一株荧光假单胞杆菌的分离鉴定与反硝化特性

【目的】从污水厂的活性污泥中获得一株高效反硝化细菌。【方法】采用低温驯化,进行初筛、复筛选取一株反硝化活性最高的菌株,命名为L2,通过形态学、生理生化特征及16S r RNA基因序列分析研究其分类地位,系统研究理化因素对该菌株反硝化性能的影响。【结果】菌株在低温条件下能够稳定高效地进行反硝化,鉴定该菌株为荧光假单胞杆菌(Pseudomonas fluorescens),其反硝化最适接种量为10%,温度为20°C,p H为7.0,盐浓度为0.5%,碳源为葡萄糖,C/N为5.0,能够耐受较高初始硝态氮浓度。【结论】菌株L2是一株耐低温、耐高浓度初始硝态氮、耐低C/N、兼性厌氧、高效反硝化的荧光假单胞杆菌。     

木质纤维素燃料乙醇蒸馏废水的高温厌氧处理及菌群结构分析

【目的】为开发高效的高浓度木质纤维素燃料乙醇蒸馏废水厌氧处理及资源化利用工艺,以活性炭为载体,在实验室规模上对高温厌氧流化床反应器处理木质纤维素燃料乙醇蒸馏废水进行研究。【方法】反应器经65 d梯度驯化后启动,对工艺参数进行一系列优化,并通过基于16S rRNA基因的分子生态学技术分析厌氧污泥中的优势菌群。【结果】实验获得了最优的反应条件和处理效果:厌氧流化床反应器(Anaerobic fluidized bed reactor,AFBR)在温度55±1°C、有机负荷率(OLR)13.8 g COD/(L·d)及水力停留时间(HRT)48 h操作时,COD去除率达到90%以上,同时甲烷产率达到290 mL/g COD;菌群鉴定分析结果显示高温厌氧活性污泥中Clostridia所占比例最大,产甲烷菌属以Methanoculleus和Methanosarcina为主,其它功能菌群主要为Alphaproteobacteria等。【结论】AFBR反应器可高效降解木质纤维素燃料乙醇蒸馏废水并产生生物能源甲烷,其反应体系内微生物种类丰富。     

一个氨氧化菌群的筛选及除氮特性

摘要:【目的】筛选耐受低C/N比、高氨氮环境的高效氨氧化菌群,为开发新型氨氮去除菌剂奠定基础。【方法】采用多点取样、低C/N比、高浓度氨氮废水强行驯化、驯化液连续梯度稀释等步骤,筛选具有高效去除铵氮能力的氨氧化菌群,并考察不同C/N比、摇床转速和铵氮浓度下目的菌群去除铵氮的特性;分离培养目的菌群中的优势菌株,经形态学观察、生理生化特性测定和16S rRNA序列分析对菌株进行鉴定。【结果】筛选到了3个具有较强去除铵氮能力的氨氧化菌群,其中以JQ8活性最好,对初始NH4+ -N 17.86 mmol/L、C/N比为4的合成废水处理6 d后,NH4+-N去除率达到97.01%;在C/N≥4、NH4+-N≤28.57 mmol/L环境下,菌群JQ8对溶液中NH4+-N的6 d去除率均可达95%,净除氮率接近80%。实验室模拟好氧活性污泥处理系统处理线路板工业废水,用菌群JQ8对系统强化处理7 d后NH4+-N和TN去除率分别达到87.8%和67.9%。分析菌群JQ8组成发现,Defluvibacter sp.、Paracoccus sp．和Aquamicrobium sp．细菌为其主要优势菌株。【结论】从垃圾渗滤液中筛选到一个具有较强铵氮去除能力的氨氧化菌群JQ8,可耐受较低C/N比和高氨氮环境,在强化污水处理系统对工业废水氨氮处理中,表现出良好的效果。     

