厌氧氨氧化反应器研究进展

厌氧氨氧化是废水生物脱氮研究的新领域,厌氧氨氧化反应器影响厌氧氨氧化菌的富集、厌氧氨氧化过程的启动、运行的稳定性和处理效果,是其中十分重要的研究内容.本文根据厌氧氨氧化反应的基本特征,分析了反应过程对反应器的主要要求;通过对固定床反应器、流化床反应器、气提式反应器、上流式厌氧污泥床(UASB)等反应器的运行参数和运行结果的比较,分析了各种类型反应器的主要优缺点,并对反应器今后的发展方向提出了建议.表2参37     

新型生物脱氮技术的工艺研究

以上流式厌氧污泥床反应器（ Ｕ Ａ Ｓ Ｂ） 作为厌氧氨氧化（ａｎａｍ ｍｏｘ） 反应器,用无机盐培养液完成了反应器的启动,并稳态运行ａｎａｍ ｍｏｘ 反应器．采用生物膜反应器作为生物硝化反应器,以无机盐培养液完成反应器的启动．将硝化反应器和ａｎａｍｍｏｘ 反应器组合在一起构成新型生物脱氮系统,以硝化反应器的出水作为ａｎａｍｍｏｘ反应器的进水,同时补充相应数量的 Ｎ Ｈ４ ＋ Ｎ．整个系统的总氮容积去除率可达１ ５７７ ｍｇ Ｌ－ １ ｄ － １ ．该新型生物脱氮系统能同时去除 Ｎ Ｈ４ ＋ Ｎ 和 Ｎ Ｏ Ｘ－ Ｎ,并且对高浓度的 Ｎ Ｈ４ ＋ Ｎ 去除具有较大的潜力．     

铁氨氧化研究进展及在污水脱氮中的应用探索

近几年来,铁氨氧化(Feammox)反应在不同的环境体系中相继被发现. Feammox反应是在厌氧环境中以及微生物的驱使作用下,NH₄⁺和Fe(Ⅲ)分别作为电子供体和电子受体,Fe(Ⅲ)被还原生成为Fe(Ⅱ),而NH₄⁺则转化生成为亚硝酸盐(NO₂^-)、硝酸盐(NO₃^-)和氮气(N₂)几种不同形态的氮素.Feammox的发现进一步揭示了氮素在自然界循环中的新的转化途径,这种新的氮素转换途径给污水领域中的脱氮技术方法带来了全新视角.另外,Feammox能够和厌氧氨氧化(Anammox)和铁型反硝化(NDFO)耦合或者通过实现Fe(Ⅲ)和Fe(Ⅱ)之间的循环转化进行脱氮,使得Feammox成为了一种潜在的新型脱氮技术.通过综述Feammox的发展历程、反应机制、以及对自然界生态系统所产生的的影响和其所受影响的物理性因素,最后,进一步探讨Feammox在污水脱氮中的应用,并对其未来发展进行总结和展...     

新型废水生物脱氮的微生物学研究进展

生物脱氮是含氮废水处理公认的最佳处理方式,随着对生物脱氮微生物学原理研究的不断深入,许多新的生物脱氮特殊菌株或菌群及微生物转化机制不断被发现.本文在传统生物脱氮过程机理上,结合最近国内外生物脱氮的新发现,就短程硝化反硝化、同时硝化反硝化、厌氧氨氧化的微生物学原理进行了阐述.图1表2参23     

厌氧氨氧化电子受体的研究

研究发现,除已经证实的硝酸盐外,常规生物反硝化反应的两种中间产物亚硝酸和Ｎ２Ｏ也能用作氨厌氧氧化的电子受体;厌氧氨生物氧化的主要产物为Ｎ２．     

垃圾渗滤液生物脱氮新途径

介绍了垃圾渗滤液的传统脱氮技术，对短程硝化反硝化、同步硝化反硝化和厌氧氨氧化的研究作了综述和讨论，并分析了这些新技术的特点以及在垃圾渗滤液脱氮方面的研究和应用前景，指出了厌氧氨氧化是垃圾渗滤液生物脱氮可能的有效方法。     

