Research progress of Anammox-denitrification coupling start up and Influencing Factors

Since anammox can simultaneously remove ammonia and nitrite nitrogen,And low cost,have been researched by many scholars,It high ammonia wastewater treatment has great application value.However,high concentrations of organic carbon on anaerobic ammonium oxidation significantly inhibited.How to achieve anaerobic ammonium oxidation and denitrification coupling,is now a focus of research in the training process anammox bacteria and denitrifying bacteria on pH,organic matter with different requirements,this paper summarizes the anammox and denitrification startup method and pH,organic matter on anaerobic ammonia oxidation and denitrification coupling and explore control strategies for anaerobic ammonium oxidation and denitrification coupling recommendations.

ANAMMOX富集与优化停曝比对MBR-SNAD工艺的影响

采用膜生物反应器(MBR)研究了厌氧氨氧化细菌在富集过程中的活性变化,在启动全程自养脱氮(CANON)工艺中以恒定曝气量,通过优化停曝比实现氨氧化细菌(AerAOB)和厌氧氨氧化细菌(An AOB)协同脱氮并且有效抑制亚硝酸盐氧化菌(NOB)的活性,然后添加有机物(乙酸钠)逐步启动同步亚硝化-厌氧氨氧化耦合异养反硝化(SNAD)工艺.结果表明,在厌氧氨氧化细菌富集过程中,通过不断缩短水力停留时间(HRT)提高进水氮负荷的方式强化厌氧氨氧化细菌活性,其平均活性由0.603mgN/(h·gVSS)提高到了8.1mgN/(h·gVSS);当恒定曝气量为50mL/min,停曝比为4:10(min:min)时,AerAOB和An AOB对氨氮的去除量分别占总氨氮去除量的58.8%和41.2%, NOB氧化亚硝态氮的量占总硝态氮生成量的15.3%,成功抑制了NOB的活性;当C/N比为0.5,调整停曝比为4:15后,反硝化过程氮去除量占总氮去除率的20.9%,厌氧氨氧化过程氮去除量占总氮去除率的79.1%,实现了Aer AOB、An AOB和反硝化细菌(DNB)协同脱氮的目的.

The integration of methanogenesis with denitrification and anaerobic ammonium oxidation in an expanded granular sludge bed reactor

The integration of methanogenesis with denitrification and anaerobic ammonium oxidation(ANAMMOX) was studied in an expanded granular sludge bed(EGSB) reactor in this work. Experimental results from the continuous treatment of wastewater with nitrite and ammonium, which lasted for 107 days, demonstrated that wastewater with high nitrite and ammonium could be anaerobically treated in an expanded granular sludge bed reactor. More than 91% to 97% of COD were removed at up to about 3.9 g COD/(L·d) of COD volumetric loading rate. More than 97% to 100% of nitrite was denitrified at up to about 0.8 g NO -_2-N/(L·d), which is 16 times higher than that in a conventional activated sludge system with nitrification/denitrification(0.05 gN/(L·d)). No dissimilatory reduction of nitrite to ammonium occurred in the process. However, maximum of about 40% ammonium was found to be lost. Batch tests of 15 days with sludge from the reactor showed that 100% of nitrite was denitrified completely, and about 3% of ammonium was removed when only ammonium (34.3 mg/L) and nitrite(34.3 mg/L) were added into the sludge suspension medium. Furthermore, about 15% of ammonium amounts were lost with organic COD addition. It suggested that the methanogenesis in the system could enhance ANAMMOX because of intermediate hydrogen produced during methanogenesis.

Anammox transited from denitrification in upflow biofilm reactor

Anammox was successfully transited from heterotrophic denitrification and autotrophic denitrification in two upflow biofilm reactors, respectively. The results showed that the volumetric loading rate and nitrogen removal efficiency in the reactor transited from heterotrophic denitrification were higher than that in its counterpart. When the hydraulic retention time was 12 h or so, the total nitrogen loading rate was about 0.609 kg N/(m3·d), and the effluent ammonia and nitrite concentrations were less than 8.5 mg/L and 2.5 mg/L, respectively. The upflow anammox biofilm reactor was capable of keeping and accumulating the slow-growing bacteria efficiently. During operation of the reactor, the biomass color was gradually turned from brownish to red, and the ratio of ammonia consumption, nitrite consumption and nitrate production approached the theoretical one. These changes could be used as an indicator for working state of the reactor.