微生物烟气脱硫中硫酸盐还原阶段的限制性因素及其影响

【目的】利用硫酸盐还原菌(SRB)厌氧活性污泥进行烟气脱硫,探索硫酸盐生物还原的最适条件及重金属离子对硫酸盐生物还原的影响,以提高硫酸盐还原阶段的效率。【方法】对取自污水处理厂的SRB厌氧活性污泥进行高浓度硫酸盐胁迫驯化。分析生物脱硫过程中SRB厌氧污泥还原硫酸盐的限制性因素及影响。【结果】在最适生长条件下(pH 6.5,32°C),经驯化获得的SRB厌氧活性污泥有较强的硫酸盐还原能力。Fe2+的适量添加对硫酸盐还原有一定促进作用。SRB厌氧污泥还原硫酸盐的ThCOD/SO42-最适值为3.00,ThCOD=3.33为最适理论化学需氧量,硫酸盐还原率可达72.15%。SRB厌氧污泥还原硫酸盐反应体系中抑制SRB活性的硫化物浓度为300 mg/L。Pb2+和Ni2+在较低的浓度下(1.0 mg/L和2.0 mg/L)对硫酸盐的还原产生较强的抑制作用,而Cu2+在稍高的浓度下(8.0 mg/L)显示出明显的抑制作用。【结论】经驯化,SRB厌氧活性污泥显示出较强的硫酸盐还原能力,具有应用于工业烟气生物脱硫的潜力。去除重金属离子Pb2+、Ni2+和Cu2+可有效解除对硫酸盐生物还原作用的抑制。     

厌氧氨氧化菌的物种多样性与生态分布

厌氧氨氧化是微生物和环境领域的重大发现,厌氧氨氧化可同时去除氨氮和亚硝氮,在环境工程上具有重大开发价值.由于厌氧氨氧化菌生长极慢,倍增时间长达11 d以上,严重制约了该反应的开发进程,因此,对厌氧氨氧化菌的研究具有重要意义.厌氧氨氧化菌种类丰富,除了人们最早认识的浮霉状菌外,还有硝化细菌和反硝化细菌,这些菌群生态分布广泛,为开辟新的厌氧氨氧化菌种资源创造了条件.硝化细菌和反硝化细菌兼有厌氧氨氧化能力,其代谢多样性为加速厌氧氨氧化反应器的启动提供了依据.厌氧消化污泥可呈现硫酸盐型厌氧氨氧化活性,可为新型生物脱氮工艺的研发奠定基础.探明厌氧氨氧化菌种资源及其生态分布,将有利于厌氧氨氧化的开发应用.     

保藏温度对厌氧氨氧化颗粒污泥特性的影响

为考察保藏温度对厌氧氨氧化污泥颗粒特性的影响,同时优化保藏厌氧氨氧化颗粒污泥温度参数,本试验首先通过HRT调控进水基质负荷培养厌氧氨氧化颗粒污泥,并采用KHCO3和Na HCO3交替提供无机碳源。然后分别在–40℃、4℃、(27±4)℃室温和35℃条件下避光保藏。结果表明,Na HCO3可代替KHCO3作为厌氧氨氧化菌生长的无机碳源。相比于其他保藏温度,4℃保藏能够较好地维持生物量和生物活性,同时能较好地维持颗粒污泥的沉降性能、颗粒污泥和细胞结构完整性。在保藏过程中,一阶衰减指数模型可拟合厌氧氨氧化颗粒污泥生物量及活性的衰减过程,衰减指数与胞溶程度正相关,而且生物量的衰减比活性的衰减更快。同时,颗粒污泥胞外聚合物中蛋白质与多糖的比值(PN/PS)和血红素不能有效指示保藏过程中颗粒污泥沉降性能和活性的变化,而生物活性与胞溶程度呈负相关。     

厌氧氨氧化菌富集培养物对羟胺的转化研究

【目的】羟胺是厌氧氨氧化的重要中间产物,本研究旨在探明厌氧氨氧化菌对羟胺的转化特性。【方法】采用厌氧氨氧化菌富集培养物,以羟胺和亚硝酸盐为基质进行分批培养试验,检测反应液中基质和产物的消涨情况。【结果】不接种厌氧氨氧化富集培养物时,羟胺和亚硝酸盐具有化学稳定性,彼此不发生化学反应;接种厌氧氨氧化富集培养物后,羟胺和亚硝酸盐发生化学反应;反应过程中有中间产物氨的产生和转化,最大氨氮积累浓度为0.338mmol/L;液相中总氮浓度从起始的4.694mmol/L降至结束时的0.812mmol/L,转化率为82.7%。羟胺和亚硝氮浓度均为2.5mmol/L时,羟胺最大比污泥转化速率为0.535mmol/(gVSS.h),是厌氧氨氧化反应体系中氨氮最大比污泥转化速率的1.81倍。将羟胺浓度提高至5.0mmol/L时,羟胺和亚硝氮转化速率分别提高26.7%和120.7%,最大氨氮积累浓度为0.795mmol/L;将亚硝氮浓度提高至5.0mmol/L时,羟胺和亚硝氮转化速率分别提高6.9%和9.0%,最大氨氮积累浓度为1.810mmol/L。【结论】厌氧氨氧化富集培养物能够转化羟胺,其对羟胺的转化速率高于对氨的转化速率。羟胺相对过量可显著加快羟胺和亚硝酸盐的转化速率,亚硝酸盐相对过量对羟胺和亚硝氮转化速率影响不大,提高羟胺或亚硝氮浓度均会增大中间产物氨氮的积累。实验现象可用van de Graaf模型解释,对于进一步开发厌氧氨氧化工艺具有重要的理论意义。     

