Tannery wastewater treatment using combined electrocoagulation and electro-Fenton processes

Abstract

Tannery wastewater was performed using electrocoagulation (EC) coupled with an electro-Fenton (EF) process and boron-doped diamond (BDD) anodes to generate hydrogen peroxide (H2O2), and then optimized using the response surface methodology (RSM). Effects of three independent variables (e.g., reaction time, current density and Fe2+ concentration) on the performance of electrochemical processes were analyzed using a statistical experimental design. Current density and reaction time were significant for total organic carbon (TOC) removal when the EC and EF processes were tested. The interaction between initial Fe2+ concentration (0.66 mM L-1, the highest value) and reaction time was significant and achieved 32% TOC removal, but because it was used with the highest current density value tested (70 mA cm-2), the energy consumption was as high as 74.5 kWh m-3. Optimization of the process for TOC removal and energy consumption was accomplished by lowering the current density and treatment time values (40 mA cm-2 and 217 min) during EF treatment. Under these conditions, 25% of TOC removal was achieved. The integrated EC-EF system generated 64% TOC removal using a greater current density (9.7 mA cm-2) during the EC process, and the overall treatment energy consumption was 22.3 kWh m-3. The sludge produced under the tested EC conditions exhibited no hazardous characteristics. The EC treatment was also faster in TOC abatement (sixth-order kinetic), compared to the EF treatment (third-order kinetic).