污泥酵制园林营养土好氧-厌氧交替法可行性分析

为研究好氧-厌氧交替法用于脱水污泥酵制园林营养土达到无害化、营养化、腐殖化(三化)目标的可行性,开展了好氧、厌氧、交替实验效果分析。结果表明:大肠菌群死亡率,酵温50℃时为80%,60℃时为95%;好氧、厌氧、交替,冬季最高酵温分别为52.5、29.5、52.2℃(夏季分别为62.5、41.8、64℃),大肠菌群达标所需时间好氧、交替均为8 d(冬)和3d(夏),厌氧28 d以上;平均碱解氮,厌氧0.859 g/kg>交替0.856 g/kg>好氧0.798 g/kg;20 d后平均有效磷,交替1.852g/kg>好氧1.692 g/kg>厌氧1.636 g/kg;20 d后平均有效钾:交替14.215 g/kg>好氧13.187 g/kg>厌氧11.945 g/kg;20d后平均腐殖质,交替10.510 g/kg>厌氧9.398 g/kg>好氧8.768 g/kg。分析可知,好氧法、交替法可使发酵污泥达到无害化,营养化、腐殖化指标交替法高于好氧法,交替法用于污泥酵制园林三化营养土可行,其控制参数需实验确定。     

污水污泥发酵制园林营养土的好氧-厌氧交替方式控制研究

为使污水污泥发酵后制成的园林营养土符合无害化、营养化、腐殖化的要求,通过好氧-厌氧交替试验,考察了不同通风方式、好氧-厌氧交替方式下的大肠菌群数量、发酵温度、有效氮、有效磷、腐殖质等的变化,以确定交替试验的最佳条件.结果表明,污水污泥发酵制园林营养土较佳的通风方式为:通气量1.4～2.8 m3/(h·t)、通气5 mi...     

不同季节的沼液中细菌分离培养与含量分析

采用TPY琼脂分别对不同季节的好氧、厌氧沼液中的细菌进行需氧和厌氧培养，对培养出的细菌进行计数和形态观察。结果表明：（1）夏季厌氧沼液中厌氧菌及兼性细菌数量均极显著高于春季；夏季好氧沼液中好氧菌数量显著高于春季。（2）冬季厌氧沼液的厌氧培养和需氧培养的细菌数量，均极显著低于秋季；冬季好氧沼液中的需氧培养出的细菌数，显著低于秋季。（3）夏、秋季的厌氧招液，厌氧培养出的细菌数极显著高于好氧沼液厌氧培养出的细菌；冬季厌氧沼液厌氧培养出的细菌数，显著高于好氧沼液厌氧培养出的细菌。（4）沼液中的细菌种类繁多，表型特征复杂。（5）沼液中的杆菌最多，其夏季各种形状菌都较其它季节多。（6）四季沼液中，革兰氏阴性菌均占多数，革兰氏阳性菌均占少数。     

抗生素菌渣堆肥进程中微生物群落的变化

将青霉素菌渣、林可霉素菌渣与牛粪等原料分别进行好氧堆肥实验，以考察堆肥过程中不同菌渣对微生物群落的影响。在堆制的41d里，根据温度变化分阶段采集堆肥样品，采用稀释倒平板法测定细菌、放线菌和真菌的数量。结果表明，菌渣不同，其堆肥中的微生物群落变化趋势不同。青霉素菌渣堆肥中细菌数量变化趋势为高一低，真菌数量变化趋势为高一低．高，放线菌数量为逐渐增加；林可霉素菌渣堆肥过程中细菌数量变化趋势为低一高一低，放线菌和真菌数量变化趋势为高．低．高。依据真菌菌落形态观察，菌渣堆肥中的真菌种类比对照牛粪堆肥单一，表明两种菌渣对堆肥中的微生物多样性均产生了不利影响。林可霉素菌渣堆肥初始时的细菌数量比对照低1个数量级，放线菌数量在整个堆肥进程中都明显低于对照，堆肥结束时，随着菌渣含量的增加，放线菌数量逐渐下降，高温期真菌数量下降幅度随着菌渣含量增加而加大，表明林可霉素菌渣对细菌、放线菌和真菌均有不同程度的抑制。堆肥化后菌渣中林可霉素残留量的减少表明，在一定条件下堆肥处理可以将抗生素菌渣无害化和资源化。     

