去除污泥中重金属铬的生物淋滤反应器设计与应用

用微生物方法去除污泥中重金属（生物淋滤法）是近年来发展的新技术，探索工程化的条件有重要的应用价值。设计了一套容积为1m^3的生物淋滤反应器，由生物淋滤池、搅拌器、曝气器和空气压缩机等构成。其中，搅拌叶轮由平叶桨和斜叶桨组合而成。利用制革污泥进行了半连续的生物淋滤试验，结果表明，在反应器中污泥与菌体和营养物质能充分混匀，经过2-5d的处理，污泥pH持续下降到2．0以下，污泥中铬的溶出率达90％-99．5％。     

生物淋滤-Fenton对印染污泥脱水性能的影响

采用嗜酸性硫杆菌生物淋滤联合Fenton氧化法对印染污泥脱水性能进行了研究。结果表明,生物淋滤过程中pH下降速率随着硫粉添加量增加而变快,经生物淋滤处理后污泥的脱水性能在一定程度上得到了改善。对生物淋滤后的污泥进行了Fenton氧化处理,获得的最佳反应条件为反应时间2 h,H2O2和Fe2+添加量分别为6 g/L和0.5 g/L。在该条件下,污泥上清液中总有机碳(TOC)由20.8 mg/L增加到356.6 mg/L;污泥比阻(SRF)和滤饼含水率分别由5.98×1011s2/g和88.75%减少至1.26×1011s2/g和82.85%。生物淋滤-Fenton氧化法在污泥破解程度和脱水性能改善方面均优于单独Fenton氧化法。     

生物淋滤-Fenton对印染污泥脱水性能的影响

采用嗜酸性硫杆菌生物淋滤联合Fenton氧化法对印染污泥脱水性能进行了研究。结果表明,生物淋滤过程中pH下降速率随着硫粉添加量增加而变快,经生物淋滤处理后污泥的脱水性能在一定程度上得到了改善。对生物淋滤后的污泥进行了Fenton氧化处理,获得的最佳反应条件为反应时间2h,H2O2和Fe2＋添加量分别为6g／L和0．5g／L。在该条件下,污泥上清液中总有机碳（TOC）由20．8mg／L增加到356．6mg／L;污泥比阻（SRF）和滤饼含水率分别由5．98×10^11s2／g和88．75％减少至1．26×10^11 S2／g和82．85％。生物淋滤-Fenton氧化法在污泥破解程度和脱水性能改善方面均优于单独Fenton氧化法。     

生物淋滤改善城市污泥的脱水性能

污水处理过程中产生大量剩余污泥,使得污泥脱水逐渐成为污泥处理的关键环节。本研究采用生物淋滤方法处理城市污泥,改善污泥脱水性能。通过污泥比阻、滤饼含水率和离心脱水率的变化评价生物淋滤改善剩余污泥脱水性能的效能。综合考虑污泥脱水性能改善效果和运行成本,生物淋滤优化条件为:硫粉投加量3 g/L;Fe2+投加量4 g/L;接种物投加量(接种物与供试污泥的体积比,mL/mL)0.4。在优化条件下,污泥体系被酸化至pH为2.0左右需要36～48 h,淋滤污泥的比阻由1.26×1014 m/kg降至8.14×1012 m/kg,降低了93.54%,滤饼含水率从98.39%降至73.68%,同时污泥离心脱水率从72%提高到83%。回调淋滤污泥pH至6.0,污泥比阻继续降至8.27×1011 m/kg,污泥比阻降低99.34%,污泥从难脱水状态转化为易脱水状态。通过污泥体系中铁离子和污泥絮体特征的变化,分析生物淋滤改善污泥脱水性能的机理。作为底物投加的Fe2+在微生物氧化作用下快速转化为Fe3+。生物氧化产生的Fe3+的絮凝作用可能是生物淋滤改善污泥脱水性能的主要机理。     

