反硝化细菌
曝气
亚硝酸盐
化学
硝化作用
同步硝化反硝化
反硝化
好氧反硝化
环境化学
活性污泥
制浆造纸工业
硝酸盐
氮气
环境工程
生态学
污水处理
生物
环境科学
有机化学
工程类
作者
Thomas Dobbeleers,Jolien D’aes,Solange Miele,Michel Caluwé,Veerle Akkermans,Dominique Daens,Luc Geuens,Jan Dries
标识
DOI:10.1007/s00253-017-8415-1
摘要
In this study, a sequencing batch reactor (SBR), treating synthetic wastewater (COD/N = 5), was operated in two stages. During stage I, an aeration control strategy based on oxygen uptake rate (OUR) was applied, to accomplish nitrogen removal via nitrite >80%. In stage II, the development of aerobic granular sludge (AGS) was examined while two aeration control strategies (OUR and pH slope) maintained the nitrite pathway and optimized the simultaneous nitrification-denitrification (SND) performance. Stimulation of slow-growing organisms, (denitrifying) polyphosphate-accumulating organisms (D)PAO and (denitrifying) glycogen-accumulating organisms (D)GAO leads to full granulation (at day 200, SVI10 = 47.0 mL/g and SVI30 = 43.1 mL/g). The average biological nutrient removal efficiencies, for nitrogen and phosphorus, were 94.6 and 83.7%, respectively. Furthermore, the benefits of an increased dissolved oxygen concentration (1.0–2.0 mg O2/L) were shown as biomass concentrations increased with approximately 2 g/L, and specific ammonium removal rate and phosphorus uptake rate increased with 33 and 44%, respectively. It was shown that the combination of both aeration phase-length control strategies provided an innovative method to achieve SND via nitrite in AGS.
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