Abstract:The perforation in the carbon block to optimize the structure of anode was researched by using simulation software ANSYS and ANSYS-FLUENT in order to reduce the energy consumption of aluminium reduction industry further more. The industrial test was carried out to study the industrial applications and verify the simulation result. The simulation results show that the bubble layer thickness of the perforated anode is 1.28 cm, reduced by 0.72 cm compared with that of the normal anode, the corresponding voltage is about 240 mV. The minimum temperature of anode block is 704.3 ℃, and the voltage drop of the perforated anode is 379 mV and the current density distribution of the perforated anode and ordinary anode are consistent. The maximum of thermal stress is 17.4 MPa in the perforated anode, which is far less than the allowable stress. The perforated anode industrial test was conducted on three cells. The average cell voltage of perforated anodes decreases by 229 mV compared with the traditional reduction cell after long-term operation, and the current efficiency increases from 91.15% to 91.85%. The production per ton aluminium direct current (DC) consumption of perforated anode reduces by 683 kW∙h. The experimental results agree with the theoretical calculation, which indicates that the polar distance of the perforated anode is decreased because the bubbles exhaust quickly.

Key words: aluminum reduction cell; low power consumption; perforation structure anode; bubble layer thickness; coupled multi-field; numerical simulation; industrial test