电子受体及中间产物对厌氧氨氧化的影响

研究了厌氧氨氧化混合培养物对不同基质(硝酸盐、亚硝酸盐)的转化特性，确定了氨和硝酸盐、亚硝酸盐转化比例(物质的量)分别为1.085、0.897．亚硝酸盐转化成硝酸盐的比率为14.97％．在培养液中加入厌氧氨氧化的中间产物羟胺可以加速反应的进行．图3表2参9     

COD对颗粒污泥厌氧氨氧化反应性能的影响

研究了COD对颗粒污泥厌氧氨氧化反应的影响,并对颗粒污泥的厌氧氨氧化脱氮性能进行了分析.厌氧颗粒污泥取自实验室长期运行的EGSB生物脱氮反应器,实验用水为人工配水,以葡萄糖为有机碳源;主要考察了COD对NH4 -N、NO2--N、NO3--N和TN去除的影响.结果表明:当进水不含COD时,反应器对NH4 -N、NO2--N和NO3--N和TN的去除率分别为12.5%、29.1%、16.1%和16.3%;当COD浓度分别为200mg/L、350mg/L和550mg/L时,反应器对NH4 -N的去除率分别为14.2%、14.2%和23.7%,对NO2--N的去除率均接近100%,对NO3--N的去除率分别为94.5%、86.6%和84.2%,对TN的去除率分别为50.7%、46.9%和50.4%,COD去除率分别为85%、66%和60%.分析发现,在反应初期,氨氮的去除主要通过厌氧氨氧化过程实现,随着反应的进行,反硝化菌活性逐渐提高,传统的反硝化过程占优势.同时还观察到,在反应初期COD对氨氮去除的抑制作用非常明显.图2参21     

厌氧氨氧化工艺的抑制现象

厌氧氨氧化(Anammox)工艺因其高效低耗优势,在废水生物脱氮领域中具有广阔的应用前景.然而,基质、有机物、盐度、重金属、磷酸盐及硫化物等物质对Anammox工艺产生的抑制作用制约了工艺的推广应用.基质主要通过游离氨和游离亚硝酸对Anammox产生抑制,而温度和pH是基质抑制的重要调控参数.非致毒性有机物对Anammox的作用因其种类跟浓度而异.在较低的浓度条件下对Anammox的抑制作用不显著,而高于抑制阈值将严重抑制Anammox.其抑制机制尚无定论.部分研究证明致毒性有机物(醇、醛、酚及抗生素等)对Anammox具有抑制作用,但研究有待拓展深化.超过抑制阈值的盐度会抑制Anammox活性,但合适的盐度(3~15 g L-1NaCl)却能够促进Anammox生物颗粒的形成.重金属对Anammox的抑制报道较少.因试验条件及菌种等的差异使得磷酸盐及硫化物对Anammox的抑制在不同试验中存在很大差异.Anammox抑制是可控的,通过pH和温度调节、基质浓度及负荷控制、污泥驯化以及添加辅助剂等方法可解除或缓解抑制.建议今后在特种废水的Anammox脱氮、复合抑制以及Anammox抑制的分子生态学机理等方面开展深入研究.     

低氨氮垃圾渗滤液中有机污染物厌氧氨氧化处理

采用上流式厌氧污泥床处理某垃圾填埋场渗滤液.实验结果表明,在厌氧氨氧化活性稳定后,反应器对氨氮、亚硝氮具有较好的处理效果,氨氮和亚硝氮的平均去除率分别达到98.42%和99.01%,相应的平均容积去除负荷分别为93.64 mg·l-1·d-1和127.57 mg·l-1·d-1,COD的平均去除率为23.51%,平均容积去除负荷为84.53 mg·l-1·d-1.通过GC-MS总共检测出48种主要有机污染物,其中14种有机物的去除率为100%,2种有机物的去除率介于90%和100%之间,7种有机物的去除率介于50%和90%之间,此外还有13种有机物去除率低于50%,反应中亚硝氮和氨氮的去除率比值为1.37,反应器中存在厌氧氨氧化和反硝化的协同作用.     

