Abstract
The cost-effective and stable operation of an anaerobic ceramic membrane bioreactor (AnCMBR) depends on operational strategies to minimize membrane fouling. A novel strategy for backwashing, filtration and relaxation was optimized for stable operation of a side stream tubular AnCMBR treating domestic wastewater at the ambient temperature. Two in situ backwashing schemes (once a day at 60 s/day, and twice a day at 60 s × 2/day) maintaining 55 min filtration and 5 min relaxation as a constant were compared. A flux level over 70% of the initial membrane flux was stabilized by in situ permeate backwashing irrespective of its frequency. The in situ backwashing by permeate once a day was better for energy saving, stable membrane filtration and less permeate consumption. Ex situ chemical cleaning after 60 days’ operation was carried out using pure water, sodium hypochlorite (NaOCl), and citric acid as the order. The dominant cake layer was effectively reduced by in situ backwashing, and the major organic foulants were fulvic acid-like substances and humic acid-like substances. Proteobacteria, Firmucutes, Epsilonbacteria and Bacteroides were the major microbes attached to the ceramic membrane fouling layer which were effectively removed by NaOCl.
Highlights
Nowadays, anaerobic membrane bioreactors (AnMBR) have become an emerging and potential technology for domestic wastewater (DWW) treatment and reuse [1]
Membrane fouling was mainly investigated in accordance with the Trans membrane pressure (TMP) evolution on a daily basis [37]
A novel strategy for filtration, relaxation and backwashing with minimal in situ backwashing frequency and short duration was employed for a tubular side stream membrane in an anaerobic ceramic membrane bioreactor (AnCMBR)
Summary
Anaerobic membrane bioreactors (AnMBR) have become an emerging and potential technology for domestic wastewater (DWW) treatment and reuse [1]. Sustainable DWW treatment scenarios highlight this technology since AnMBR distinctly reduces the overall energy demand by producing methane-rich biogas, mineralized nutrients in the form of ammonia and orthophosphate enabling direct agricultural use of the effluent for ferti-irrigation [4]. These unique advantages of AnMBR technology have attracted the interest of both the research and industrial community for its application [5]. AnMBR is still an immature technology with a very limited research and practical applications in developing countries [6]. For developing countries in tropical regions, the ambient temperature operation of AnMBR is profitable, Processes 2020, 8, 545; doi:10.3390/pr8050545 www.mdpi.com/journal/processes
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