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1.
数学模拟好氧颗粒污泥的形成及水力剪切强度对颗粒粒径的影响 总被引:4,自引:4,他引:0
以生物膜数学模型和活性污泥数学模型为基础,建立好氧颗粒污泥一维数学模型,并模拟营养物质的去除、颗粒粒径变化、反应器周期表现以及好氧颗粒污泥内DO和菌群分布.模拟有机物SS浓度和出水NH4+-N浓度逐渐降低,在大约50 d左右达到稳定,50 d后模拟出水浓度分别<25 mg.L-1和<1.5 mg.L-1.模拟出水NO3--N浓度随着粒径的增加呈现降低趋势.当颗粒粒径由模拟30 d时的1.1 mm增加到100 d时的2.5 mm,颗粒污泥缺氧区面积相应增加,总氮(TN)的去除率由不到10%增加到91%左右,最终模拟出水NO3--N浓度降低到<3 mg.L-1.在好氧颗粒污泥系统内,由于氧气传质阻力,模拟颗粒污泥外层DO浓度高而内层浓度低,颗粒内可以发生同时硝化反硝化,且好氧颗粒污泥内DO特征随时间而发生变化.在好氧初期,好氧颗粒污泥代谢活性高,模拟DO传质深度大约为100~200μm;而在好氧末期,模拟DO传质深度为800μm.模拟自养菌主要分布在DO浓度高的颗粒外层,异养菌分布在整个颗粒.当水力剪切系数kde由0.25(m.d)-1逐渐增加到5(m.d)-1时,模拟颗粒平衡粒径依次由3.5 mm左右减小到大约1.8 mm.在不同水力剪切强度下模拟颗粒污泥生长特征相似,其平衡状态下粒径随曝气强度的增加而减小,可以通过控制曝气强度来控制好氧颗粒污泥的平衡粒径. 相似文献
2.
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0.166,0kgN/(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0.158,0.105,0.094kgN/(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 0.180,0kgN/(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0.026,0.096,0.108kgN/(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. 相似文献
3.
ABR耦合CSTR一体化工艺好氧颗粒污泥亚硝化性能调控及稳态研究 总被引:5,自引:4,他引:1
本研究将厌氧折流板反应器(ABR)末端两隔室分别改为曝气池与沉淀池,使其成为厌氧耦合好氧一体化工艺,探索连续流条件下好氧颗粒污泥亚硝化实现条件.分别在厌氧区和好氧区接种厌氧颗粒污泥和好氧颗粒污泥,控制好氧区沉淀时间为1 h,好氧区C/N比由1逐渐降低至0.4,并逐步提高进水氨氮容积负荷[由0.89 kg·(m3·d)-1提高至2.23 kg·(m3·d)-1].经45 d的运行,在好氧区成功培养出成熟的亚硝化颗粒污泥,其外观呈黄色,结构密实、边缘清晰,出水亚硝酸盐积累率稳定在80%左右.游离氨(FA)和游离亚硝酸(FNA)共同抑制作用是实现稳定亚硝酸盐积累的关键因素.运行初期部分好氧颗粒污泥出现解体现象,好氧区产生大量絮体;但后期絮体逐步转化为小粒径颗粒污泥,表明一定数量的有机碳源有利于絮体颗粒化,而大量富集慢速生长的硝化细菌对颗粒的稳定维持起重要作用. 相似文献
4.
取成熟的好氧颗粒污泥,在同一测试装置中采用相同的曝气条件进行体积溶氧传递系数(kLa)的测试,当传统活性污泥和成熟好氧颗粒污泥浓度MLSS为2 000、4 000、6 000、8 000 mg·L-1时,其kLa(min-1)值分别为0.586 1±0.009 5、0.586 1±0.027 2、0.555 6±0.016 8、0.533 8±0.026 8和0.645 5±0.027 6、0.632 0±0.075 5、0.618 5±0.062 5、0.640 6±0.055 5,表明颗粒污泥kLa值高于同浓度条件下的絮体污泥,且随浓度增加,絮体污泥氧传递效率下降而颗粒污泥无明显变化.对好氧颗粒污泥进行筛分后,大颗粒和小颗粒在污泥浓度相同、体积相同、表面积相同以及个数相同的情况下二者的kLa值均无明显差别,由此可以推断,这些因素对好氧颗粒污泥kLa的影响可以忽略.研究结果对于污水处理厂节能运行具有一定的参考价值. 相似文献
5.