厌氧氨氧化反应器的启动研究

目的：对UASB-生物膜反应器进行厌氧氨氧化反应的启动研究。方法：以自配含氨氮和亚硝氮的废水为进水,以氧化沟工艺城市污水处理厂回流污泥为接种污泥。结果：反应器内部菌群进行了竞争,在运行至第66d时氨氮、亚硝酸盐氮的去除率分别达到了60.4%、58.7%,同时有硝酸盐氮生成,表明厌氧氨氧化反应已经成为反应器内的主导反应。结论：厌氧氨氧化反应器实现了快速启动。     

改性生物填料载体强化厌氧氨氧化反应器脱氮研究

以上流式厌氧污泥床(UASB)为研究对象,主要探究2种改性生物填料载体对厌氧氨氧化反应器脱氮性能的影响,并以电子扫描显微镜(SEM)、脱氢酶活性检测及菌群结构分析等微观方面解析影响脱氮性能差异的原因.结果 表明:活性炭聚氨酯及改性聚乙烯塑料填料2种生物填料载体的投加均能在一定程度上提高厌氧氨氧化反应器的脱氮性能,当反应...     

厌氧氨氧化颗粒污泥聚集机制研究进展

厌氧氨氧化(anaerobic ammonium oxidation,anammox)工艺被认为是当前污水生物脱氮领域最经济的处理工艺,有利于实现污水处理厂的能源自给。厌氧氨氧化菌是该工艺的核心功能微生物。以厌氧氨氧化菌为主导微生物形成的厌氧氨氧化颗粒污泥具有沉速大、污泥持留能力强及对不利环境抵抗能力强等突出优势,是实现厌氧氨氧化工艺最有前景的污泥形态。本论文围绕厌氧氨氧化颗粒,介绍了厌氧氨氧化菌的特性、种类及代谢途径,综述了厌氧氨氧化颗粒污泥的形成假说及与厌氧氨氧化颗粒污泥聚集密切相关的胞外聚合物(extracellular polymeric substance,EPS)和群体感应研究现状,并对今后厌氧氨氧化颗粒的研究进行了展望,以期为后续厌氧氨氧化颗粒的研究及厌氧氨氧化颗粒工艺的优化提供参考。     

Rapid startup and high rate nitrogen removal from anaerobic sludge digester liquor using a SNAP process

In this study, a single-stage autotrophic nitrogen removal reactor, packed with a novel acrylic fiber biomass carrier material (Biofix), was applied for nitrogen removal from sludge digester liquor. For rapid start-up, conventional activated sludge was added to the reactor soon after the attachment of anammox biomass on the Biofix carriers, which allowed conventional activated sludge to form a protective layer of biofilm around the anammox biomass. The Nitrogen removal efficiency reached 75% within 1 week at a nitrogen loading rate of 0.46 kg-N/m³/day for synthetic wastewater treatment. By the end of the synthetic wastewater treatment period, the maximum nitrogen removal rate had increased to 0.92 kg-N/m³/day at a nitrogen loading rate of 1.0 kg-N/m³/day. High nitrogen removal rate was also achieved during the actual raw digester liquor treatment with the highest nitrogen removal rate being 0.83 kg-N/m³/day at a nitrogen loading rate of 0.93 kg-N/m³/day. The thick biofilm on Biofix carriers allowed anammox bacteria to survive under high DO concentration of 5–6 mg/l resulting in stable and high nitrogen removal performance. FISH and CLSM analysis demonstrated that anammox bacteria coexisted and surrounded by ammonium oxidizing bacteria.     

