TY - JOUR
T1 - Enhanced removal of natural organic matter by hybrid process of electrocoagulation and dead-end microfiltration
AU - Ben-Sasson, Moshe
AU - Zidon, Yehoyada
AU - Calvo, Rivka
AU - Adin, Avner
PY - 2013/10
Y1 - 2013/10
N2 - The significant role played by natural organic matter (NOM) in aquatic environments and water purification processes motivates the critical need to optimize its removal by membrane filtration. This work studied the performances of hybrid process that combines electrocoagulation (EC) and dead-end microfiltration (MF) to remove NOM. Both iron and aluminum were used as the anode materials under experimental conditions of pH 6, 7 and 8. Filtration performance was characterized by NOM removal rates and the time needed to filter 750. mL of solution. The results revealed that both iron- and aluminum-based electrocoagulation pretreatment can mitigate NOM fouling and improve NOM removal rates. Still, improved NOM removal due to EC pretreatment was not necessarily followed by fouling mitigation and, in some conditions, a severe fouling effect coupled with improved removal rates was observed. In general, the positive effect of EC on fouling was observed both at the initial stage and during the late stages of filtration. Both fouling mitigation intensity and improved removal rates were strongly dependent on initial pH value, EC operation time and type of electrode. The most significant improvement in MF performance due to iron- or aluminum-based EC was observed at pH 6. At higher pHs (7 and 8), the iron electrode was favored over the aluminum electrode.At optimal conditions, a 36-fold shorter filtration time and a 20% increase in NOM removal rates were observed with the EC-MF hybrid process as compared to 100. kDa ultrafiltration alone. These observations emphasize the high potential to incorporate an EC-MF hybrid process into NOM removal methods, due to its ability to facilitate high fluxes, low fouling, and high colloidal/NOM removal.
AB - The significant role played by natural organic matter (NOM) in aquatic environments and water purification processes motivates the critical need to optimize its removal by membrane filtration. This work studied the performances of hybrid process that combines electrocoagulation (EC) and dead-end microfiltration (MF) to remove NOM. Both iron and aluminum were used as the anode materials under experimental conditions of pH 6, 7 and 8. Filtration performance was characterized by NOM removal rates and the time needed to filter 750. mL of solution. The results revealed that both iron- and aluminum-based electrocoagulation pretreatment can mitigate NOM fouling and improve NOM removal rates. Still, improved NOM removal due to EC pretreatment was not necessarily followed by fouling mitigation and, in some conditions, a severe fouling effect coupled with improved removal rates was observed. In general, the positive effect of EC on fouling was observed both at the initial stage and during the late stages of filtration. Both fouling mitigation intensity and improved removal rates were strongly dependent on initial pH value, EC operation time and type of electrode. The most significant improvement in MF performance due to iron- or aluminum-based EC was observed at pH 6. At higher pHs (7 and 8), the iron electrode was favored over the aluminum electrode.At optimal conditions, a 36-fold shorter filtration time and a 20% increase in NOM removal rates were observed with the EC-MF hybrid process as compared to 100. kDa ultrafiltration alone. These observations emphasize the high potential to incorporate an EC-MF hybrid process into NOM removal methods, due to its ability to facilitate high fluxes, low fouling, and high colloidal/NOM removal.
KW - Coagulation
KW - Electrocoagulation
KW - Electroflocculation
KW - Microfiltration
KW - Natural organic matter
KW - Ultrafiltration
UR - http://www.scopus.com/inward/record.url?scp=84883022771&partnerID=8YFLogxK
U2 - 10.1016/j.cej.2013.07.101
DO - 10.1016/j.cej.2013.07.101
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AN - SCOPUS:84883022771
SN - 1385-8947
VL - 232
SP - 338
EP - 3345
JO - Chemical Engineering Journal
JF - Chemical Engineering Journal
ER -