实验考察两种接种污泥——絮状活性污泥和厌氧颗粒在膜生物反应器(MBR)中培养好氧颗粒污泥过程中理化特性的差异,实验结果表明:好氧颗粒污泥均以丝状菌交织构成网状框架结构,球菌、杆菌穿插其间,并且外围附着一些原、后生动物;由厌氧颗粒污泥形成的好氧颗粒表面结构比由絮状污泥形成的好氧颗粒污泥表面结构更加规则致密。由絮状污泥和厌氧颗粒污泥培养成熟的好氧颗粒污泥平均粒径分别为1.3mm和1.5mm,它们的粒径比较接近,但都小于厌氧颗粒污泥。两种好氧颗粒污泥的SVI值75mL/g,沉降速度都随粒径的增大而增大,范围为25~89m/h,都具有良好的沉降性能。两种接种污泥在MBR反应器中培养好氧颗粒污泥的过程中,MLVSS的增殖率均先为负值,然后逐渐上升变成正值,并且在好氧颗粒成熟后稳定在一定的水平。 相似文献
6.
SBR中厌氧颗粒污泥向好氧颗粒污泥的转化 总被引:25,自引:10,他引:15
在SBR反应器中以醋酸钠为碳源,UASB厌氧颗粒污泥作为接种污泥,在好氧曝气条件下运行.通过观察污泥颗粒形态、结构等的变化,发现在运行中污泥颗粒经历了形态保持,成分置换的过程.污泥浓度先增加后降低,在运行35 d后逐渐稳定在5g/L,SVI值稳定在30~40mL/g的水平.在40~60d内反应器中颗粒污泥一直占主体成分,悬浮相浓度低于0.5g/L.在好氧条件下最终颗粒污泥形态、大小稳定,表明好氧颗粒污泥已经成功获得,好氧颗粒污泥与接种污泥相比在粒径、沉降速度、含水率以及惰性成分的含量上都有一定的变化.电镜观察还表明,原厌氧颗粒污泥中的微生物以球菌为主,而获得的好氧颗粒污泥中的微生物以丝状菌和杆菌为主. 相似文献
7.
污泥龄对低氧丝状菌活性污泥微膨胀系统的影响 总被引:2,自引:0,他引:2
为了研究污泥龄(SRT)对低氧丝状菌活性污泥微膨胀系统的影响,采用序批式间歇反应器(SBR)进行试验,分别按照厌氧/好氧和单级好氧的方式运行,考察了不同SRT下丝状菌污泥微膨胀系统的沉降性、脱氮除磷过程以及污泥特性的变化.结果表明,在好氧水力停留时间充分的条件下,低氧环境不但不会影响丝状菌微膨胀污泥的硝化进程,而且还有助于同步硝化反硝化(SND)、单级好氧除磷的发生.厌氧/好氧运行时,SRT与活性污泥的比硝化速率、比释磷速率和比吸磷速率成反比,与SND率和污泥的含磷量成正比.单级好氧运行时,减小SRT对硝化过程影响不大,但是有助于改善除磷效果.活性污泥的比耗氧速率(SOUR)、胞外聚合物(EPS)中多糖与蛋白质含量的比值、以及粘度都与SRT成反比.适当地减小SRT可以改善丝状菌微膨胀污泥的沉降性.厌氧/好氧运行时,厌氧段微氧环境易引发过度丝状菌污泥膨胀;单级好氧运行时,SRT过低会造成污泥黏性骤增而引发黏性污泥膨胀. 相似文献
8.
不同好氧颗粒污泥中微生物群落结构特点 总被引:3,自引:0,他引:3
为了探讨活性污泥好氧颗粒化过程对微生物种群的影响、不同底物及不同颗粒化方法培养的好氧颗粒污泥中微生物群落结构的差异,以接种污泥、模拟废水好氧颗粒污泥和分别投加粉末活性炭和硅藻土的实际生活污水好氧颗粒污泥为研究对象,利用PCR-DGGE对比分析了接种污泥和好氧颗粒污泥中的微生物群落结构.结果表明:活性污泥好氧颗粒化过程会减少微生物种群多样性,影响颗粒污泥稳定性的细菌被淘汰,而聚磷菌、反硝化菌、难降解有机物降解菌等污水处理功能微生物都在颗粒化过程中得到保留.活性污泥好氧颗粒化过程中能够实现亚硝化细菌(AOB)一定程度的富集.与接种活性污泥相比,好氧颗粒污泥中AOB的多样性指数与均匀性指数均有提高.好氧颗粒污泥中的优势菌群主要分布于变形菌门(Proteobacteria)、拟杆菌门(Bacteroidetes)和未培养菌(uncultured bacterium).其中AOB均属于β-Proteobacteria的亚硝化单胞菌属(Nitrosomonas). 相似文献
9.