Correlation of anaerobic ammonium oxidation and denitrification

The feasibility of the nitrous organic wastewater treated was studied in seven anaerobic sequencing batch reactors（ASBRs） （0^#-6^#） which had been run under stable anaerobic ammonium oxidation （Anammox）. By means of monitoring and data analysis of COD, NH4^#-N, NO2^--N, NO3^--N and pH, and of microbial test, the results revealed that the optimal Anammox performance was achieved from 2^# reactor in which COD/NH4^＋ -N was 1.65, Anammox bacteria and denitrification bacteria could coexist, and Anammox reaction and denitrification reaction could occur simultaneously in the reactors. The ratio of NH4^＋-N consumed ： NO2^- -N consumed ： NO3^- -N produced was 1：1.38：0.19 in 0^# reactor which was not added glucose in the wastewater. When different ratio of COD and NH4^＋-N was fed for the reactors, the ratio of NO2^- -N consumed： NH4^＋-N consumed was in the range of 1.51-2.29 and the ratio of NO;-N produced： NH4^＋ -N consumed in the range of 0 -0.05.

生活污水SNAD颗粒污泥快速启动及脱氮性能研究

采用SBR装置,接种CANON絮状污泥,通过控制沉淀时间、HRT、DO及进水基质组成(配水与实际生活污水的比例),实现具有SNAD性能颗粒污泥的快速培养,并进一步通过降基质的方式,考察SNAD颗粒污泥在处理实际生活污水时的脱氮性能.结果表明:在反应器运行至第34d时,成功培养出具有SNAD性能的颗粒污泥;颗粒粒径最大可达1103μm,最大总氮去除负荷可达1.03kg/(m^3·d);同时在降基质运行过程中,CANON脱氮始终在反应器总氮去除中占优势地位,并最终实现生活污水中氮素、有机物的同步有效去除,出水TN平均为10mg/L,出水COD平均为40mg/L,达到《城镇污水处理厂污染物排放标准》一级A排放标准.

高氨氮渗滤液处理的ANAMMOX A^2/O工艺研究

通过好氧出水回流到厌氧流化床可以实现厌氧氨氧化过程 .对于高浓度氨氮渗滤液 ,ANAMMOX反应可使ANAMMOXA2 /O工艺比普通A2 /O工艺的TN去除率提高 1 5 %～ 2 0 % ,达 32 %以上 ;好氧出水NO- 2 N浓度有较大幅度地降低 ,改善了出水水质 .ANAMMOX反应总反应级数为 3级 ,对NH+4 N、NO- 3 N和NO- 2 N的反应级数均为 1级 ,反应速率常数为 -3 4 3E -5L2 ·(mmol2 ·h) - 1.

城市生活污水SNAD工艺的启动研究

采用SBR反应器,以城市生活污水为原水,进行同步亚硝化、厌氧氨氧化、反硝化（SNAD）工艺的启动研究.首先接种厌氧氨氧化（anammox）颗粒污泥,在高曝气量下（500L/h）培养得到亚硝化颗粒污泥,然后再次接种anammox颗粒污泥,在低曝气量下（40L/h）培养得到SNAD颗粒污泥.在亚硝化稳定期,氨氮平均去除率达到94%,亚硝态氮平均积累率达到95%.在SNAD稳定期,总氮平均去除率为85%.批试实验结果表明,亚硝化稳定期亚硝化颗粒污泥的好氧氨氮和亚硝态氮氧化活性分别为为0.234和0kg N/（kg VSS·d）.SNAD颗粒污泥的厌氧氨氧化总氮去除、亚硝态氮反硝化、好氧氨氮氧化、好氧亚硝态氮氧化活性分别为0.158、0.104、0.281、0kg/（kg VSS·d）,其中硝态氮反硝化活性在0～120min和120～360min内分别为0.061和0.104kg/（kg VSS·d）.扫描电镜显示,SNAD颗粒污泥表面以短杆状菌和球状菌为主,可能为好氧氨氧化菌（AOB）和反硝化菌,颗粒污泥内部以火山口状的细菌为主,可能为anammox菌。