Methanation and chemolitrophic nitrogen removal by an anaerobic membrane bioreactor coupled partial nitrification and Anammox

● Efficient carbon methanation and nitrogen removal was achieved in AnMBR-PN/A system. ● AOB outcompeted NOB in PN section by limiting aeration and shortening SRT. ● The moderate residual organic matter of PN section triggered PD in anammox unit. ● AnAOB located at the bottom of UASB played an important role in nitrogen removal. An AnMBR-PN/A system was developed for mainstream sewage treatment. To verify the efficient methanation and subsequent chemolitrophic nitrogen removal, a long-term experiment and analysis of microbial activity were carried out. AnMBR performance was less affected by the change of hydraulic retention time (HRT), which could provide a stable influent for subsequent PN/A units. The COD removal efficiency of AnMBR was > 93% during the experiment, 85.5% of COD could be recovered in form of CH₄. With the HRT of PN/A being shortened from 10 to 6 h, nitrogen removal efficiency (NRE) of PN/A increased from 60.5% to 80.4%, but decreased to 68.8% when the HRT_PN/A further decreased to 4 h. Microbial analysis revealed that the highest specific ammonia oxidation activity (SAOA) and the ratio of SAOA to specific nitrate oxidation activity (SNOA) provide stable NO₂⁻-N/NH₄⁺-N for anammox, and anammox bacteria (mainly identified as Candidatus Brocadia) enriched at the bottom of Anammox-UASB might play an important role in nitrogen removal. In addition, the decrease of COD in Anammox-UASB indicated partial denitrification occurred, which jointly promoted nitrogen removal with anammox.     

纤毛状生物膜脱氮除磷工艺调试研究

纤毛状生物膜脱氮除磷工艺(CNR)是一种高效的生物脱氮除磷工艺.好氧池中纤毛状生物膜填料的添加,固化了大量世代时间长的硝化菌,提高了硝化反应速度,而且成功地解决了好氧段硝化菌与聚磷菌的泥龄矛盾.通过对天津某污水处理厂进行CNR工艺中试,得出结论如下:填料比表面积大,微生物附着量高达1 350～1 500g·m~(-2);填料容易挂膜、脱膜,无堵塞现象,更不需要反冲洗,维护管理简单;填料上形成的生物膜中,微生物体系稳定,种群丰富,微生物相包括钟虫(vorticella)、轮虫(rotaria)、表壳虫(arcella)、吸管虫(tokophrya)等;采用CNR工艺对污水处理,常规项目的去除率均达到80%以上,出水水质除总氮达到一级B标准,其他均达到<城镇污水处理厂污染物排放标准>(GB 18918-2002)的一级A排放标准.     

Reutilize tire in microbial fuel cell for enhancing the nitrogen removal of the anammox process coupled with iron-carbon micro-electrolysis

• MFC promoted the nitrogen removal of anammox with Fe-C micro-electrolysis. • Reutilize pyrolysis waste tire as micro-electrolysis and electrode materials. • Total nitrogen removal efficiency of modified MFC increased to 85.00%. • Candidatus kuenenia and SM1A02 were major genera responsible for nitrogen removal. In this study, microbial fuel cells (MFCs) were explored to promote the nitrogen removal performance of combined anaerobic ammonium oxidation (anammox) and Fe-C micro-electrolysis (CAE) systems. The average total nitrogen (TN) removal efficiency of the modified MFC system was 85.00%, while that of the anammox system was 62.16%. Additionally, the effective operation time of this system increased from six (CAE system alone) to over 50 days, significantly promoting TN removal. The enhanced performance could be attributed to the electron transferred from the anode to the cathode, which aided in reducing nitrate/nitrite in denitrification. The H⁺ released through the proton exchange membrane caused a decrease in the pH, facilitating Fe corrosion. The pyrolyzed waste tire used as the cathode could immobilize microorganisms, enhance electron transport, and produce a natural Fe-C micro-electrolysis system. According to the microbial community analysis, Candidatus kuenenia was the major genus involved in the anammox process. Furthermore, the SM1A02 genus exhibited the highest abundance and was enriched the fastest, and could be a novel potential strain that aids the anammox process.     

