Anammox脱氮工艺应用限制因素的调控策略

doi:10.19965/j.cnki.iwt.2021-0658

摘要/Abstract

摘要：

相比传统脱氮工艺，厌氧氨氧化（Anammox）以其低耗、高效和环境友好备受青睐，具有广阔的发展前景。基质NO₂^--N难获取，厌氧氨氧化菌（AAOB）生长缓慢且对环境敏感使反应器难启动和不完全脱氮限制因素阻碍了Anammox的工程应用。针对Anammox脱氮应用的限制因素，分析了短程硝化（PN）和短程反硝化（PD）途径获取NO₂^--N的调控，解析了反应器快速启动的环境因素、常用的反应器和高活性污泥，并介绍了PN+Anammox，PN+Anammox+反硝化（SNAD）和PD+Anammox三种一体化Anammox工艺的调控策略。

关键词: Anammox, 短程硝化, 短程反硝化, 快速启动, 一体化工艺

Abstract:

Compared with the traditional denitrification process, Anammox is favored for its low consumption, high efficiency and environmental friendliness, and has broad development prospects. The limiting factors including difficult to obtain NO₂^--N, the reactor start-up very difficult because of slow growth of AAOB sensitive to the environment, and incomplete nitrogen removal, hinder the engineering application of Anammox process. This article addressed the limiting factors for the application of the Anammox nitrogen removal. The regulation of NO₂^--N obtained by partial nitrification(PN) and partial denitrification(PD) was analyzed, the environmental factors, commonly used reactors and highly activated sludge which determined the rapid start-up of the reactor were discussed, and the regulatory strategies of three integrated Anammox processes including PN+Anammox, PN+Anammox+denitrification(SNAD) and PD+Anammox were introduced.

Key words: Anammox, partial nitrification, partial denitrification, rapid start-up, integrated process

中图分类号:

X703

蒙小俊,郭楠楠,黄志贵. Anammox脱氮工艺应用限制因素的调控策略[J]. 工业水处理, 2021, 41(7): 56-63.

Xiaojun Meng,Nannan Guo,Zhigui Huang. Regulatory strategies of limiting factors for Anammox process application[J]. Industrial Water Treatment, 2021, 41(7): 56-63.

https://www.iwt.cn/CN/Y2021/V41/I7/56

图/表 1

参考文献 65

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表征方法	简要介绍	优点	缺点
分离培养法	采用接种及菌落计数的方法，通过观察微生物的生理特性及形态构造等进行分类鉴定	要求简单，适合分离特定功能的微生物	局限性大，不能单独分离共生细菌
16S r RNA基因序列	通过比较分析16S r RNA基因序列，从而在微生物系统发育上进行分类	能动态观察群落变化	需要与已有的序列比对
高通量测序	将DNA(c DNA)随机片段化、加接头，制备测序文库，对文库中数以万计的克隆进行延伸反应，检测对应的信号，最终获取序列信息	快捷，处理量大，一次可对几百万条DNA分子进行分析	信息的分析和解读能力不足
宏基因组学	对环境样品中全部微生物的总DNA(宏基因组)进行克隆，并通过构建宏基因组文库和对比筛选等手段获得该环境中微生物的遗传多样性和分子生态学信息	可发现难培养或不可培养微生物以及相关的功能基因	文库所包含的微生物基因不全面
实时定量PCR	测量和鉴别非常微量的特异性DNA片段，通过监测CT值而实现对原始目标基因的含量定量	高效快速、操作简便、高度敏感	非特异性扩增和扩增偏差

表征方法	简要介绍	优点	缺点
分离培养法	采用接种及菌落计数的方法，通过观察微生物的生理特性及形态构造等进行分类鉴定	要求简单，适合分离特定功能的微生物	局限性大，不能单独分离共生细菌
16S r RNA基因序列	通过比较分析16S r RNA基因序列，从而在微生物系统发育上进行分类	能动态观察群落变化	需要与已有的序列比对
高通量测序	将DNA(c DNA)随机片段化、加接头，制备测序文库，对文库中数以万计的克隆进行延伸反应，检测对应的信号，最终获取序列信息	快捷，处理量大，一次可对几百万条DNA分子进行分析	信息的分析和解读能力不足
宏基因组学	对环境样品中全部微生物的总DNA(宏基因组)进行克隆，并通过构建宏基因组文库和对比筛选等手段获得该环境中微生物的遗传多样性和分子生态学信息	可发现难培养或不可培养微生物以及相关的功能基因	文库所包含的微生物基因不全面
实时定量PCR	测量和鉴别非常微量的特异性DNA片段，通过监测CT值而实现对原始目标基因的含量定量	高效快速、操作简便、高度敏感	非特异性扩增和扩增偏差

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