the adaptability of coal types, but the increase of oxygen concentration increases the NOx emission compared with the conventional oxygen concentration combustion. In this paper, the effects of primary air oxygen concentration, flue gas recirculation rate and excess air coefficient on the oxygen-rich combustion characteristics of pulverized coal in cement rotary kiln were analyzed by numerical simulation method. The results show that with the increase of primary air oxygen concentration, the flame length in the kiln becomes shorter, and when the primary air oxygen concentration increases from 21% to 33%, the maximum temperature in the rotary kiln increases from 1964 K to 2071 K. The addition of circulating flue gas reduces the oxygen concentration in the kiln, makes the combustion performance of volatiles in pulverized coal and coke worse, reduces the combustion effect, and reduces the combustion temperature in the kiln. As the excess air coefficient increases, the temperature in the rotary kiln decreases.