溶藻菌对受污染水源水除藻及脱氮特性研究

针对我国水源地藻类污染日趋严重等问题,利用前期分离获得的溶藻菌Streptomyces sp.HJC-D1研究固定化微生物技术强化污染水源水除藻以及脱氮性能。结果表明,对照组和试验组的水体叶绿素a平均去除率分别为（71.66±5.35）%和（80.94±4.36）%,NH4＋—N的平均去除率为（77.76±2.83）%和（72.36±3.18）%,而高锰酸盐指数（CODMn）平均去除率为（24.99±1.52）%和（18.74±1.38）%;不同曝气条件的影响研究发现,曝气/停曝时间比2：4、曝气量60 L.h-1工况下,系统CODMn和NH4＋—N去除率均有所提高,相比对照组NO3-—N积累更为明显;水力停留时间（HRT）变化对系统NH4＋—N、CODMn等的去除影响不大,但缩短HRT时叶绿素a去除率有所降低;分析反应器内填料表面微生物相发现,试验组填料表面有溶藻菌富集,推测对照组除藻主要通过填料对藻类的吸附去除,而试验组则是藻类吸附在填料表面后通过溶藻微生物实现藻类去除。     

厌氧除磷同步脱氮及影响因素研究

采用鸡粪污泥为种泥,在厌氧混合连续流反应装置内进行厌氧还原磷产生磷化氧功能菌的富集,进行硝酸盐、硫酸盐、不同碳源和氮源条件下厌氧除磷效率的研究,并考察磷化氧的生成与硝酸、总磷、氨氮去除的关系.结果表明,(1)SO_4~(2-)-S适宜的投加量为26 mg·L~(-1),不投加NO_3~--N.水中含有氧化态的无机物在厌氧条件下与磷争夺[H]导致厌氧除磷的效率下降.(2)合适的碳源为葡萄糖1 000 mg·L~(-1),纤维素不适合作为碳源,合适的氮源为蛋白胨500 mg·L~(-1),水中含有的还原糖和有机氮源促进磷化氧的生成.(3)pH值控制在6.5～7.0的范围,最适宜的生长温度在35℃左右.(4)氨氮的去除率随着总磷的去除率而增加,在厌氧条件下可达到同时脱氮除磷的效果.磷的去除由厌氧除磷菌还原磷生成磷化氧完成,氨氮由生成氮气或生成蛋白质来去除.     

表面流人工湿地中氮磷的去除机理

人工湿地作为一种高效、低耗的污水处理新工艺已被广泛接受，特别是其在脱氮、除磷方面的应用逐步为人们所重视。本文深入地讨论了表面流人工湿地中各种生物、物理、化学过程对污水中各种形态含氮、含磷化合物的去除机理，及其具体途径、相关反应和反应类型，总结了国内外对各个过程影响因素、控制条件、反应速度、去除能力及相互之间协调拮抗作用的研究结果。虽然硝化／反硝化作用和土壤吸附沉淀作用已被公认为是表面流人工湿地脱氮、除磷的主要途径，但不同研究结果之间仍存在着明显差异，鲜有多介质环境条件下各种脱氮、除磷过程中多种氮、磷形态的质量平衡研究，而以此为基础的人工湿地生态动力学模型的研究则是深入了解人工湿地运行机理、设计和预测其处理效率，以及推动人工湿地污水处理工艺广泛应用的关键。     