生物淋滤法处理制革污泥的运行方式研究

生物淋滤技术浸提去除污泥中的重金属,是使污泥洁净化的有效方法.在自行设计的一套总容积为50 L的搅拌釜式反应器中进行制革污泥的生物淋滤试验.在连续曝气时,研究了连续搅拌方式和搅拌30 min后,停机30、45、60min再搅拌的间歇运行方式的效果.结果表明,连续搅拌运行以及搅拌30 min后停机30、45、60 min的间歇搅拌运行,分别经过48、60、84、156 h的生物淋滤,污泥的pH值下降到2.0以下,氧化还原电位(ORP)上升到530～545 mV,铬的溶出率达到99%以上;当固定供气量为9L/min时,污泥中的溶解氧保持在1.2～2.7 mg/L;在各种运行方式中,搅拌30 min再停机30 min的间歇运行方式,其淋滤效果与连续搅拌方式相近,而综合能耗最低,因此,搅拌30 min再停机30 min的间歇搅拌运行方式可作为工程应用的参考.     

生物淋滤法处理制革污泥的运行方式研究

生物淋滤技术浸提去除污泥中的重金属，是使污泥洁净化的有效方法。在自行设计的一套总容积为50L的搅拌釜式反应器中进行制革污泥的生物淋滤试验。在连续曝气时，研究了连续搅拌方式和搅拌30min后，停机30、45、60min再搅拌的间歇运行方式的效果。结果表明，连续搅拌运行以及搅拌30min后停机30、45、60min的间歇搅拌运行，分别经过48、60、84、156h的生物淋滤，污泥的pH值下降到2．0以下，氧化还原电位（ORP）上升到530～545mV，铬的溶出率达到99％以上；当固定供气量为9L／min时，污泥中的溶解氧保持在1．2～2．7mg／L；在各种运行方式中，搅拌30min再停机30min的间歇运行方式，其淋滤效果与连续搅拌方式相近，而综合能耗最低，因此，搅拌30min再停机30min的间歇搅拌运行方式可作为工程应用的参考。     

Fenton预处理对城市污泥重金属形态及生物淋滤溶出影响

针对生物淋滤处理城市污泥重金属Cr、As和Pd的溶出效率较低的问题,采用芬顿(Fenton)氧化法对城市污泥进行预处理,考察Fenton氧化对污泥中重金属Cr、As和Pd赋存形态转化及后继生物淋滤过程溶出率的影响。实验结果表明,经pH=4.00、Fe~(2+)=1.00 g·L~(-1)、H_2O_2=9 g·L~(-1)的条件下Fenton预处理后,重金属Cr、As和Pb的存在形态均由稳定性较强的可氧化态和残渣态向不稳定的弱酸提取态和可还原态转化,其不稳定态比重分别由15%、30%、9%提高到了24%、41%、11%;生物淋滤实验结果显示,由于重金属形态变化,重金属Cr、As和Pb溶出率分别由52.71%、11.15%、33.19%提升至60.76%、24.32%、45.96%。Fenton预处理联合生物淋滤法提高了对重金属Cr、As和Pb的去除效果,有助于实现污泥的无害化处理处置。     

好氧颗粒污泥对膜生物反应器污泥性能的影响

采用膜生物反应器进行含酚废水的处理,探讨投加好氧颗粒污泥对反应器中污泥性能的影响。结果表明,在膜生物反应器中投加好氧颗粒污泥能有效改善污泥性能,提高处理效果。从采用絮状污泥到逐渐增加好氧颗粒污泥投加量为100%的过程中,反应器中污泥浓度明显提高,MLSS由5 582 mg/L增加到8 168 mg/L;沉降性能得到改善,SVI由135.85 mL/g下降到29.36 mL/g;疏水性增强,Zeta电位由-20.302 mV升高到-4.325 mV;对含酚废水中COD、NH3-N的降解能力明显提高,COD、NH3-N、NO3-N去除率分别由87.3%、83.2%、55.3%增加到99.2%、94.9%、66.3%。改善了膜污染现象,膜通量衰减率由63.3%降低到42.8%。用二元多项式三维回归分析,得到污染物去除率关于好氧颗粒污泥投加量和反应器运行时间的二元方程,对指导好氧颗粒污泥膜生物反应器的连续运行具有重要意义。     

