游离和聚乙烯醇包埋门多萨假单胞菌好氧反硝化脱氮的研究

以从采自温州西片污水处理厂的活性污泥样品中分离的好氧反硝化门多萨假单胞菌(Pseudmonas mendocina)WZUF20为受试对象,以聚乙烯醇(PVA)-海藻酸钙-活性炭包埋固定化,研究游离和固定化细胞在人工硝态氮污水中好氧反硝化去除硝态氮的条件,以及它们对人工氨氮、硝态氮和亚硝态氮污水的氨氮、硝态氮和亚硝态氮的去除能力。结果表明:(1)游离细胞和固定化细胞去除硝态氮的适宜条件是相似的,适宜碳源为丁二酸钠、乙酸钠和柠檬酸钠,适宜碳源和KNO3质量比为10∶1,适宜温度、转速和pH分别为20~35℃、100~200r/min和6.0~9.5;(2)在适宜条件下,游离细胞和固定化细胞对人工氨氮污水氨氮的去除速率分别为8.79、1.67mg/(L·h),对人工硝态氮污水硝态氮的去除速率分别为8.17、4.54mg/(L·h),对人工亚硝态氮污水亚硝态氮的去除速率分别为16.42、7.67mg/(L·h);(3)在人工硝态氮污水中连续5批次的去硝态氮试验表明,PVA-海藻酸钙-活性炭固定化细胞是稳定的。说明门多萨假单胞菌(Pseudmonas mendocina)WZUF20以及PVA-海藻酸钙-活性炭包埋制备的固定化细胞具有应用于实际废水脱氮的潜力。     

一株贫营养异养硝化-好氧反硝化细菌的分离鉴定及脱氮特性

从水源水库沉积物中筛选出一株具有较高脱氮效率的异养硝化-好氧反硝化菌SF9。扫描电镜观察其形态特征为(0.2~0.4)μm×(0.4~0.8)μm椭球状,16S r DNA序列分析表明菌株与Delftia lacustris DSM 21246(T)相似性为100%,并分析其系统发育分类地位,对该菌进行贫营养反硝化特性研究。结果表明,该菌在分别以硝氮、亚硝氮及氨氮为唯一氮源时去除率分别达81%、64%和40%。同步硝化反硝化研究表明,该菌在氨氮存在的情况下会优先利用氨氮,在以氨氮与硝氮为氮源时和以氨氮与亚硝氮为氮源时氨氮的去除率分别达81%和74%。将菌株接种到微污染源水(总氮2.34mg/L、C/N为1.2)水体中,总氮72 h去除率达到35%,TOC消耗30%。结果表明,菌株SF9与其他已报道的好氧反硝化菌相比,能耐受更低的C/N比,可作为微污染水源水微生物修复的高效菌剂。     

生物膜反应器中低氨氮浓度废水的亚硝化

在连续流生物膜反应器中通过控制DO、pH和HRT,对低氨氮浓度废水进行了亚硝化的实验研究。结果表明,在进水氨氮浓度为35～45 mg/L,温度为34℃的情况下,当DO=1.4～1.5 mg/L,pH=8.3,HRT=6 h时,氨氮的去除率与亚硝态氮的积累率均可达到80%左右,实现了较好的氨氮降解及稳定的亚硝态氮的积累。     

高有机物浓度下氨氮的好氧硝化

污水中往往同时含有较高浓度的有机物和氨氮,研究较高有机物浓度下氨氮的好氧生物硝化,以为工程应用提供实践和理论依据。考察了COD浓度为1 200 mg·L~(-1),好氧活性污泥处理氨氮废水过程中COD、NH_4~+-N的去除情况,硝态氮、亚硝态氮的生成情况。在整个驯化阶段,氨氮的最高去除率达到86.42%,COD最高去除率达到85.40%,同时亚硝态氮的最大生成量为15.97 mg·L~(-1),硝态氮的最高生成量为5.14 mg·L~(-1),且8 h的短期实验显示,COD、NH_4~+-N的去除可以同步进行。     