SNAD生物膜厌氧氨氧化活性的氨氮抑制动力学研究

通过批试实验研究了氨氮浓度对SNAD生物膜厌氧氨氧化性能的影响.SNAD生物膜反应器以生活污水为进水.进水NH_4^+-N和COD浓度平均值分别为70mg/L和180mg/L,出水NH_4^+-N,NO_2^--N,NO_3^--N和COD浓度平均值分别为2mg/L,2mg/L,7mg/L和50mg/L.SNAD生物膜具有良好的厌氧氨氧化活性.初始NH_4^+-N和NO_2^--N浓度都为70mg/L时,厌氧氨氧化批试NH_4^+-N、NO_2^--N和TIN去除速率分别为0.121kg N/(kg VSS·d),0.180kg N/(kg VSS·d)和0.267kg N/(kg VSS·d).采用Haldane模型可以很好的拟合氨氮浓度对厌氧氨氧化活性的影响.在高FA和低FA工况下氨氮浓度对厌氧氨氧化活性的抑制动力学常数相差不大.M1(FA浓度为0.7~20.4mg/L)和M2(FA浓度为6.3~190.5mg/L)的最大NO_2^--N理论去除速率r_(max)分别为0.209kg N/(kg VSS·d)和0.221kg N/(kg VSS·d),氨氮半饱和常数Ks分别为9.5mg/L和6.1mg/L,氨氮自身抑制常数KI分别为422mg/L和597mg/L.氨氮(而不是游离氨)对SNAD生物膜的厌氧氨氧化活性起主要抑制作用.

SNAD反应器中颗粒污泥和絮体污泥脱氮特性

通过血清瓶批试研究了温度为30℃时,SNAD（simultaneous partial nitrification,anaerobic ammonium oxidization and denitrification）反应器内的颗粒污泥R1（1～2.5mm）和絮体污泥R2（0～0.25mm）的脱氮特性.结果表明,颗粒污泥的好氧氨氮和好氧亚硝态氮氧化活性分别为0.166,0kg N/（kg VSS？d）.厌氧氨氧化、亚硝态氮反硝化、硝态氮反硝化总氮去除速率分别为0.158,0.105,0.094kg N/（kg VSS？d）.絮体污泥的好氧氨氮氧化活性和好氧亚硝态氮氧化活性分别为0.180,0kg N/（kg VSS？d）.厌氧氨氧化、亚硝态氮反硝化、硝态氮反硝化总氮去除速率分别为0.026,0.096,0.108kg N/（kg VSS？d）.颗粒污泥和絮体污泥都具有良好的亚硝化性能和反硝化性能.颗粒污泥的厌氧氨氧化性能良好,絮体污泥的厌氧氨氧化性能较差.扫描电镜显示,在SNAD颗粒污泥的表面主要是一些短杆菌和球状菌.在SNAD颗粒污泥中心区域主要为火山口状细菌.在絮体污泥中,同时存在短杆菌,球状菌和火山口状细菌.

城市生活污水SNAD生物膜脱氮特性

通过批试实验研究了同步亚硝化、厌氧氨氧化和反硝化(SNAD)生物膜的脱氮性能.SNAD生物膜具有良好的厌氧氨氧化和反硝化活性.厌氧氨氧化NH_4^+-N、NCV-N和总无机氮(TIN)去除速率分别为0.121,0.180,0.267kgN/(kgVSS·d);反硝化和亚硝态氮氧化活性分别为0.211,0.053kg NO_2^--N/(kg VSS·d).SNAD生物膜厌氧氨氧化适宜的pH值范围为5~9,生物膜有助于缓解pH值对厌氧氨氧化菌的抑制作用.SNAD生物膜对NO_2^--N和FNA的抑制作用表现出良好的耐受能力.当NO_2^--N浓度分别为100,150mg/L时,对应的FNA浓度分别为70,100ng/L,厌氧氨氧化NH_4^+-N去除速率分别为0.087,0.029kg N/(kg VSS·d).扫描电镜显示,在SNAD生物膜表面主要是一些短杆菌.在SNAD生物膜内部主要为火山口状细菌,应为厌氧氨氧化菌.