好氧颗粒污泥中丝状微生物生长研究 总被引:5,自引:0,他引:5
通过在序批式摇床反应器(SSBR)中分别接种絮状活性污泥与厌氧颗粒污泥来处理含盐及淡水2种废水并培养好氧颗粒污泥,研究好氧颗粒污泥中丝状微生物的过度生长及可行的控制措施.结果表明,进水水质与接种污泥类型都会影响颗粒污泥中丝状微生物的生长.同是接种好氧絮状污泥的R1、R3,由于R1进水为含盐废水而R3为淡水,R1中颗粒污泥丝状化程度低于R3,而接种厌氧颗粒污泥并处理含盐废水的R2颗粒污泥丝状化程度最低.当好氧颗粒污泥外部出现明显丝状微生物过度生长时,各反应器中颗粒污泥平均丝状化程度△分别达到△R1=1.4、△R2=1.2及△R3=2.0.对各反应器颗粒污泥中丝状微生物进行鉴定,R1颗粒中丝状微生物主要为Eikelboom 0092及Nocardia spp.,R2中主要为.Fungi spp.及Nocardia spp.,R3中主要为S.natans 及H.hydrossis,这几种类型丝状微生物一般出现在污泥龄长、溶解氧浓度低及基质易降解的环境中,但由于好氧颗粒污泥结构不同于传统活性污泥,试验通过控制污泥负荷、污泥龄及曝气量等并不能有效控制颗粒中丝状微生物的过度生长.试验将各反应器进水基质由易降解的葡萄糖配水换为难生物降解废水时,能快速有效地控制颗粒污泥中丝状微生物的过度生长. 相似文献
10.
在实验室序批式活性污泥法(SBR)处理系统中以普通活性污泥为接种污泥,采用厌氧-好氧的运行方式提高系统的除磷效果.同时培养颗粒污泥,并对系统中磷的变化和去向进行分析.结果表明,整个试验共运行146 d,成熟颗粒污泥平均粒径为603μm,污泥体积指数(SVI)约为30 mL.g-1,COD去除率可达90%,磷的去除率可达95%左右.颗粒污泥系统除厌氧放磷和好氧聚磷以外,还存在明显的污泥颗粒积磷现象.磷的去除途径主要为:系统排泥(出水悬浮物和专门排泥)和污泥积磷.由厌氧末期颗粒污泥的X射线衍射(XRD)分析结果可知,化学沉淀是污泥积磷的一种重要方式,大量的金属离子会与磷形成无机盐沉积在污泥颗粒上. 相似文献
11.
Aerobic granules seeded with activated sludge flocs and pellets (obtained from activated sludge flocs) were cultivated in two
sequencing batch reactors and their characteristics were compared. Compared with granules seeded with activated sludge flocs,
those seeded with pellets had shorter start-up time, larger diameter, better chemical oxygen demand removal e ciency, and higher
hydrophobicity, suspended solid concentration, and Mg2+ content. The di erent inocula led the granule surface with di erent microbial
morphologies, but did not result in di erent distribution patterns of extracellular polymeric substances and cells. The anaerobic
bacterium Anoxybacillus sp. was detected in the granules seeded with pellets. These results highlighted the advantage of pellet over
activated sludge floc as the seed for aerobic granulation and wastewater treatment. 相似文献
12.
针对好氧颗粒污泥的快速培养,研究了流体流速对好氧颗粒污泥形成特性的影响机制.由于反应器构型的差异,造成水力剪切力与流体特性的不同,从而对好氧颗粒污泥的形成产生较大影响.研究表明,在圆筒式SBR反应器中接种厌氧活性污泥,在36d时培养得到了成熟的颗粒,与挡板式反应器相比提前了4d左右,且MLSS提高了16.2%,达到5023mg/L;颗粒也更加致密,SVI达到45mL/g,远好于挡板式SBR反应器(序批式反应器)的SVI 63mL/g.原因是与挡板式SBR反应器相比,圆筒式SBR反应器的平均液相流速更高,气泡分布更均匀,水力剪切力更强.因此圆筒式SBR反应器培养好氧颗粒污泥的时间较短,污泥颗粒化的速度提高,得到的颗粒污泥更加紧凑密实. 相似文献
13.
14.
好氧颗粒污泥处理高含盐废水研究 总被引:17,自引:5,他引:12
试验采用序批式摇床反应器(SSBR)在高含盐废水中利用不同类型接种污泥培养出了好氧颗粒.结果表明,好氧颗粒污泥能够有效处理高含盐废水并且具有很好的抗盐度冲击能力.当废水盐度小于10 g/L NaCl并且进水基质为葡萄糖时,利用好氧颗粒污泥处理该废水可以取得70.3%~97.6%的TOC去除率.当进水盐度达到35 g/L NaCl并且进水基质为难降解Vc废水时,利用好氧颗粒污泥处理该含盐废水能够取得与相同基质相同运行条件下淡水废水中相似的70%的TOC去除率.试验在含盐废水中得到了粒径为0.5~3 mm的好氧颗粒污泥,其沉降速度大大高于淡水对照组中得到的好氧颗粒污泥沉降速度.相对淡水对照组中好氧颗粒污泥,含盐废水中好氧颗粒具有污泥产率更低、污泥活性(OUR)更高、颗粒稳定性更好的优势.从不同接种污泥类型来看,好氧絮状污泥和厌氧颗粒污泥接种都能快速实现污泥好氧颗粒化,但絮状污泥接种实现好氧颗粒化所需的时间更短.另外,在相同运行条件下,接种好氧絮状污泥反应器取得的TOC去除效果优于接种厌氧颗粒污泥反应器,但厌氧颗粒污泥接种具有更强的抗盐度冲击能力. 相似文献
15.