PVA-alginate immobilized cells for anaerobic ammonium oxidation (anammox) process

The feasibility of an anaerobic ammonium oxidation (anammox) process combined with a cell-immobilization technique for autotrophic nitrogen removal was investigated. Anammox biomass was cultivated from local activated sludge and achieved significant anammox activity in 6 months. The development of a mature anammox biomass was confirmed by fluorescence in situ hybridization (FISH) analysis and off-line activity measurements. The abundance fraction of the anammox bacteria determined by FISH analysis was estimated by software. The anaerobic ammonia oxidizers occupied almost half of the total cells. Additionally, the anammox biomass was granulated as spherical gel beads of 3-4 mm in diameter by using a cell-immobilization technique. The nitrogen removal activity was proved to be successfully retained in the beads, with about 80% of nitrogenous compounds (NH(4) (+), NO(2) (- )and total nitrogen) removed after 48 h. These results offer a promising technique for the preservation of anammox microorganisms, the protection of them against the unfavorable surroundings, and the prevention of biomass washout towards the implementation of sustainable nitrogen elimination biotechnology. This is the first report on the immobilization of anammox biomass as gel beads.     

铁矿物强化厌氧氨氧化效能及其微生物机制研究进展

自然界中的氮循环与铁循环相互交联,参与氮循环的厌氧氨氧化（anaerobic ammonium oxidation,anammox）菌的生长代谢及活性发挥也与铁元素紧密关联。自然界广泛存在的铁矿物因具有运行成本低廉、稳定性好、二次污染小等优势,在污水处理领域得到广泛应用。在厌氧氨氧化脱氮系统中引入适量铁矿物,不仅有助于促进anammox菌和铁还原菌的富集,提高功能基因丰度和相关酶活性,还可能通过影响污泥浓度、血红素c含量、胞外聚合物含量和颗粒化程度,改善污泥性能和提高厌氧氨氧化系统的稳定性。同时,铁矿物具有促进体系多种氮素转化途径（如anammox、铁自养反硝化、铁氨氧化、异化硝酸盐还原成铵和反硝化）相耦合的潜能,可以提高anammox污水处理系统的总氮去除率。本文基于铁矿物在促进污水生物脱氮方面的良好性能及其在anammox系统中的变化,从脱氮效能、污泥特性、微生物特征及酶活性等方面,系统综述了铁矿物对厌氧氨氧化系统的强化作用机制,并从anammox菌对铁矿物的利用及铁元素的摄取角度展望了后续的研究方向,以期为铁矿物强化厌氧氨氧化系统的实际应用提供理论和技术指导。     

Adaptation of a freshwater anammox population to high salinity wastewater

For the successful application of anaerobic ammonium oxidation (anammox) in wastewater practice it is important to know how to seed new anammox reactors with biomass from existing reactors. In this study, a new high salinity anammox reactor was inoculated with biomass from a freshwater system. The changes in activity and population shifts were monitored. It was shown that freshwater anammox bacteria could adapt to salt concentrations as high as 30 gl(-1) provided the salt concentration was gradually increased. Higher salt concentrations reversibly inhibited anammox bacteria. The nitrogen removal efficiency and maximum anammox activity of the salt adapted sludge was very similar to the reference freshwater sludge. Fluorescence in situ hybridization analysis revealed that the freshwater anammox species Candidatus "Kuenenia stuttgartiensis" was the dominant in both salt adapted sludge and freshwater sludge. These results show that gradual adaptation may be the key to successful seeding of anammox bioreactors.     

Identification of bacteria coexisting with anammox bacteria in an upflow column type reactor

Anammox process has attracted considerable attention in the recent years as an alternative to conventional nitrogen removal technologies. In this study, a column type reactor using a novel net type acrylic fiber (Biofix) support material was used for anammox treatment. The Biofix reactor was operated at a temperature of 25°C (peak summer temperature, 31.5°C). During more than 340 days of operation for synthetic wastewater treatment, the nitrogen loading rates of the reactor were increased to 3.6 kg-N/m³/d with TN removal efficiencies reaching 81.3%. When the reactor was used for raw anaerobic sludge digester liquor treatment, an average TN removal efficiency of 72% was obtained with highest removal efficiency of 81.6% at a nitrogen loading rate of 2.2 kg-N/m³/d. Results of extracellular polymeric substances (EPS) quantification revealed that protein was the most abundant component in the granular sludge and was found to be almost twice than that in the sludge attached to the biomass carriers. The anammox granules in the Biofix reactor illustrated a dense morphology substantiated by scanning electron microscopy and EPS results. The results of DNA analyses indicated that the anammox strain KSU-1 might prefer relatively low nutrient levels, while the anammox strain KU2 strain might be better suited at high nutrient concentration. Other types of bacteria were also identified with the potential of consuming dissolved oxygen in the influent and facilitating survival of anammox bacteria under aerobic conditions.     

