| Abstrakt: |
The production of commercially important rare-earth elements in significant proportions also leads to the problem of industrial effluents containing metal oxides, cyanides, etc. generated from mining, mineral processing, and metallurgical operations. In the current work, ultrasound (US)-based methods are used for treatment of commercially obtained effluent from rare-earth metal processing industry containing ammonium thiocyanate (NH4SCN) as a major target contaminant. The effect of operating parameters as pH (actual values as 1, 3, 7, 9, 12), H2O2loading (800 to 1400 ppm), O3flow rate (0.5 to 2 L/min), and catalyst type (TiO2or MnO2at fixed loading of 1 g/L) on the efficacy of treatment was studied. The treatment of effluent using the approaches of US and ozone (flow rate as 0.5 L/min) alone under the constant conditions of 120 W and 70% duty cycle showed no chemical oxidation demand (COD) reduction; however, it was significantly improved on combination giving 54.83% reduction. Under optimized conditions, the approach of US + O3at flow rate of 0.5 L/min and pH of 12 combined with H2O2(1200 ppm) and catalyst TiO2(1g/L) gave still higher COD reduction as 64.28% and 69.45%, respectively. The degradation of the contaminants using the US-based approaches followed a first-order kinetic mechanism, and a comparison of different approaches has been presented based on rate constants. Overall, it has been demonstrated that combined treatments based on US + O3in the presence of catalyst can be an effective method for treatment of effluent obtained from rare-earth processing. |