异养硝化-好氧反硝化菌粪产碱杆菌的脱氮特性

为了对粪产碱杆菌(Alcaligenes faecalis No.4)的脱氮特性进行研究,提出了不同环境因子对菌株脱氮性能影响的对比实验。结果表明,该菌能利用柠檬酸钠和乙酸钠作为惟一碳源,以柠檬酸钠为碳源时脱氮活性最高,硝酸铵、氯化铵、碳酸铵和硫酸铵4种铵盐均能作为惟一氮源,而硝态氮和亚硝态氮几乎不能被该菌代谢转化;当温度在30~37℃、摇床转速超过120 r/min、p H为6~8之间时,该菌对氨氮的去除效果最好;该菌对高中低浓度的氨氮都具有很好的去除效果,对高浓度的氨氮有很好的耐受性;该菌对0%、3%盐度的适应期较短,对6%的盐度经过较长时间的适应期后,也能够快速地处理氨氮,具有良好的耐盐性。     

低浓度乙酸盐诱导下厌氧氨氧化与异养反硝化高效耦合脱氮

通过连续流实验研究了低浓度乙酸盐诱导下厌氧氨氧化颗粒污泥与异养反硝化菌的耦合脱氮性能,同时采用批试实验考察耦合系统中的氮素转化及去除途径。结果表明:采用低浓度乙酸盐对厌氧氨氧化颗粒污泥进行驯化,可以实现厌氧氨氧化与异养反硝化的高效耦合脱氮。系统在稳定时期,进水NH_4~+-N为30~40 mg·L~(-1)、NO_2~--N为45~55 mg·L~(-1)、CH_3COONa为60~80 mg·L~(-1),NH_4~+-N、NO_2~--N和TN的去除率分别为93.84%、94.62%和86.46%。耦合系统中的颗粒污泥同时存在厌氧氨氧化特性、硝化特性和反硝化特性。颗粒污泥表现出良好的厌氧氨氧化特性,总氮去除速率为12.46 mg·(g MLSS·h)~(-1)。系统中存在的硝化细菌可以消耗进水中的溶解氧从而缓解溶解氧对ANAMMOX菌的抑制,其中AOB活性高于NOB活性。系统中颗粒污泥对硝氮的反硝化作用强于对亚硝氮的反硝化作用,亚硝氮反硝化和硝氮反硝化的降解速率分别为1.89和3.59 mg·(g MLSS·h)~(-1)。当亚硝氮和硝氮同时存在时,反硝化菌优先将硝氮还原成亚硝氮。     

不同DO下亚硝态氮氧化菌硝化系统N 2O减量化研究

采用序批式活性污泥反应器(SBR),在富集亚硝态氮氧化菌(NOB)的基础上,考察了DO对连续进水模式下硝化过程中N_2O减量化的影响。结果表明,在污泥氨氧化菌(AOB)和NOB的比耗氧速率(SOUR)分别为(2.36±0.31)、(7.62±0.43)mg/(L·h)条件下,不外加碳源进行小试实验,氨氮均小于1.0mg/L,亚硝态氮均小于0.5mg/L。DO由0.2mg/L增至3.0mg/L过程中,随着DO增加,积累的硝态氮浓度逐渐上升,而累计产生的N_2O浓度先上升后下降。DO为0.2mg/L时,积累的硝态氮和累计产生的N_2O浓度最低,可以实现N_2O的最大减量化。在进水连续投加氨氮的方式下,氨氮氧化速率不是引起N_2O生成的关键步骤,碳源缺乏的情况下NOB硝化系统中低DO可以有效控制N_2O的释放。     

一体化膜生物反应器中短程硝化反硝化对氨氮的脱除

采用一体化膜生物反应器处理模拟氨氮废水,通过改变温度、pH、DO实现了反应器中短程硝化的稳定运行。结果表明,在进水氨氮、COD分别为67~86、240~342 mg/L的情况下,当温度为30℃、进水pH为8.1时,通过逐渐降低DO至1.2mg/L,亚硝态氮得到富集,氨氮和COD的去除率均能达到80%以上,且系统的耐冲击负荷能力较好;整个运行期间保持了较高的混合液悬浮固体浓度(MLSS),处于3 200~8 210mg/L,污泥沉降比和污泥体积指数(SVI)相对稳定,SVI处于75~138mL/g。     