不同接种物启动Anammox反应器的性能研究

采用上流式生物膜滤器(UBF)研究了以厌氧颗粒污泥和反硝化污泥作为接种物启动厌氧氨氧化(Anammox)反应器的性能.结果表明,2种接种物均能成功启动Anammox反应器.启动过程可分为菌体自溶阶段、活性迟滞阶段、活性提高阶段和活性稳定阶段.这种启动过程的阶段性特征符合Logistic方程.以厌氧颗粒污泥启动Anammox反应器,菌体自溶阶段较长(49d),活性迟滞阶段较短(8d),基质去除速率最高可达2090mg/(L-d);以反硝化污泥启动Anammox反应器,菌体自溶阶段较短(3d),而活性迟滞阶段较长(36d),基质去除速率最高可达1030mg/(L-d).分别以负荷提升前后的基质去除速率、基质去除率以及出水基质浓度的变化情况作为效能指标评价2个反应器运行的稳定性,以厌氧颗粒污泥作为接种物启动Anammox反应器的稳定性能明显占优势.在高负荷率下运行,以反硝化污泥作为接种物启动的Anammox反应器较易失稳.根据启动过程的阶段性和反应器运行的稳定性,对Anammox反应器采取相应的调控对策可促进启动过程的顺利进行.

炭管膜曝气生物膜反应器SNAD脱氮研究

以包裹无纺布的微孔炭管作为膜曝气生物膜反应器（MABR）的膜组件，进行了短程硝化，厌氧氨氧化和反硝化耦合脱氮（SNAD）研究。实验中，控制温度34±1℃，pH7．5～8．5，HRT8h，通过逐步降低膜内压力使反应器中的溶解氧由8mg／L逐步降低到0．5mg／L以下。实验采用亚硝酸细菌挂膜，然后接种厌氧氨氧化细菌，实现在单一反应器中同时发生短程硝化、厌氧氨氧化和反硝化耦合脱氮功能。结果表明，经过180d的连续稳定运行，氨氮去除率达到了93．4％，总氮去除率达到了92．5％，COD去除率达到97．2％，氨氮去除负荷0．6kgN／（m^3·d）。适合SNAD工艺的最佳C／N比为0．2～0．6，当COD浓度过高时，会抑制厌氧氨氧化细菌，使SNAD工艺的处理效果明显下降。

基于SBR反应器的ANAMMOX工艺的启动运行

采用SBR反应器,接种好氧硝化污泥,在142 d内于较高负荷下成功启动了厌氧氨氧化反应器。反应器总氮容积负荷(以N计)为0.43 kg/m3.d,总氮去除率最高达到93.3%,平均为80.5%;氨氮和亚硝酸盐氮的去除率最高达到93.9%和99.8%,平均去除率为81.2%和85.7%。在稳定运行阶段,氨氮去除量、亚硝酸盐氮去除量、硝酸盐氮生成量三者之间的比值为1∶1.38∶0.18。反应器启动过程中,出水、进水pH差值的变化趋势由负到正,然后稳定在一定范围内;且污泥性状有较大变化,污泥中微生物所占比率有所提高,整个反应器中适应厌氧氨氧化运行方式的菌种增殖较快。

ANAMMOX与反硝化协同脱氮反应器的启动特性研究

向成功启动并已稳定运行2年的ANAMMOX反应器中连续添加有机物(葡萄糖),研究ANAMMOX与反硝化协同脱氮反应器的启动特性。结果表明,在短期内(35 d)可成功启动ANAMMOX与反硝化协同脱氮反应器。启动过程可分为迟滞、适应和稳定运行三个阶段,在稳定运行阶段反应器对NH+4-N、NO-2-N、TN和COD的去除率分别高达95%、99%、94%和93%,NH+4-N去除量、NO2--N去除量与NO-3-N生成量的比值为1∶1.32∶0.03,出水碱度和pH均略高于进水。

ANAMMOX与反硝化协同作用及氮素负荷研究

向成功启动并稳定运行630 d后的UASB生物膜反应器系统连续添加有机物,分析其对厌氧氨氧化反应脱氮效果的影响,并进行氮素浓度负荷试验。在厌氧氨氧化反应器系统中连续投加有机COD(葡萄糖),系统运行稳定,有机COD(葡萄糖)存在对系统去除氮素能力影响不大,有机COD去除率达到92.0%,仅用23 d,在同一反应器系统中成功实现了厌氧氨氧化与反硝化协同作用脱氮。氮素浓度负荷试验阶段,进水氨氮(NH4+-N)、亚硝氮(NO2--N)以及总氮(TN)浓度负荷分别从0.063 kg/(m3.d)和0.063 kg/(m3.d)和0.126 kg/(m3.d)提升到了0.239 kg/(m3.d)、0.315 kg/(m3.d)和0.554 kg/(m3.d),相应去除率分别为84.0%、93.0%和85.0%,厌氧氨氧化工艺的UASB生物膜反应器对氮素浓度负荷仍有很大提升空间。