厌氧、好氧、厌氧/好氧交替状态对活性污泥性质的影响

实验采用活性污泥处理模拟印染废水,研究厌氧、好氧、厌氧/好氧交替3种条件对活性污泥性质的影响。3种实验条件下,污泥沉降比(SV%)均基本保持在18%~25%之间,污泥容积指数(SVI)保持在62~66 m L/g之间。活性污泥混合液中胞外聚合物(EPS)除EPSB-蛋白质浓度持续升高外,其余形式均呈现积累、达到最大值后下降的趋势,其中厌氧/好氧交替条件下EPS浓度最高而好氧条件下最小。在整个实验期间,活性污泥的脱氢酶活性基本呈上升状态,在厌氧/好氧间歇曝气条件下脱氢酶活性最高、好氧条件次之、厌氧条件最低,最终3种条件下的脱氢酶活性分别为31.27、26.63和24.37 mg/(g·h)。活性污泥中ATP浓度基本呈现先增加后减小、再趋于稳定的变化趋势。实验结果表明,活性污泥表观产率系数顺序是好氧厌氧厌氧/好氧交替运行,厌氧/好氧交替实现了系统内污泥减量,微生物的产率系数和能量状态密切相关。脱氢酶活性对污染物的降解影响明显,而实验条件下微生物能量状态和污泥减量并不对污染物降解产生影响。     

市政污泥堆肥过程中微生物群落的动态变化

基于磷脂脂肪酸技术研究堆肥过程中的微生物群落的动态变化,从微生物结构演替的角度为优化堆肥工艺提供一定的理论依据。结果表明,在污泥高温好氧快速堆肥反应的前中期细菌占主导作用,且在整个堆肥期间丰度较高(总共检测出33种细菌磷脂脂肪酸标记物),其结构变化与堆肥反应温度变化有着密切的联系。细菌的比例增长主要集中在堆肥反应中温度较高的时期。所检测到的真菌属PLFA16:00、18:1w9c在微生物群落结构中所占的比例没有明显的变化,摩尔百分数维持在30%左右,可以推测其对污泥中木质素、纤维素这些大分子难降解的物质有一定的代谢分解作用,故受堆肥环境参数变化的影响较小,建议在堆肥中期接种合适的真菌、放线菌,增加堆肥后期微生物的代谢潜能,提高堆肥反应的效率,提升堆肥产品的肥力。     

乙草胺对土壤微生物的影响研究

研究了乙草胺在6种不同浓度下对土壤微生物种群数量及土壤中细菌、放线菌、真菌生长速率的影响.采用密闭法测定乙草胺对土壤微生物呼吸的影响.结果表明,乙草胺对土壤微生物种群数量及土壤中细菌、放线菌、真菌生长速率均有一定的抑制作用,对土壤微生物呼吸作用具有明显的抑制作用.     

牛粪自然好氧发酵微生物变化规律

以新鲜牛粪进行好氧堆肥,每间隔3d取样,以牛肉蛋白胨、高氏一号、PDA、豆芽汁为培养基,以稀释法,进行发酵微生物分离、培养、计数和鉴定.结果表明,新鲜牛粪中微生物主要为细菌；发酵过程中,细菌数量大于放线菌、霉菌约104～ 105倍,细菌是发酵过程中的优势微生物；中温性细菌是升温阶段主要作用菌群；嗜热放线菌及嗜热细菌是高温阶段优势菌群；霉菌是降温阶段优势菌群.进一步鉴定表明,细菌类群中的芽孢杆菌、纤维单胞菌,放线菌类群中的小多孢菌、小单孢菌、高温放线菌,霉菌类群中的木霉、曲霉、青霉等为发酵过程中的优势种类.酵母菌未参与发酵过程.     

