EFFECTS OF CARBON RESOURCE ADDITON STRATEGIES ON PHOSPHORUS AND NITROGEN REMOVAL AND MICROBIAL COMMUNITY STRUCTURE IN AN A2/O SYSTEM
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摘要: 为揭示碳源投加方式对低碳污水氮磷去除影响,采用A2/O系统处理模拟低C/N(C/N为2.0~4.0)污水,分别在污泥回流池、进水端投加碳源,对比研究2种方式条件下的系统氮磷污染物去除效果及微生物菌群结构特点。结果表明:与传统进水端投加碳源方式(阶段Ⅳ)相比,在污泥回流池投加等量碳源(阶段Ⅲ),有利于实现更佳的脱氮除磷效果。阶段Ⅲ的TN、TP去除率分别为54.5%、63.9%,高于阶段Ⅳ的氮、磷去除率(TN和TP去除率分别为44.9%、21.7%)。高通量测序结果表明:2种碳源投加方式均改变了微生物菌群丰富度和多样性,且在污泥回流池投加碳源更有利于优势菌群的富集,该阶段红游动菌属(Rhodoplanes,2.3%)、脱氯单胞菌属(Dechloromonas,1.6%)及生丝菌属(Hyphomicrobium,1.4%)为优势菌属,其比例均高于阶段Ⅳ。Abstract: To reveal the effect of carbon resource addition strategies on nitrogen and phosphorus removal in low carbon wastewater, an A2/O system was employed to treat the simulated low C/N wastewater(C/N 2.0~4.0) with carbon resource addition respectively at the sludge return tank and the water inlet. The nitrogen and phosphorus removal efficiency and microbial community structure were comparatively investigated under different conditions.Resultsshowed that higher removal efficiency of nitrogen and phosphorus was easily achieved by adding the same amount of carbon source to the sludge return tank(stage Ⅲ), compared with the traditional way of adding carbon source at the water inlet(stage Ⅳ). When the A2/O system was stably operated at stage Ⅲ, the removal rate of TN and TP was 54.5% and 63.9% respectively, higher than that at stage Ⅳ(the removal rate of TN and TP was 44.9% and 21.7%, respectively). High-throughout sequencing results indicated that the microbial abundance and diversity changed with carbon resource addition strategies. Meanwhile, the way of adding carbon source to the sludge return tank was conducive to the enrichment of dominant flora. Rhodoplanes(2.3%), Dechloromonas(1.6%) and Hyphomicrobium(1.4%) was the dominant genus at stage Ⅲ, and the proportions of the above three genus were also higher than that in stage Ⅳ when the carbon resource was added to the inlet.
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Key words:
- A2/O process /
- adding way /
- nutrient removal /
- microbial community structure
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