厌氧-好氧生物除磷影响因素的控制

采用厌氧-好氧生物除磷工艺,研究了两个关键因子--化学需氧量与磷的比值和污泥负荷对系统除磷效果的影响及其控制.结果表明,原污水中化学需氧量与磷的比值越高,厌氧放磷越多,越有利于除磷;厌氧放磷与厌氧吸收碳源呈正相关;并且,进水化学需氧量与磷的比值的变化对整个系统碳源污染物的去除效果不会产生明显的影响.试验发现,厌氧条件下聚磷菌贮存碳源的多寡并不完全依赖于高能磷酸键水解提供的能量,原污水中化学需氧量越多,越有利于厌氧碳源的贮存.若要达到好的除磷效果,系统的污泥负荷必须控制在0.21～0.5 kg/(kg·d)之间,且污泥负荷越高,除磷效果越佳.     

Research on polyhydroxyalkanoates and glycogen transformations: Key aspects to biologic nitrogen and phosphorus removal in low dissolved oxygen systems

In this paper, a study was conducted on the effect of polyhydroxyalkanoates (PHA) and glycogen transformations on biologic nitrogen and phosphorus removal in low dissolved oxygen (DO) systems. Two laboratory-scale sequencing batch reactors (SBR1 and SBR2) were operating with anaerobic/aerobic (low DO, 0.15–0.45 mg·L^-1) configurations, which cultured a propionic to acetic acid ratio (molar carbon ratio) of 1.0 and 2.0, respectively. Fewer poly-3-hydroxybutyrate (PHB), total PHA, and glycogen transformations were observed with the increase of propionic/acetic acid, along with more poly-3-hydroxyvalerate (PHV) and poly-3-hydroxy-2-methyvalerate (PH2MV) shifts. The total nitrogen (TN) removal efficiency was 68% and 82% in SBR1 and SBR2, respectively. In the two SBRs, the soluble ortho-phosphate (SOP) removal efficiency was 94% and 99%, and the average sludge polyphosphate (poly-P) content (g·g-MLVSS^-1) was 8.3% and 10.2%, respectively. Thus, the propionic to acetic acid ratio of the influent greatly influenced the PHA form and quantity, glycogen transformation, and poly-P contained in activated sludge and further determined TN and SOP removal efficiency. Moreover, significant correlations between the SOP removal rate and the (PHV+ PH2MV)/PHA ratio were observed (R²>0.99). Accordingly, PHA and glycogen transformations should be taken into account as key components for optimizing anaerobic/aerobic (low DO) biologic nitrogen and phosphorus removal systems.     

Enhanced nitrogen removal reliability and efficiency in integrated constructed wetland microcosms using zeolite

The purpose of this study is to reduce the seasonal fluctuation and enhance the efficiency of nitrogen removal in vertical flow-horizontal subsurface flow (VF-HSF) constructed wetlands. Two sets of VF-HSF constructed wetlands were built, VF1-HSF1 and VF2-HSF2, and a zeolite section was placed in VF2. The results showed that VF2-HSF2 compared to VF1-HSF1 was not only a more reliable nitrogen removal method, but also enhanced the nitrogen removal efficiency by 50%. The average apparent rate of nitrogen removal in VF2-HSF2 reached to 2.52 gN·m^-3·d^-1, which doubled the rate in VF1-HSF1. Plant uptake and organic nitrogen sediment accounted for 12% and 6% of the total nitrogen removal in VF1-HSF1, respectively, and 10% and 4% in VF2-HSF2, respectively. Biologic nitrogen removal was the dominant mechanism, which accounted for 79% and 87% of the total nitrogen removal in VF1-HSF1 and VF2-HSF2, respectively. Ammonia adsorbed by zeolite during the cold seasons was desorbed, and then nitrified in warm seasons, which resulted in a bioregeneration efficiency of 91%. Zeolite in VF was capable of transferring ammonia from cold seasons to warm seasons as well as enhancing nitrification, which was accompanied by high potential denitrification in HSF that reinforced the efficiency and relieved seasonal fluctuation of nitrogen removal in VF-HSF.