红霉素生产废水中微生物群落结构分析

采用聚合酶链式反应-变性梯度凝胶电泳技术（PCR—DGGE）研究了序批式活性污泥法（SBR）处理红霉素生产废水过程中从厌氧处理阶段到好氧处理阶段的微生物群落结构变化，并对微生物群落的部分优势细菌进行了克隆测序和系统发育树分析。结果表明，微生物群落丰富度随SBR处理进程呈递增趋势；微生物群落的相似性在相邻的处理阶段间相对较高，相隔越远的处理阶段间则越低；6种优势菌的同源性均在95％以上，其中有4种细菌均为厌氧和好氧处理阶段的优势菌，有1种细菌仅为好氧处理阶段的优势菌。     

蔬菜与餐厨垃圾厌氧发酵启动阶段微生物分析

为了研究厌氧发酵启动阶段微生物菌群结构、数量变化情况与沼气产量的关系，分别对蔬菜废弃物和餐厨垃圾单一物料发酵进行分析，并测定pH值、挥发性脂肪酸（VFA）、氧化还原电位。结果表明，餐厨垃圾比蔬菜废弃物的启动时间长，但产气持久。蔬菜废弃物中细菌达峰值的时间早于餐厨垃圾，说明蔬菜废弃物中的有机质更利于微生物降解利用。两种原料中的微生物群落结构变化一致，启动阶段初期好氧和兼性厌氧细菌属优势菌，其中产酸菌增殖速率高于氨化细菌，是启动阶段降解有机质的主要菌群。随后厌氧细菌快速增殖，13增殖速率由不足20％增长到近100％并保持稳定。厌氧纤维素降解菌在启动阶段增殖较慢，原料中纤维素降解在厌氧发酵后期。原料液VFA中丁酸含量最多，最高浓度4．7mg／mL以上，占有机酸总量总量的46％以上，厌氧发酵类型为丁酸发酵型。     

3种污泥对磺胺二甲基嘧啶的吸附性能

研究了厌氧颗粒污泥、厌氧污泥及好氧污泥对磺胺二甲基嘧啶(SM2)的吸附性能。当SM2初始浓度为50μg/L时,采用活性污泥灭活吸附,考察了吸附平衡时间、吸附等温线及温度对污泥吸附的影响,并比较了失活污泥与活性污泥的吸附性能。结果表明,3种污泥对SM2的吸附均在1 h内达到吸附平衡;3种失活污泥对SM2的吸附都可用Freundl-ich和Langmuir吸附模型来描述,并且Freundlich吸附模型的拟合效果要好于Langmuir模型(R2F>R2L);温度对3种污泥吸附影响规律一致,并且吸附常数KF(15℃)>KF(25℃)>KF(35℃),这说明吸附为放热反应,低温有利于吸附反应的进行。活性污泥对SM2的吸附与失活污泥吸附规律一致,都符合Freundlich模型。3种活性污泥对SM2的去除是吸附和降解的共同作用,并且都是降解占主导地位,降解效率为厌氧污泥>好氧污泥>厌氧颗粒污泥。     

Effects of metsulfuron-methyl on the microbial population and enzyme activities in wheat rhizosphere soil

The effects of metsulfuron-methyl, a sulfonylurea herbicide, on the wheat soil microorganisms were evaluated by the methods of microbial inoculation culture, and the activities of three enzymes were measured using the colorimetric method. The tolerant microorganisms that can resist 500 microg x g(-1) metsulfuron-methyl in the counting culture medium were studied specially. Metsulfuron-methyl distinctly inhibited the common aerobic heterotriphic bacteria, but the effects on common fungi and common actinomycete were not evident. In the meantime, the number of tolerant fungi increased greatly in the rhizosphere after the application of metsulfuron-methyl in contrast to the significant decrease of the amount of tolerant actinomycete. It indicates that fungi might turn into the dominant microbial type and actinomycete is the sensitive factor in the soil polluted by sulfonylurea residues. The population of aromatic compounds-decomposing bacteria, aerobic azotobacter, and nitrite bacteria all increased in the earlier period, but the aerobic azotobacter decreased rapidly in number 30 days later, and the amount of nitrite bacteria also showed a temporary decrease with time 15 days later. However, the denitrifying bacteria just began to increase significantly after the crops had grown for 50 days. The amount of sulfur-oxidizing bacteria gradually decreased with the growth of crops, and so were the sulfate-reducing bacteria after metsulfuron-methyl application. To all types of microorganisms, there were more microbes in rhizosphere samples than those in nonrhizosphere except aerobic azotobacter. It means the growth of wheat root system can stimulate the growth of most microorganisms. The activities of hydrogen peroxidase and polyphenol oxidase in soil samples after metsulfuron-methyl application were notably lower than those in the control, and the difference of the activities between the samples of rhizosphere and nonrhizosphere was evident. On the contrary, the activity of dehydrogenase was not inhibited by the application of metsulfuron-methyl, and the rhizosphere effect was not obvious either.     

