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反硝化生物滤池亚硝酸盐积累研究及管控实践

中国给水排水[ISSN:1000-4062/CN:12-1073/TU] 卷: 第41卷期数: 2025年第9期页码: 88-93 栏目: 出版日期: 2025-05-01

Title:: Nitrite Accumulation Investigation and Control Strategies in Denitrifying Biofilter

作者:: 于斓^1,2，李鹏飞^1,2，张达飞^1,2，赵梦升^1,2，孙冀垆^1,2，蒋奇海^1,2，何政²，李魁晓¹，王慰¹，李亚明^1,2，张新勃^1,2; （1.北京城市排水集团有限责任公司，北京 100022；2.北京北排水环境发展有限公司，北京 100124）

Author(s):: YU　Lan^1，2， LI　Peng-fei^1，2， ZHANG　Da-fei^1，2， ZHAO　Meng-sheng^1，2， SUN　Ji-lu^1，2， JIANG　Qi-hai^1，2， HE　Zheng²， LI　Kui-xiao¹， WANG　Wei¹， LI　Ya-ming^1，2， ZHANG　Xin-bo^1，2; （1. Beijing Drainage Group Co. Ltd.， Beijing 100022， China； 2. Beijing Drainage Water Environment Development Co. Ltd.， Beijing 100124， China）

关键词:: 亚硝酸盐; 反硝化生物滤池; 甲醇; 反冲洗周期; 进水负荷; 乙酸钠

Keywords:: nitrite; denitrifying biofilter; methanol; backwash cycle; influent load; sodium acetate

摘要:: 根据反硝化生物滤池脱氮运行时的NO₂^--N积累情况，从甲醇投配率、反冲洗周期、进水负荷、磷浓度、乙酸钠投配率角度进行试验，探究降低NO₂^--N积累量的管控措施。结果表明，当甲醇投配率在20~40 mg/L时，投配率越高，NO₂^--N积累越严重，最高可达6 mg/L以上；不同反冲洗周期以及磷浓度对反硝化菌群未产生明显影响，NO₂^--N积累仍较高；当进水负荷降至50%时，可有效增加脱氮停留时间，出水NO₂^--N稳定在2 mg/L左右，但需根据实际运行设定差异化的负荷配比；更换碳源为乙酸钠后，对NO₂^--N积累的缓解效果较好，最大积累量可控制在2~3 mg/L，可以作为NO₂^--N积累管控的有效措施。

Abstract:: According to the NO₂^--N accumulation observed in the denitrifying biofilter during operation, experiments were carried out from multiple perspectives, including methanol dosing rate, backwash cycle, influent load, phosphorus concentration, and sodium acetate dosing rate, to investigate effective control strategies for mitigating NO₂^--N accumulation. When the methanol dosing rate was in the range of 20-40 mg/L, a higher dosing rate resulted in more severe NO₂^--N accumulation, with the maximum level exceeding 6 mg/L. Different backwash cycles and phosphorus concentrations had no significant impact on the denitrifying bacterial community; however, the accumulation of NO₂^--N remained at a relatively high level. When the influent load was decreased to 50%, the residence time for nitrogen removal could be significantly enhanced, and the effluent NO₂^--N remained consistently below 2 mg/L. However, the differentiated load ratio should be determined based on actual operational conditions. After substituting the carbon source with sodium acetate, the accumulation of NO₂^--N was alleviated, and the maximum accumulation was maintained within the range of 2-3 mg/L. This approach can serve as an effective strategy for controlling NO₂^--N accumulation.

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更新日期/Last Update: 2025-05-01