Enhanced MBR by internal micro-electrolysis for degradation of anthraquinone dye wastewater

Anthraquinone dyes are very common and refractory pollutants in a wide variety of textile wastewaters and the treatments of these wastewaters have attracted much attention up to now. In this study, a novel enhanced membrane bioreactor (MBR) by internal micro-electrolysis (IE) was successfully applied for treatment of reactive brilliant blue X-BR dye wastewater owing to its high organic matter and nitrogen removal. The main interests were taken in exploring the effect of iron ions released from the IE on properties of biomass and membrane filtration. A hybrid MBR (HMBR) with iron ions fed and an iron controlled MBR (CMBR) were operated in parallel. The biomasses in various MBRs were characterized by sludge volume index (SVI), particle size distributions, concentration of the bound extracellular polymeric substance (EPS), and microscopic structure of the sludge flocs. The results demonstrated that alleviation of membrane fouling in HMBR for a long time was mainly caused by the improvement of settleability and compactability of flocs, as well as the increase in the particle size. As a skeleton frame of aggregations, bound EPS effectively enhanced the bioflocculation of small particles, which was beneficial in controlling membrane biofouling. However, in the last phase, membrane permeability in HMBR continued to drop and tended to be lower than that in CMBR, which mostly attributed to the severely inorganic fouling besides the negative impact of EPS on membrane filterability. Therefore, iron ions control was critical in operation of the enhanced IE/MBR system. (C) 2012 Elsevier B.V. All rights reserved.