Microbial biomass and activity in a Brazilian soil amended with untreated and composted textile sludge

This laboratory study examines the effect of application of untreated and composted textile sludge on microbial biomass and activity in a Brazilian soil. The soil was amended with untreated and composted sludge at rates equivalent of 6.4t ha(-1) (0.64 g per 100g of soil) and 19t ha(-1) (1.90 g per 100g of soil), respectively, and were incubated at 28 degrees C for 60 days and daily sampled for microbial activity. An additional experiment, in the same condition, was conduced for evaluation of microbial biomass and enumeration of microorganisms at 15, 30 and 60 days after incubation. The application of composted sludge increased significantly the microbial biomass and activity, and bacteria number of soil. There were not differences in the microbial activity and bacteria number among the control and untreated sludge amended soils. In conclusion, after 2 months of incubation, the effects of the two amendments on soil microorganisms were: microbial biomass, soil respiration and bacteria number were increased only in composted sludge treated soil. qCO2 and fungi number were not affected by untreated and composted sludge.     

Effects of butachlor on microbial populations and enzyme activities in paddy soil

This paper reports the influences of the herbicide butachlor (n-butoxymethlchloro -2', 6'-diethylacetnilide) on microbial populations, respiration, nitrogen fixation and nitrification, and on the activities of dehydrogenase and hydrogen peroxidase in paddy soil. The results showed that the number of actinomycetes declined significantly after the application of butachlor at different concentrations ranging from 5.5 microg g(-1) to 22.0 microg g(-1) dried soil, while that of bacteria and fungi increased. Fungi were easily affected by butachlor compared to the bacteria. The growth of fungi was retarded by butachlor at higher concentrations. Butachlor however, stimulated the growth of anaerobic hydrolytic fermentative bacteria, sulfate-reducing bacteria (SRB) and denitrifying bacteria. The increased concentration of butachlor applied resulted in the higher number of SRB. Butachlor inhibited the growth of hydrogen-producing acetogenic bacteria. The effect of butachlor varied on methane-producing bacteria (MPB) at different concentrations. Butachlor at the concentration of 1.0 microg g(-1) dried soil or less than this concentration accelerated the growth of MPB, while at 22.0 microg g(-1) dried soil showed an inhibition. Butachlor enhanced the activity of dehydrogenase at increasing concentrations. The soil dehydrogenase showed the highest activity on the 16th day after application of 22.0 microg g(-1) dried soil of butachlor. The hydrogen peroxidase could be stimulated by butachlor. The soil respiration was depressed during the period from several days to more than 20 days, depending on concentrations of butachlor applied. Both the nitrogen fixation and nitrification were stimulated in the beginning but reduced greatly afterwards in paddy soil.     

剩余污泥发酵产酸特征及基质释放规律研究

剩余污泥发酵既能实现污泥减量,又能获得污水生物脱氮除磷所需的挥发性脂肪酸VFAs等。采用序批式污泥发酵实验,在(30±1)℃的条件下,研究剩余污泥投配比对序批式污泥发酵系统污泥减量、产酸以及基质释放过程的影响,探索VFAs生成最大化的条件。实验结果表明:投加接种污泥不能明显提高序批式污泥发酵系统剩余污泥的减量效果,但可以改善污泥的产酸特性;当污泥投配比大于50%时,发酵过程中将出现2个VFAs浓度峰,且第二次峰浓度更大;较为理想的序批式污泥发酵投配比是60%~80%、发酵时间为5 d或25 d,前者VFAs表观转化率最大(约24%),后者发酵液中VFAs浓度最高(约600 mg/L);发酵过程中,NH4+-N总体呈上升趋势,磷浓度发酵5 d时达到最大值。     

Odours from pulp mill effluent treatment ponds: the origin of significant levels of geosmin and 2-methylisoborneol (MIB)