水质净化高效复合微生态制剂的研制

在室内模拟条件下,采用正交实验的方法对光合细菌、枯草芽孢杆菌和反硝化细菌的复配比例进行了研究,筛选一种用于水产养殖水质净化的高效复合微生态制剂。结果表明,当光合细菌(菌细胞浓度约为2×109CFU/mL)、枯草芽孢杆菌(菌细胞浓度约为8×108CFU/mL)和反硝化细菌(菌细胞浓度约为8×108CFU/mL)按菌液体积比为1∶2∶1进行复配利于水中溶解氧的提高和COD、氨氮、亚硝态氮、硝态氮的降解。验证实验表明,筛选组合各指标均优于商品微生态制剂和空白对照,其中溶解氧含量显著高于商品微生态制剂EM和复合芽孢菌处理,在实验第5天对COD的降解率为95%,显著优于EM和复合芽孢菌处理的66.3%和47.9%,实验第7天对氨氮、亚硝态氮和硝态氮的降解率分别达到70%、89%和56%。     

微生物复合固定化颗粒特征分析及去除河水氨氮效果的研究

以炉渣和改性玉米芯2种基质作为吸附材料,海藻酸钠(SA)和聚乙烯醇(PVA)2种包埋剂为基本骨架,微生物为降解主体,制备得到微生物复合固定化颗粒,并分析了颗粒的物理特征、活性恢复方式、对河水中氨氮和其他氮素的去除效果。结果表明:添加不同吸附基质对固定化颗粒的影响不同;实际河水驯化是有效的活性恢复方式;微生物复合固定化颗粒反应24h后,河水中氨氮降至1mg/L以下,河水中氨氮、亚硝态氮、硝态氮和TN去除率均在90%左右,对河流中氮污染的治理有一定的意义。     

完全自营养脱氮过程中的影响因素

基于正交实验考察了溶解氧（DO）、初始NH4＋-N浓度、pH对SBR自营养脱氮性能的影响。结果表明，DO和NH4＋-N浓度对好氧氨氧化速率影响大，pH对好氧氨氧化速率的影响小；DO、NH4＋-N浓度对亚硝酸氧化速率的影响较大，pH对亚硝酸氧化速率的影响较小；DO、NH4＋-N浓度和pH对厌氧氨氧化菌（ANAOB）的活性影响较小。好氧氨氧化菌（AOB）直接影响到CANON系统的总氮去除能力，是CANON系统的控制反应，DO是关键控制因子。实验确定的CANON系统优化运行条件为，DO（0．3±0．05）mg／L、初始NH4＋-N浓度150mg／L和pH7．4。     

Ammonium-nitrogen transformation and nitrogen retention in broiler manure supplemented with a soil amendment containing nitrifying bacteria

The effect of a soil amendment on ammonium nitrogen transformation and nitrogen retention in broiler manure was evaluated. Prior to incubation, broiler manure was mixed with autoclaved soil or non-autoclaved soil in different ratios to make 1 kg mixtures; broiler manure:non-autoclaved soil=9:1, 5:5, and 1:9 or broiler manure:autoclaved soil=9:1, 5:5, and 1:9. The non-autoclaved soil treatment reduced either numerically or significantly NH(4)(+)-N concentration compared to the autoclaved soil treatment during the 8-wk incubation. Total-N concentration of the non-autoclaved soil treatments was lower than the autoclaved soil treatments from 4 to 8 wk. The lowest manure to non-autoclaved soil treatment (M:S=1:9) had considerably more nitrite and nitrate; however, the higher ratio manure to non-autoclaved soil treatments (M:S=9:1 and 5:5) had slightly higher total nitrite and nitrate levels compared to the same ratio of autoclaved soil treatments. The moisture level of the 9:1, 5:5, and 1:9 M:S treatments were approximately 70, 45, and 30%, respectively. The results indicated that nitrifying bacteria in the non-autoclaved soil reduced the ammonium nitrogen concentrations of poultry manure by converting NH(3) or NH(4)(+) to NO(2)(-) or NO(3)(-). However, the higher moisture levels in treatments with greater manure to soil ratios (M:S=9:1 and 5:5) created anaerobic conditions that allowed for denitrification and greater N losses.     

