The fate of selected micropollutants in a single-house MBR

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• 作者：Christian Abegglen ; Adriano Joss ; Christa S. McArdell ; Guido Fink ; Michael P. Schlü ; sener ; Thomas A. Ternes ; Hansruedi Siegrist
• 关键词：Biological degradation ; Decentralized wastewater treatment ; MBR ; Micropollutants ; Water reuse
• 刊名：Water Research
• 出版年：2009
• 出版时间：April 2009
• 年：2009
• 卷：43
• 期：7
• 页码：2036-2046
• 全文大小：418 K

文摘

Membrane bioreactor (MBR) technology is an interesting option for single-house wastewater treatment or small communities. Because typically a very high effluent quality is achieved with respect to pathogens, suspended solids, organics and nitrogen, the permeate is well suited for reuse. Little is known about the fate of micropollutants in such small systems. The differences between centralized and decentralized biological wastewater treatment with respect to micropollutants are manifold: besides the operational parameters like hydraulic and sludge retention time, the main difference is in the load variation. While the influent load is expected to be more or less constant in large catchments, it varies strongly in small MBRs due to irregular consumption (e.g. of medication by individuals). Concentrations of micropollutants are higher by a factor 50–1000 than in centralized treatment. It is also unknown how reliable degradation of micropollutants is in case of irregular exposure.

In this study, two experiments were conducted in a small MBR treating the wastewater of a three-person household. During normal operation of the treatment plant, 25 pharmaceuticals (antibiotics, antiphlogistics, lipid regulators, iodinated contrast media and hormones) that had not been used by members of the household were added in concentrations typical for municipal wastewater. The removal of most substances was in the same range as for centralized wastewater treatment. It was shown that biological transformation was the main elimination process while adsorption to the activated sludge was negligible for most substances due to the low sludge production at high sludge retention time. No appreciable lag for inducing biological degradation was observed. The high hydraulic and sludge residence time had a positive effect on the elimination of slowly degradable substances, but this was partly compensated by the lower biological activity.

An experiment with antibiotics concentrations typical for decentralized treatment (between 500 and 1000 μg l⁻¹; sulfamethoxazole, sulfapyridine, trimethoprim, clarithromycin, roxithromycin) did not show an inhibitory effect on either nitrification or denitrification.