机械淋滤-厌氧生物组合工艺处理有机生活垃圾中试研究

采用机械淋滤/厌氧生物组合工艺,充分发挥机械淋滤反应器的水解酸化功能和厌氧生物反应器的产甲烷功能,对有机生活垃圾进行了中试规模处理。厌氧生物反应器经过接种,15 d驯化完成。厌氧反应器出水回流淋洗水量对机械淋滤反应器运行特征有较大影响,当回流淋洗水量为3.0 m3/d时,淋滤液COD、VFA第8天时浓度分别为41 000 kg/L和2 000 kg/L。对机械淋滤反应器/厌氧反应器组合工艺进行了多批次实验,每吨有机生活垃圾平均产生沼气87.2 m3,甲烷含量稳定在75%,平均产沼系数为0.46 m3/kg COD,厌氧生物反应器出水COD平均值为560 mg/L,在对有机生活垃圾处理的同时实现有机生活垃圾资源化利用。     

基于生物淋滤的城市污泥重金属溶出及形态迁移

利用生物淋滤法处理城市污泥,以生物淋滤过程中pH、ORP(氧化还原电位)变化以及重金属(Zn、Cu、Cd)溶出率为指标,考察淋滤菌接种比例、初始pH、淋滤时间对生物淋滤的影响,并分析了生物淋滤前后,重金属形态变化以及重金属的生物有效性和迁移性。结果表明富集筛选的嗜酸性氧化亚铁硫杆菌(A.f)可有效溶出污泥中的重金属。生物淋滤最佳条件为:初始pH=4.00,淋滤菌接种比例30%,重金属Zn,Cu,Cd在第10天的整体处理效果最优,溶出率分别达到75.30%、50.40%和74.44%。BCR形态分析表明:原污泥中Zn,Cu,Cd主要以弱酸提取态、可还原态和氧化态存在,残渣态较少;生物淋滤之后,3种重金属弱酸提取态、可还原态和氧化态含量有不同程度降低,其中,可还原态含量降低最为显著,残渣态基本无变化,并且淋滤后污泥中重金属氧化态及残渣态所占比例较淋滤前高,污泥稳定性得到提升。生物淋滤可以通过减少污泥中重金属含量和改变重金属形态降低其生物有效性和迁移性。     

Bioleaching of heavy metals from livestock sludge by indigenous sulfur-oxidizing bacteria: effects of sludge solids concentration

A technologically and economically feasible process called bioleaching was used for the removal of heavy metals from livestock sludge with indigenous sulfur-oxidizing bacteria in this study. The effects of sludge solids concentration on the bioleaching process were examined in a batch bioreactor. Due to the buffering capacity of sludge solids, the rates of pH reduction, ORP rise and metal solubilization were reduced with the increase of the solids concentration. No apparent influence of solids concentration on sulfate produced by sulfur-oxidizing bacteria was observed when the solids concentration was less than 4% (w/v). A Michaelis-Menten type of equation was able to well describe the relationship between solids concentration and rate of metal solubilization. Besides, high efficiencies of metal solubilization were achieved after 16 d of bioleaching. Therefore, the bioleaching process used in this study could be applied to remove heavy metals effectively from the livestock sludge.     

Enhanced Cr bioleaching efficiency from tannery sludge with coinoculation of Acidithiobacillus thiooxidans TS6 and Brettanomyces B65 in an air-lift reactor