Pulp and paper mills are well known for their sharp, sulphurous stack emissions, but the secondary treatment units also can be significant contributors to local odour. This study investigated the source(s) of earthy/musty emissions from a mixed hardwood pulp mill in response to a high local odour. Samples from five sites in the mill over five months were analyzed for earthy/musty volatile organic compounds (VOCs), examined microscopically, and plated for bacteria and moulds. In all cases, activated sludge showed substantial geosmin levels and to a lesser extent 2-methylisoborneol (MIB) at 2000-9000 times their odour threshold concentrations (OTCs). These VOCs were lower or absent upstream and downstream, suggesting that they were produced within the bioreactor. Geosmin and MIB were highest in late summer and declined over winter, and correlated with different operating parameters. Geosmin was most closely coupled with temperature and MIB with nitrogen uptake. Cyanobacteria were present in all sludge samples, but actinomycetes were not found. Gram-negative bacteria and one fungal species isolated from the bioreactor and secondary outfall tested negative for geosmin or MIB. We conclude: (i) geosmin and MIB contribute significantly to airborne odours from this mill, but are diluted below OTC levels at the river; (ii) these VOCs are generated by biota in the activated sludge; and (iii) cyanobacteria are likely primary source(s). The growth of cyanobacteria in activated sludge represents a loss of energy to the heterotrophic population; thus earthy/musty odours may represent a diagnostic for less than optimal conditions.     

接种外源微生物菌剂对香蕉茎秆堆肥的影响

为了研究接种外源微生物菌剂对香蕉茎秆堆肥的影响,本实验采用高温好氧堆肥技术,设计了对照（不接菌）、接种白腐菌及棱盖多孔菌3个处理,探讨了不同处理堆肥过程中堆体温度、水分、pH值、电导率、有机碳、C/N、发芽指数及堆肥质量的变化情况。结果表明,接种微生物菌剂处理的温度均高于对照,且高温期持续时间相对较长,以接种白腐菌处理的高温持续时间最长;接种外源微生物菌剂对堆肥含水率、pH、EC、全碳、C/N变化影响不大;与对照相比,接种白腐菌可增加全氮及全钾的含量,有利于提高堆肥产品质量;接种白腐菌处理在36 d（GI〉50%）就达到腐熟,比对照提前8 d腐熟,明显缩短堆肥腐熟时间;而接种棱盖多孔菌处理比对照推迟10 d腐熟,共需54 d不利于香蕉茎秆堆肥的进行。     

Effects of Metsulfuron-Methyl on the Microbial Population and Enzyme Activities in Wheat Rhizosphere Soil

The effects of metsulfuron-methyl, a sulfonylurea herbicide, on the wheat soil microorganisms were evaluated by the methods of microbial inoculation culture, and the activities of three enzymes were measured using the colorimetric method. The tolerant microorganisms that can resist 500 μ g·g^?1 metsulfuron-methyl in the counting culture medium were studied specially. Metsulfuron-methyl distinctly inhibited the common aerobic heterotriphic bacteria, but the effects on common fungi and common actinomycete were not evident. In the meantime, the number of tolerant fungi increased greatly in the rhizosphere after the application of metsulfuron-methyl in contrast to the significant decrease of the amount of tolerant actinomycete. It indicates that fungi might turn into the dominant microbial type and actinomycete is the sensitive factor in the soil polluted by sulfonylurea residues. The population of aromatic compounds–decomposing bacteria, aerobic azotobacter, and nitrite bacteria all increased in the earlier period, but the aerobic azotobacter decreased rapidly in number 30 days later, and the amount of nitrite bacteria also showed a temporary decrease with time 15 days later. However, the denitrifying bacteria just began to increase significantly after the crops had grown for 50 days. The amount of sulfur-oxidizing bacteria gradually decreased with the growth of crops, and so were the sulfate-reducing bacteria after metsulfuron-methyl application. To all types of microorganisms, there were more microbes in rhizosphere samples than those in nonrhizosphere except aerobic azotobacter. It means the growth of wheat root system can stimulate the growth of most microorganisms. The activities of hydrogen peroxidase and polyphenol oxidase in soil samples after metsulfuron-methyl application were notably lower than those in the control, and the difference of the activities between the samples of rhizosphere and nonrhizosphere was evident. On the contrary, the activity of dehydrogenase was not inhibited by the application of metsulfuron-methyl, and the rhizosphere effect was not obvious either.