石化废水剩余污泥在厌氧消化时,污泥停留时间长,且产气量较低,并且反应器容积较大,所需资金投入较高。污泥厌氧消化预处理能够改变污泥特性,缩短了后续消化时间,提高甲烷产量,减少剩余污泥量。综述了各种污泥预处理技术的最新进展,分析了石化污泥厌氧消化预处理的可行性。 相似文献
16.
Sludge granulation is considered to be the most critical parameter governing successful operation of an upflow anaerobic sludge blanket and expanded granular sludge bed (EGSB) reactors. Pre-granulated seeding sludge could greatly reduce the required start-up time. Two lab-scale and a pilot-scale EGSB reactors were operated to treat Shaoxing Wastewater Treatment Plant containing wastewater from real engineering printing and dyeing with high pH and sulfate concentration. The microbiological structure and the particle size distribution in aerobic excess sludge, sanitary landfill sludge digested for one year, and the granular sludge of EGSB reactor after 400 d of operation were analyzed through scanning electron microscopy (SEM) and sieves. The lab-scale EGSB reactor seeded with anaerobic sludge after digestion for one year in landfill showed obviously better total chemical oxygen demand (TCOD) removal efficiency than one seeded with aerobic excess sludge after cation polyacrylamide flocculation-concentration and dehydration. The TCOD removed was 470.8 mg/L in pilot scale EGSB reactor at short hydraulic retention time of 15 h. SEM of sludge granules showed that the microbiological structure of the sludge from different sources showed some differences. SEM demonstrated that Methanobacterium sp. was present in the granules of pilot-scale EGSB and the granular sludge produced by landfill contained a mixture of anaerobic/anoxic organisms in abundance. The particle size distribution in EGSB demonstrated that using anaerobic granular sludge produced by sanitary landfill as the seeding granular sludge was feasible. 相似文献
17.
Cultivation of aerobic granules for simultaneous nitrification and denitrification in two sequencing batch airlift bioreactors was studied. Conventional activated floc and anaerobic granules served as main two inoculated sludge in the systems. Morphological variations of sludge in the reactors were observed. It was found that the cultivation of aerobic granules was closely associated with the kind of inoculated sludge. Round and regular aerobic granules were prevailed in both reactors, and the physical charactedstics of the aerobic granules in terms of settling ability, specitic gravity, and ratio Of water containing were distinct wnen the inoculate sludge differe. Aerobic granules formed by seeding activated floc are more excellent in simultaneous nitrification and denitrification than that by aerobic granules formed from anaerobic granules. It was concluded that inoculated sludge plays a crucial role in the cultivation of aerobic granules for simultaneous nitrification and denitrification. 相似文献
18.
Shasha Yuan Mingming Gao Hui M Muhammad Zaheer Afzal Yun-Kun Wang Mingyu Wang Hai Xu Shu-Guang Wang Xin-Hua Wang 《环境科学学报(英文版)》2018,30(5):154-160
Inexact mechanism of aerobic granulation still impedes optimization and application of aerobic granules. In this study, the extended Derjaguin, Landau, Verwey, and Overbeek(XDLVO) theory and physicochemical properties were combined to assess the aggregation ability of sludge during aerobic granulation process qualitatively and quantitatively. Results show that relative hydrophobicity of sludge and polysaccharide content of extracellular polymeric substances(EPS) increased, while electronegativity of sludge decreased during acclimation phase. After 20 days' acclimation, small granules began to form due to high aggregation ability of sludge. Since then, coexisted flocs and granules possessed distinct physicochemical properties during granulation and maturation phase. The relative hydrophobicity decreased while electronegativity increased for flocs, whereas that for granules presented reverse trend. Through analyzing the interaction energy using the XDLVO theory, small granules tended to self-grow rather than self-aggregate or attach of flocs due to poor aggregation ability between flocs and granules during the granulation phase. Besides, remaining flocs were unlikely to self-aggregate owing to poor aggregation ability, low hydrophobicity and high electronegativity. 相似文献