Bioleaching process has been demonstrated to be an effective technology in removing Cr from tannery sludge, but a large quantity of dissolved organic matter (DOM) present in tannery sludge often exhibits a marked toxicity to chemolithoautotrophic bioleaching bacteria such as Acidithiobacillus thiooxidans. The purpose of the present study was therefore to enhance Cr bioleaching efficiencies through introducing sludge DOM-degrading heterotrophic microorganism into the sulfur-based sludge bioleaching system. An acid-tolerant DOM-degrading yeast strain Brettanomyces B65 was successfully isolated from a local Haining tannery sludge and it could metabolize sludge DOM as a source of energy and carbon for growth. A combined bioleaching experiment (coupling Brettanomyces B65 and A. thiooxidans TS6) performed in an air-lift reactor indicated that the rates of sludge pH reduction and ORP increase were greatly improved, resulting in enhanced Cr solubilization. Compared with the 5 days required for maximum solubilization of Cr for the control (single bioleaching process without inoculation of Brettanomyces B65), the bioleaching period was significantly shorten to 3 days for the combined bioleaching system. Moreover, little nitrogen and phosphorous were lost and the content of Cr was below the permitted levels for land application after 3 days of bioleaching treatment.     

元素硫颗粒粒径对污泥重金属生物沥滤的影响

以城市污水处理厂剩余污泥作为处理介质,土著嗜酸氧化硫硫杆菌(Acidithiobacillus thiooxidans,A.thiooxi-dans)为主要沥滤微生物,采用序批式生物沥滤装置,就投加150~725μm的不同粒径元素硫对沥滤的酸化效果、硫酸根产率和重金属去除效果的影响进行了研究。结果表明,在元素硫投配量为3 g/L,曝气强度为1.0 L/(min.L)的条件下,元素硫粒径在165~215μm范围减小时能显著改善污泥酸化速度、提高酸化程度和硫酸根产率。底物元素硫的最佳粒径为165μm,此时沥滤体系pH下降速率为0.85个pH单位/d,硫酸根的产率为454.9 mg/(L.d),沥滤6 d后污泥中高浓度重金属Cu、Zn、Cd的去除率达到70.3%、81.2%、87.8%.     

废旧镍镉电池的生物沥滤处理——沥滤停留时间的影响研究

用污泥加硫酸化液沥滤镍镉电池中的重金属是一种全新的工艺,该工艺主要由生物酸化反应器和金属沥滤反应器两个反应器组成.生物酸化反应器中产生的酸液就是沥滤电池中重金属的反应液.研究表明,酸化液在沥滤反应池的停留时间对沥滤的效果有显著影响.在1、4、7、12 d 4个停留时间中,4 d的效果是最好的,对金属Cd和Ni都用40 d左右基本实现了全部滤除;1d略微慢一些,Cd用了40 d,Ni用了45 d;7 d和12 d的沥滤时间都长于50 d.4 d产生的金属废液量是1 d的1/4,考虑到后续处理金属沥滤废液的工作量,选择4d的停留时间要优于1d.     

生物法和化学法回收制革污泥中铬的对比研究

研究了嗜酸性硫杆菌(Thiobacillus)生物沥滤法和1:1硫酸化学沥滤法分离回收制革污泥中的铬.比较了嗜酸性硫杆菌生物沥滤法和化学沥滤法回收制革污泥铬过程中pH、氧化还原电位(ORP)、沉降比(SV)以及铬的沥滤率的变化.试验结果表明,pH是影响制革污泥中铬的沥滤率的关键因素.生物沥滤法在使污泥pH大幅度降低的同时,能很好地改善污泥的沉降性能,对铬的沥滤效果好于化学沥滤法.     

Degradation of inhibitory substances by heterotrophic microorganisms during bioleaching of heavy metals from anaerobically digested sewage sludge

The presence of organic acids was found to be inhibitory to the bioleaching of sewage sludge and the objective of the present study was to elucidate the roles of heterotrophic microorganisms in removing organic acids during the bioleaching of heavy metals from anaerobically digested sewage sludge. Microbiological analysis showed that acetic and propionic acids posed a severe inhibitory effect on iron-oxidizing bacteria as reflected by a sharp decrease in their viable counts in the first 4d and it only started to increase 2d after the depletion of both acids. Biodegradation of these inhibitory organic acids was revealed by sharp increases in total fungi and acidophiles between day 3 and day 5 which coincided with degradation of organic acids. This was further confirmed by the increases in total counts of both acetate and propionate degraders in the same period. Two yeast strains Y4 and Y5 with strong ability to degrade acetate and/or propionate were isolated and identified as Pichia sp. and Blastoschizomycetes capitatus, respectively. B. capitatus Y5 was an more important player in removing the inhibitory organic acids during the bioleaching process since it could utilize both acetate and propionate as sole carbon source while Pichia sp. Y4 was an strict acetate degrader. Results from the present study not only provided the evidence for biodegradation of organic acids by heterotrophs, but also disclosed a biological mechanism for the initiation of bioleaching of organic acid-laden sewage sludge.     

