Osmotic versus conventional membrane bioreactors integrated with reverse osmosis for water reuse: Biological stability, membrane fouling, and contaminant removal

Wenhai Luo,Hop V Phan,Ming Xie,Faisal I Hai,William E Price,Menachem Elimelech,Long D Nghiem

doi:10.1016/j.watres.2016.11.036

Abstract

This study systematically compares the performance of osmotic membrane bioreactor – reverse osmosis (OMBR-RO) and conventional membrane bioreactor – reverse osmosis (MBR-RO) for advanced wastewater treatment and water reuse. Both systems achieved effective removal of bulk organic matter and nutrients, and almost complete removal of all 31 trace organic contaminants investigated. They both could produce high quality water suitable for recycling applications. During OMBR-RO operation, salinity build-up in the bioreactor reduced the water flux and negatively impacted the system biological treatment by altering biomass characteristics and microbial community structure. In addition, the elevated salinity also increased soluble microbial products and extracellular polymeric substances in the mixed liquor, which induced fouling of the forward osmosis (FO) membrane. Nevertheless, microbial analysis indicated that salinity stress resulted in the development of halotolerant bacteria, consequently sustaining biodegradation in the OMBR system. By contrast, biological performance was relatively stable throughout conventional MBR-RO operation. Compared to conventional MBR-RO, the FO process effectively prevented foulants from permeating into the draw solution, thereby significantly reducing fouling of the downstream RO membrane in OMBR-RO operation. Accumulation of organic matter, including humic- and protein-like substances, as well as inorganic salts in the MBR effluent resulted in severe RO membrane fouling in conventional MBR-RO operation.

Highlights

Water scarcity due to population growth, urbanization, climate change, and environmental pollution is a vexing challenge to the sustainable development of our society (Elimelech and Phillip, 2011)
It is noteworthy that an MF or UF membrane was coupled with osmotic membrane bioreactor (OMBR) in these two studies to control salinity build-up, which is an inherent issue associated with OMBR due to the high salt rejection by the forward osmosis (FO) membrane and, more importantly, the reverse draw solute flux
This study aims to compare the performance of osmotic membrane bioreactor – reverse osmosis (OMBR-reverse osmosis (RO)) with conventional membrane bioreactor – reverse osmosis (MBR-RO) in terms of biological stability, contaminant removal, and membrane fouling

Summary

Introduction

Water scarcity due to population growth, urbanization, climate change, and environmental pollution is a vexing challenge to the sustainable development of our society (Elimelech and Phillip, 2011). This challenge calls for further efforts to develop and improve technologies that can tap into alternative water sources, such as municipal wastewater, to enhance water supply and mitigate water shortage. Membrane bioreactor (MBR) is a well-known technology for wastewater treatment and water reuse. MBR combines conventional activated sludge (CAS) treatment and a physical membrane filtration process, typically including microfiltration (MF) and ultrafiltration (UF)

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