Mechanism of NOx Formation from Nitrogen in the Combustion of the Coals Used in Sintering Process

Abstract

The released NOx during fuel combustion is one of the major air pollutants, directly related to acid rain and photochemical smog. At present, there is not an economical and effective method of inhibiting NOx emission from sintering flue gas. Therefore, controlling the conditions of fuel combustion is extremely required for the reduction in NOx. The current research investigated the effects of different combustion parameters on the formation of NOx for three type of coals. The formation of NOx decreased with increasing temperature and heating rate while it increased when oxygen content in an atmosphere increased. Anthracite coal replacement with coke up to 100 pct promoted a decrease in the formed NOx amount and XNO by 21 and 53 pct, respectively. The addition of CaO and FeO enhanced the conversion of nitrogen to NOx, especially at temperatures below 1273 K (1000 °C). Taking both the oxidation reaction to form NOx and reduction reaction of NOx to form N2 into account, the activation energy (EA) values of anthracite and coke were evaluated to be 2.2 and 3.6 kJ/mol, respectively. The combustion of semi-anthracite coal emitted the largest amount of NOx, but the anthracite coal containing less fuel-N than other coals showed the highest value of XNO, which indicates that nitrogen content in coal is not the major factor affecting the formation of NOx. The change in nitrogen functionality after combustion process might be the reason for the unpredicted results in the XNO. The pyrrolic-N in anthracite coal might be considered to be the major functional form that directly affects the conversion of nitrogen to NO.