复合介质渗透反应格栅去除地下水中的氨氮

针对受低浓度氨氮污染的地下水,实验筛选组合了不同的反应介质,利用串联的多介质填充柱模拟渗透反应格栅,通过物理吸附及生物硝化-反硝化作用来实现氮的去除。结果表明,在进水氨氮浓度为10 mg/L、流速为0.5 m/d的条件下,模拟柱对氨氮的去除率达到98%以上,且不会出现亚硝酸盐及硝酸盐浓度的升高。水体经过释氧柱后溶解氧由2mg/L升高至10 mg/L以上,表明释氧材料可提供硝化细菌所需的好氧环境。好氧柱中填充易于生物挂膜的生物陶粒及对氨氮有较强吸附能力的沸石,二者联用通过生物硝化-物理吸附协同作用实现对氨氮的去除,其中生物作用实现的氨氮去除量占总去除量的50%左右。后续厌氧反应柱填充海绵铁除氧并利用松树皮颗粒作为碳源,创造反硝化菌生长条件,硝酸盐氮浓度可由10 mg/L降低至5 mg/L以下,实现对好氧反应阶段所产生的硝酸盐的去除,避免了地下水的二次污染。     

Influence of the DMPP (3,4-dimethyl pyrazole phosphate) on nitrogen transformation and leaching in multi-layer soil columns

The application of nitrogen fertilizers leads to various ecological problems such as nitrate leaching. The use of nitrification inhibitors as nitrate leaching retardants is a proposal that has been suggested for inclusion in regulations in many countries. In this study, using a multi-layer soil column device, the influence of new nitrification inhibitor DMPP (3,4-dimethyl pyrazole phosphate) was studied for understanding the nitrogen vertical transformation and lowering the nitrate leaching at different soil profile depths. The results indicated that, within 60 d of experiment, the regular urea added 1.0% DMPP can effectively inhibit the ammonium oxidation in the soil, and improve the ammonium concentration in soil solution over the 20cm depths of soil profile, while decline the concentrations of nitrate and nitrite. No obvious difference was found on ammonium concentrations in soil solution collected from deep profile under 20cm depths between regular urea and the urea added 1.0% DMPP. There was also no significant difference for the nitrate, ammonium and nitrite concentrations in the soil solution under 40cm depths of soil profile with the increasing nitrogen application level, among the treatments of urea added 1.0% DMPP within 60 d. It is proposed that DMPP could be used as an effective nitrification inhibitor in some region to control ammonium oxidation and decline the ion-nitrogen leaching, minimizing the shallow groundwater pollution risk and being beneficial for the ecological environment.     

曝气生物滤池中碳和氮代谢特性

用充填陶瓷滤料的曝气生物滤池研究碳和氮代谢特性.曝气生物滤池进水氨氮为52 mg/L左右、COD为100 mg/L左右和回流比为200%时,经过20多d的运行,出水氨氮小于0.05 mg/L、COD小于25 mg/L、亚硝态氮为4.7 mg/L和硝态氮为7.1 mg/L,COD去除率达75%,氨氮去除率达99.9%,总氮去除率达78%;过大和过小的回流比对曝气生物滤池的运行性能都是不利的.研究成果可以应用于一般城市污水以及含低COD、高氨氮工业废水的处理.     

污水低氧脱氮机制及其应用研究进展

阐述了污水低氧脱氮的基本原理,即抑制或去除亚硝酸盐氧化菌(NOB),同时保留氨氧化菌(AOB),并保持其活性;探讨了污水低氧脱氮实现途径;详细介绍了几种典型的污水低氧脱氮工艺(短程硝化(SHARON)工艺、厌氧氨氧化(ANAMMOX)工艺、好氧反氨化(DEMON)工艺、低氧自养硝化反硝化(OLAND)工艺、甲烷营养型硝化反硝化工艺和亚硝酸盐型完全自养脱氮(CANNON)工艺)的应用研究进展;最后对污水低氧脱氮处理工艺的工程运用进行了展望.     