Presence and activity of anammox and denitrification process in low ammonium-fed bioreactors

A combination of anammox and denitrification process was studied for 300 days in low ammonium-fed bioreactors under the support of organic carbon. Nutrient profiles, (15)N-labelling techniques and qualitative fluorescence in situ hybridization (FISH) probes were used to confirm the nitrogen removal pathways and intercompetition among different bacteria populations. About 80% of nitrogen removal was achieved throughout the study period. The results confirmed that anammox bacteria were absent in the bioreactor inoculated with anaerobic granules only but they were present and active in the central anoxic parts of biopellets in the bioreactor inoculated with mixed microbial consortium from activated sludge and anaerobic granules. It also showed that the anammox bacteria were successfully enriched in the low ammonium-fed bioreactors. Results of this study clearly demonstrated that anammox and denitrification processes could coexist in same environment and anammox bacteria were less competitive than denitrifying bacteria.     

Importance of the operating pH in maintaining the stability of anoxic ammonium oxidation (anammox) activity in moving bed biofilm reactors

Two bench-scale parallel moving bed biofilm reactors (MBBR) were operated to assess pH-associated anammox activity changes during long term treatment of anaerobically digested sludge centrate pre-treated in a suspended growth partial nitrification reactor. The pH was maintained at 6.5 in reactor R1, while it was allowed to vary naturally between 7.5 and 8.1 in reactor R2. At high nitrogen loads reactor R2 had a 61% lower volumetric specific nitrogen removal rate than reactor R1. The low pH and the associated low free ammonia (FA) concentrations were found to be critical to stable anammox activity in the MBBR. Nitrite enhanced the nitrogen removal rate in the conditions of low pH, all the way up to the investigated level of 50 mg NO₂-N/L. At low FA levels nitrite concentrations up to 250 mg NO₂-N/L did not cause inactivation of anammox consortia over a 2-days exposure time.     

Nitrogen removal performance using anaerobic ammonium oxidation at low temperatures

An anaerobic ammonium oxidation (anammox) process for ammonia-rich wastewater treatment has not been reported at temperatures below 15 degrees C. This study used a gel carrier with entrapped anammox bacteria to obtain a stable nitrogen removal performance at low temperatures. In a continuous feeding test, a high nitrogen conversion rate (6.2 kg N m(-3) day(-1)) was confirmed at 32 degrees C. Nitrogen removal activity decreased gradually with decreasing operation temperature; however, it still occurred at 6 degrees C. Nitrogen conversion rates at 22 and 6.3 degrees C were 2.8 and 0.36 kg N m(-3) day(-1), respectively. Moreover, the stability of anammox activity below 20 degrees C was confirmed for more than 130 days. In batch experiments, anammox gel carriers were characterized with respect to temperature. The optimum temperature for anammox bacteria was found to be 37 degrees C. Furthermore, it was clear that the temperature dependence changed at about 28 degrees C. The apparent activation energy in the temperature range from 22 to 28 degrees C was calculated as 93 kJ mol(-1), and that in the range from 28 to 37 degrees C was 33 kJ mol(-1). This value agrees with the result of a continuous feeding test (94 kJ mol(-1), between 6 and 22 degrees C). The nitrogen removal performance demonstrated at the low temperatures used in this study will open the door for the application of anammox processes to many types of industrial wastewater treatment.     

厌氧氨氧化反应器启动过程的影响因素及微生物群落变化研究进展

自厌氧氨氧化反应发现以来,由于其具有低能耗、无需外加碳源等优点,已成为人们在污水生物脱氮研究与应用中的最新关注点。然而,由于极低的生长速率、极长的倍增时间以及严格的代谢条件等特点,限制了厌氧氨氧化菌的应用。综述了厌氧氨氧化菌富集培养过程中的影响因素,介绍了不同污泥来源的厌氧氨氧化优势菌属、分子鉴定方法,提供了部分用于厌氧氨氧化菌鉴定使用的引物序列和厌氧氨氧化菌最新发现的属与种。最后,对未来的研究方向提出一些建议思考,以期为厌氧氨氧化工艺在污水处理中的应用提供参考。