Effects of fouling and scaling on the retention of trace organic contaminants by a nanofiltration membrane: The role of cake-enhanced concentration polarisation

Citation data:

Separation and Purification Technology, ISSN: 1383-5866, Vol: 73, Issue: 2, Page: 256-263

Publication Year:
2010
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Repository URL:
https://works.bepress.com/long_nghiem/81; https://ro.uow.edu.au/engpapers/5502
DOI:
10.1016/j.seppur.2010.04.010
Author(s):
Dirk Vogel; Alexander Simon; Abdulhakeem Ali Alturki; Bernd Bilitewski; William E. Price; Long D. Nghiem
Publisher(s):
Elsevier BV
Tags:
Chemistry; Chemical Engineering; Engineering
article description
The combined impact of humic acid fouling and CaCO 3 scaling on the retention of trace organic contaminants by a commercially available nanofiltration membrane was investigated in this study. Due to the presence of humic acid in the feed solution, CaCO 3 scaling behaviour differed substantially from that of a pure CaCO 3 solution. A prolonged induction period was consistently observed prior to the onset of membrane scaling. In addition, membrane scaling following humic acid fouling did not result in a complete loss of permeate flux. This is consistent with the absence of any large CaCO 3 crystals. In fact, the CaCO 3 crystals on the membrane surface were quite small and similar in size, which would result in a relatively porous cake layer. At the onset of CaCO 3 scaling the retention of all three trace organic contaminants started to decrease dramatically. The observed decrease in retention of the trace organic contaminants was much more severe than that reported previously with a single layer of either organic or colloidal fouling. Such severe decrease in retention can be attributed to the extended cake-enhanced concentration polarisation effect occurring as a result of the combination of membrane fouling and scaling. The porous CaCO 3 scaling layer could lead to a substantial cake-enhanced concentration polarisation effect. In addition, the top CaCO 3 scaling layer could reduce the wall shear rate within the underlying humic acid fouling layer, causing an additional concentration polarisation effect.