含氮杂环化合物吡啶的缺氧降解和毒性削减研究

运用摇瓶试验,研究了含氮杂环化合物吡啶的缺氧降解情况、毒性削减规律以及它们之间的关系。结果表明,在吡啶缺氧降解过程中,有利于废水毒性削减的C／N比为8左右;废水中主要致毒物质为吡啶和亚硝酸盐,且亚硝酸盐的毒性大于吡啶的毒性,两者的联合为毒性相加作用;在整个吡啶降解过程中,废水毒性与吡啶降解和亚硝酸盐的产生有着直接联系,毒性削减时间长短与吡啶初始浓度有关。     

Comparative abiotic or biotic degradation of carboxin by two Entisols with different surface properties or Pseudomonas aeruginosa strain: A toxicity study using the crustacean Thamnocephalus platyurus

The microcrustacean Thamnocephalus platyurus was used to detect the toxicity reduction of carboxin in abiotic degradation compared to biotic degradation. The abiotic degradation was obtained using two sterilized Entisols with different surface properties while the biotic degradation by Pseudomonas aeruginosa was obtained using the fungicide as the only C source. The results showed that the highest toxicity reduction rates for the abiotic degradation were achieved in 20 days with 49.2% for the coarser soil, 60.7% for the soil with a finer texture, whereas for the biotic degradation, 60.6%. Analysis (¹H NMR) showed that the soils transformed carboxin to produce sulfoxide and enol in different concentrations depending on the soil properties, while P. aeruginosa metabolized the fungicide to produce inorganic compounds such as ammonium and nitrite, minor degradation pathways were oxidized to sulfoxide and hydrolytic ring-opening to 2-[(2-hydroxyethyl)thio]acetoacetanilide enol. These results indicated that the degradation of carboxin occurred via abiotic catalytic processes as well as via biotic transformation leading to less toxic derivatives and such phenomena are caused by exchange/surface features of soils, rather than by the mere content of clay or organic matter fractions.     

Sonochemically induced decomposition of energetic materials in aqueous media

This study demonstrates that ultrasound rapidly degrades the energetic compounds RDX (cyclo-1,3,5-trinitramine-2,4,6-trimethylene) and ADN (ammonium dinitramide) in aqueous microheterogeneous media. The conditions for effective degradation of these nitramines, as monitored by UV absorption spectroscopy, were determined by varying sonication time, the heterogeneous phase and its suspension density, and the concentration of NaOH. In the presence of 5 mg/ml of aluminum powder and at pH approximately 12 (10 mM NaOH), 74% of the RDX and 86% of the ammonium dinitramide (ADN) in near-saturated solutions decompose within the first 20 min of sonication (20 kHz; 50 W; < or =5 degrees C). Sonication without Al powder and base yields minimal degradation of either RDX and ADN (approximately 5-10%) or the nitrite/nitrate ions that are expected byproducts during RDX and ADN degradation. Sonication at high pH in the presence of dispersed aluminosilicate zeolite, alumina, or titanium dioxide also yields minimal degradation. Preliminary electrochemical studies and product analyses indicate that in situ ultrasonic generation of metallic aluminum and/or aluminum hydride drives reductive denitration of the nitramines. Sonochemical treatment in the presence of a reductant offers an effective and rapid waste remediation option for energetic waste compounds.     

炼钢废气除尘污水处理的研究

系统地研究了影响石灰中和法处理转炉除尘废水含铜沉降速度的因素.结果表明,在搅拌时间10 min和中等搅拌强度的条件下,pH值控制在8.2～9.0范围内能使废水中铜含量在1 h的沉降时间内降至国家排放标准2 mg/L以下.实验还研究了在石灰中和过程中加入适量絮凝剂的影响因素.结果表明,在搅拌时间3 min和相同pH值范围的条件下,加入絮凝剂能使废水中铜含量在30 min的沉降时间内降至国家排放标准2 mg/L以下.