Nonisothermal Investigation of Reaction Kinetics between Electric Arc Furnace Dust and Calcium Chloride under Carbon-Containing Conditions

Abstract

The volatilization of zinc in the electric arc furnace dust–CaCl₂ and ZnFe₂O₄–ZnO–CaCl₂–C reaction systems was investigated. Experiments were conducted under an N₂ atmosphere in an infrared lamp heating furnace, and the activation energy of the reaction rate of zinc volatilization was determined by the Ozawa method. The activation energy in the dust–CaCl₂ reaction system was 123 ± 27 kJ/mol; when the dust was decarburized, the activation energy was reduced to 84 ± 4 kJ/mol. Further, the simultaneous carbothermic reduction by the carbon contained in the dust and chloride volatilization of zinc improved the reaction rate. In the temperature range where carbothermic reduction and chlorination occur simultaneously, carbothermic reduction is favored. The reduction of metal oxides in the dust inhibits the chlorination and carbothermic reduction of zinc, reducing the reaction rate and activation energy.

Effect of heating rate on zinc reaction rate from dust-CaCl₂ reaction system (Zn:CaCl₂:C = 1:1:0.464 (mol)).