提高生物法分离制革污泥中铬分离效率的研究

在已确定污泥驯化最佳条件的基础上,通过改变滤材、液固分离条件,添加营养物质继续降低pH等方法,进行提高生物沥滤法分离制革污泥中铬的分离效率的研究。同时考察化学沥滤法（1∶1硫酸）在相同条件下的分离效率。试验结果表明：用相应pH值酸液（1∶1硫酸配制）淋洗,淋洗+闷洗和抽真空＋酸液淋洗等过滤方式可提高铬的分离效率。生物沥滤中当pH值下降至1.8时,分离效率即可达到94.65%,与直接用蒸馏水淋洗相比要高得多。化学沥滤中当pH值下降到1时,分离效果可达96.7%,沥滤污泥中剩余铬含量可达到制革污泥农用标准。     

Comparison of sludge characteristics and PCR-DGGE based microbial diversity of nanofiltration and microfiltration membrane bioreactors

The objective of this study was to compare the sludge characteristics and microbial community diversity between the submerged nanofiltration membrane bioreactor (NF MBR) and microfiltration membrane bioreactor (MF MBR) treating the same municipal wastewater. The influence of a higher concentration of organic matter and salt was investigated. The results of water qualities showed that the dissolved organic carbon (DOC), total phosphorus (T-P) and salt concentrations of the supernatant in the NF MBR were three, four and two times as high as those in the MF MBR, respectively. The specific oxygen uptake rate of the NF MBR (2.9+/-0.4 mg O(2)g(-1)MLSSh(-1)) was lower than that of the MF MBR (4.3+/-1.1 mg O(2)g(-1)MLSS h(-1)). Result of extractable extracellular polymeric substances showed that the NF MBR sludge had more protein and less polysaccharide compared to the MF MBR sludge, whereas specific amount of total organic carbon were the same in both MBRs. The median floc diameters of the NF MBR and the MF MBR were 72+/-12 microm and 59+/-12 microm, respectively, which could be attributable to the different polysaccharide concentrations between both MBR mixed liquor. A higher concentration of materials (DOC, T-P and salt) in the bioreactor, determined by the high rejection rate of the NF membrane, did not significantly affect the microbial diversity under similar operation conditions.     

Bioleaching of heavy metals from anaerobically digested sewage sludge using FeS2 as an energy source

The effect of using FeS2 as an energy source, on the bioleaching of heavy metals (Zn, Cr, Cu, Pb and Ni) and nutrients (nitrogen and phosphorus) from anaerobically digested sludge using isolated indigenous iron-oxidizing bacteria was investigated in this paper. Addition of FeS2 in the range of 0.5-4.0 g l(-1) accelerated the acidification of sludge and raised the oxidation-reduction potential of sludge medium with an inoculation of 15% (v/v) of active bacteria, thus resulting in an overall increase in metal dissolution efficiency. After 16 days of bioleaching at 28 degrees C and an initial pH of 3.0, up to 99% of Zn, 65% of Cr, 74% of Cu, 58% of Pb and 84% of Ni can be removed from the sludge. In contrast, only 94% of Zn, 12% of Cr, 21% of Cu, 32% of Pb and 38% of Ni were leached out in the control without inoculation of iron-oxidizing bacteria and the addition of FeS2. Less than 15% of nitrogen and 6% of phosphorous were lost after 16 days of bioleaching when using FeS2 as the energy source. Comparing to 39% and 45% loss respectively for these two nutrients when using FeSO4.7H2O as the energy source, FeS2 appears to be a more suitable energy source for preserving nutrients in sludge while removing heavy metals from sludge.