Mitigation of membrane fouling of alginate with combined actions of aeration and powdered activated carbon: Fouling behaviors and mechanisms

A laboratory‐scale flat‐sheet ceramic microfiltration membrane system was developed to investigate the membrane fouling behaviors and mechanisms of sodium alginate (SA) in the presence of aeration and powdered activated carbon (PAC). When the SA concentration increased from 20 to 500 mg/L, the perme...

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Bibliographic Details
Published in:Water environment research 2022-06, Vol.94 (6), p.e10748-n/a
Main Author: Liu, Ya‐Juan
Format: Article
Language:English
Subjects:
Activated carbon
Aeration
Air
Air flow
Alginic acid
filtration model
Flow rates
Flow velocity
Fluctuations
Fouling
membrane fouling
Membrane processes
Membranes
Microfiltration
Mitigation
powdered activated carbon
Scouring
Seaweed meal
Sodium
Sodium alginate
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Summary:A laboratory‐scale flat‐sheet ceramic microfiltration membrane system was developed to investigate the membrane fouling behaviors and mechanisms of sodium alginate (SA) in the presence of aeration and powdered activated carbon (PAC). When the SA concentration increased from 20 to 500 mg/L, the permeate flux decreased by 81.7%, and the transmembrane pressure (TMP) and resistance increased 1.7 and 24.5 times, respectively. At an SA concentration of 500 mg/L, it was found that the membrane fouling tended to decrease with the increase in the aeration rate, indicating high control of the fouling by air scouring, while PAC–aeration scouring produced a significant improvement in the permeate flux with substantially reduced fouling. In the microfiltration of 500 mg/L SA at an air flow rate of 2.2 L/min and PAC concentrations of 40, 100, and 250 mg/L, the flux increased by 179.3%, 238.0%, and 302.7%, the TMP decreased by 32.6%, 34.8%, and 45.7%, and the cake and pore blocking resistance decreased by 78.0%, 85.1%, and 87.9%, respectively, compared to the corresponding values without PAC–aeration scouring. Intermediate blocking and complete blocking models were confirmed to elucidate the effect of aeration scouring and PAC–aeration scouring on the mitigation of membrane fouling by SA. Practitioner Points Air scouring was effective at mitigating membrane fouling of sodium alginate. The addition of PAC could alleviate membrane fouling of SA. Synergistic scouring by aeration and PAC offers a promising means for more‐efficient and cost‐effective control of membrane fouling. The fouling mechanisms in various scenarios were elucidated. This study investigated the aeration‐ and powdered activated carbon‐assisted mitigation strategies of ceramic membrane fouling by sodium alginate. Powdered activated carbon‐aeration scouring offered a promising means for more efficient and cost‐effective control of membrane fouling. The complete blocking model was confirmed to elucidate the effect of powdered activated carbon‐aeration scouring on the mitigation of membrane fouling by sodium alginate.
ISSN:1061-4303
1554-7531
1554-7531
DOI:10.1002/wer.10748