藻菌生物膜协同光氧作用强化人工废水中硝化反应。

Photo-oxygenation to support nitrification in an algal-bacterial consortium treating artificial wastewater.

机构信息

UNESCO-IHE Institute for Water Education, Department of Environmental Engineering and Water Technology, P.O. Box 3015, 2601 DA Delft, The Netherlands.

出版信息

Bioresour Technol. 2013 Apr;134:244-50. doi: 10.1016/j.biortech.2013.02.005. Epub 2013 Feb 11.

DOI:10.1016/j.biortech.2013.02.005

PMID:23500581

Abstract

Oxygenation by photosynthesis in a mixed culture of algae and nitrifiers was investigated for its potential to support nitrification. An open photo-bioreactor (1L fermentor; 30°C) was inoculated with an enriched culture of nitrifiers obtained from activated sludge and a pure culture of Scenedesmus sp. The reactor was illuminated (60 μmol/m2 s) and operated as a sequencing batch reactor with 50% discharge per cycle and sludge retention time of 15 or 30 days. Full nitrification of synthetic wastewater (50 mgNH4+-N/L) without mechanical aeration was achieved after less than 14 cycles (18.5 h React per 24h cycle) and the biomass steadily increased until a concentration of 1.9 g VSS/L with 29 mg chl-a/L. The maximum observed nitrification rate was 7.7 mgNH4+-N/Lh. A mass balance showed that ammonium removal was primarily by nitrification (81-85%) rather than by ammonium uptake by algae.

摘要

采用藻类和硝化菌混合培养物的光合作用进行氧合，以研究其支持硝化作用的潜力。在一个开放的光生物反应器（1L 发酵罐；30°C）中，接种了从活性污泥中获得的硝化菌富集培养物和纯培养的 Scenedesmus sp. 该反应器受到光照（60 μmol/m2 s），并作为序批式反应器运行，每个周期有 50%的排放，污泥停留时间为 15 或 30 天。在不到 14 个周期（每 24 小时周期 18.5 小时反应）后，无需机械曝气即可实现合成废水（50 mgNH4+-N/L）的完全硝化，并且生物质稳定增加，直到达到 1.9 g VSS/L 和 29 mg chl-a/L。观察到的最大硝化速率为 7.7 mgNH4+-N/Lh。质量平衡表明，铵的去除主要是通过硝化作用（81-85%）而不是藻类对铵的吸收。

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藻菌生物膜协同光氧作用强化人工废水中硝化反应。

Photo-oxygenation to support nitrification in an algal-bacterial consortium treating artificial wastewater.

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