内碳源短程反硝化启动及EPD-ANAMMOX耦合工艺性能

接种普通活性污泥,以乙酸盐为碳源,控制进水COD/P为150:1,在A/O SBR反应器内富集培养了聚糖菌;采用逐渐提高SBR厌氧末硝酸盐投加浓度的方法,将聚糖菌驯化诱导为反硝化聚糖菌结果.SBR厌氧末排水中COD与缺氧末排水基本相同,COD平均去除率达到86.74%,总氮去除率达到98%以上.然后缩短SBR的厌氧及缺氧时间,即可启动内碳源短程反硝化(EPD)系统,缺氧末亚硝酸盐转化率(NTR)平均值为65.96%;表明内碳源短程反硝化与厌氧氨氧化(EPD-ANAMMOX)耦合工艺运行的30d内,COD去除负荷及去除率分别为0.337kgCOD/(kgMLSS·d)及87.21%;总氮去除负荷及去除率分别为0.222kgN/(m^(3)·d)及86.12%,出水中NO_(3)^(-)-N浓度低至4.2mg/L,NO_(2)^(-)-N和NH_(4)^(+)-N浓度接近于零.通过高通量测序,EPD-SBR稳定运行期的污泥与接种污泥相比,具有反硝化功能的聚糖菌属Competibacter丰度从0.001%增加至25.06%,其它聚糖菌属Defluviicoccus、Contendobacter、Sphingobium以及Amaricoccus的总丰度从0.14%增加至0.431%,表明Competibacter是SBR反应器内内碳源短程反硝过程的主要功能菌属.

基于ANAMMOX处理低C/N废水高效脱氮联合工艺研究进展

厌氧氨氧化作为一种高效低廉的生物脱氮技术,在高氨氮、低C/N比废水处理过程中显示出无比的优越性。但是,厌氧氨氧化反应过程中会生成大约11%的硝态氮,在处理高浓度含氨废水时,出水总氮可能达不到行业接管排放标准的要求。反硝化技术作为硝态氮脱除的有效手段,联合反硝化技术势必有利于提高氮素的去除率。针对生成的硝态氮问题,从碳源需求角度,基于短程硝化-厌氧氨氧化联合工艺与反硝化技术实现高效生物脱氮的工艺组合形式进行了介绍,提出了前置反硝化、半反硝化和后置反硝化联合脱氮工艺。并对这些组合工艺的特点、优劣及应用情况进行了简要分析。最后对厌氧氨氧化联合高效脱氮工艺运用于低C/N比废水处理的研究重点进行了展望。

基于ANAMMOX工艺基础上的DEAMOX新型生物脱氮工艺

反硝化氨氧化(DEAMOX)是指在自养反硝化条件下,以硫化物为电子供体,将硝酸盐还原成亚硝酸盐,然后发生以氨氮为电子供体,亚硝酸盐为电子受体的厌氧氨氧化反应。亚硝酸盐的产生和厌氧氨氧化在同一反应器内完成。综述了DEAMOX新型生物脱氮工艺的反应机理、脱氮效果及微生物特性。同时对该工艺的优势及应用前景进行了比较分析。

PD-Anammox快速启动过程中氮代谢功能基因的表达特征

为探究PD-Anammox耦合工艺快速启动过程中基质波动对微生物菌群结构及氮代谢功能基因的响应机制,通过改变进水的基质比例,联合宏基因组学和宏转录组学分析技术,深度解析耦合工艺的脱氮效能、微生物群落结构及氮代谢功能基因的变化规律。结果表明,PD-Anammox工艺的总氮去除率在进水氮源基质改变初期大幅下降,长期运行后其贡献率高达97.1%。变形菌门的相对丰度与进水中硝酸盐氮的含量呈正相关,而浮霉菌门的相对丰度与碳源浓度呈负相关。氮源瞬时冲击时,厌氧氨氧化功能基因hdh/hzo和hzsA/B/C、硝酸盐还原基因napA/B/C和nar B/C、亚硝酸盐还原基因nirS等表达量均显著下降,1 d后厌氧氨氧化和反硝化功能基因表达量显著回升。长期运行后,PD-Anammox耦合系统恢复脱氮效能,与冲击前的系统相比,hdh/hzo和hzsA/B/C基因表达量降低,而nos Z基因表达量升高。