4.2 Article

Vibrating MBR with Settling Zone for High-Flux Domestic Wastewater Treatment: Enhanced Nitrogen Removal and Fouling Mitigation

Journal

ACS ES&T WATER
Volume 2, Issue 6, Pages 1013-1021

Publisher

AMER CHEMICAL SOC
DOI: 10.1021/acsestwater.2c00001

Keywords

vibrating ceramic membrane; high; fl ux operation; settling zone; nitrogen removal; fouling control; fouling characteristics

Funding

  1. NUS Research Scholarship (PVO-SP)

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This study proposed an optimized hybrid vibrating ceramic MBR with a settling zone to achieve long-term high-flux operation for domestic wastewater treatment. The introduction of the settling zone enhanced nitrogen removal efficiency and reduced membrane fouling, while also lowering biomass and EPS concentrations to mitigate fouling. This energy-efficient VCMBR has the potential to advance high-flux MBR technology for future decentralized wastewater treatment.
High-flux operation remains a major challenge in membrane bioreactor (MBR) applications due to membrane fouling. This study proposed an optimized hybrid vibrating ceramic MBR (VCMBR) with a settling zone (SZ) to achieve long-term high-flux (40 LMH) operation for domestic wastewater treatment compared to a conventional air-sparging ceramic MBR (ASCMBR). Results showed that the VCMBR could be operated at 40 LMH with excellent organics and ammonium removal and slowed membrane fouling for over 1 week without any backwash. The introduction of SZ into the VCMBR enhanced the average TN removal efficiencies up to 68.1%, which were much higher than 29.1% in the ASCMBR with SZ. Reversible and irreversible fouling were simultaneously reduced in the VCMBR due to significant reductions of the DOMs in the fouling layer. Importantly, membrane vibration without strongly scouring the biomass could reduce the extracellular polymeric substances (EPSs) release and restrict the fouling sources, leading to better fouling control. Additionally, SZ helped lower the biomass concentrations in the membrane separation area, inducing lower EPS concentrations and thus showing less fouling propensity in both MBRs. Overall, the synergetic effects on enhancing nitrogen removal and fouling mitigation by this energy-efficient VCMBR could potentially advance high-flux MBR technology for future decentralized wastewater treatment.

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