生物强化技术提高SBR系统对低温苯胺废水处理能力的研究

为了考察高效菌株生物强化效能,解决低温条件下含苯胺废水处理效果差的问题.选择实验室筛选的高效低温苯胺降解菌JH-9为研究对象,考察了其苯胺降解能力和絮凝特性,并采用生物强化的方法将其投加到SBR反应系统中,考察其对提高系统低温条件下(12℃)含苯胺废水的处理能力的改善.结果表明:JH-9细菌在初始苯胺浓度为250 ms/L的培养液中培养52 h,去除率可达100%,其对石化废水中的其他污染物也有一定的降解能力,并且具有产絮能力.将其应用于SBR的强化系统对提高系统低温条件下(12℃)对苯胺去除效果很有效,针对含有苯胺174 mg/L的石化废水,强化系统对苯胺的去除率达到97.8%.除此以外该菌对系统TOC的去除、污泥的MLSS、MLVSS、SV等指标均有一定改善,利于保证系统快速启动和稳定运行.     

厌氧膜生物反应器处理抗生素废水研究进展与展望

中国是抗生素生产大国,抗生素生产过程伴随产生大量的含抗生素残留的有机废水,通常采用厌氧生物技术进行处理。然而传统的厌氧处理技术对抗生素废水存在效能不高的问题,并且难以实现废水中常规污染物、抗生素与耐药基因的协同控制。厌氧膜生物反应器同时具有厌氧处理与膜处理技术的优点,在处理抗生素废水方面展现出很好的应用前景。本文总结了厌氧膜生物反应器处理抗生素废水的研究进展,从常规污染物去除和耐药基因削减两方面阐述了厌氧膜生物反应器的处理优势;重点梳理了抗生素对厌氧膜生物反应处理过程中生物效能的抑制和耐药基因赋存的影响。在此基础上,提出“强化水解预处理去除抗生素残留效价(抑菌活性)-厌氧膜生物反应器”组合处理工艺作为短流程的抗生素废水处理最佳策略,在提升污水处理效能的同时实现对耐药性的协同控制,为制药废水绿色、高效和安全处理提供参考。     

生物活性炭法深度处理印染废水及其生物毒性的表征

采用负载经驯化后微生物的活性炭深度处理实际印染废水,研究生物活性炭系统中存在的生物相及其降解有机污染物的作用,并表征了处理后印染废水的生物毒性.结果表明,生物相中含有草履虫、轮虫及钟虫等原生动物.随着运行次数的增加,活性炭反应器在运行5次后出水的COD、NH3-N及色度去除率骤降,但是生物活性炭处理后出水的COD、NH3-N及色度去除率缓慢下降.生物活性炭能很好地降解印染废水中的苯酚类和稠环芳烃污染物.本研究中生物活性炭反应器对氨氮和COD的去除符合一级动力学方程,去除动力学常数分别为1.02和0.96.经过生物活性炭的处理可以将印染废水的生物毒性降到适于小球藻生长的水平.     

电-生物耦合技术对偶氮染料的去除研究

酸性大红GR是一种较难生物降解的偶氮染料,采用一种电场和生物耦合的新型技术处理酸性大红GR模拟废水,并与单纯电化学法和好氧生物法进行试验对照。结果表明：反应6 h后,电化学法、好氧生物法、电-生物耦合技术对酸性大红GR的去除率分别达到15.7%、25.8%和71.2%,电-生物耦合技术能明显提高酸性大红GR的去除效果,起到强化生物处理的作用。在15 mA微电流条件下电-生物技术能克服50 mg/L酸性大红GR对好氧生物处理的抑制作用,为高浓度难降解染料废水的生物强化处理提供了可能。     

印染废水生物强化处理技术研究进展

印染废水是国内外公认的难处理的工业废水之一 ,活性污泥法是目前最常用的处理方法 ,但还存在诸多问题。在分析中 ,主要从生物强化技术、固定化微生物技术和微生物活性增加技术等方面 ,总结了废水生物处理技术强化研究进展 ,并讨论了今后的研究方向。     

微生物选育技术在废水生物处理中的应用进展

通过对微生物特别是细菌进行筛选和培育 ,可以得到降解能力强的高效菌株 ,将这些菌株应用于废水生物处理 ,能够增强废水处理工艺去除难降解有机污染物及削减其毒性的能力 ,本文对此进行了评述与展望。     

微生物选育技术在废水生物处理中的应用进展

通过对微生物特别是细菌进行筛选和培育,可以得到降解能力强的高效菌株,将这些菌株应用于废水生物处理,能够增强废水处理工艺去除难降解有机污染物及削减其毒性的能力,本文对此进行了评述的展望。     

印染废水生物强化处理技术研究进展

印染废水是国内外公认的难处理的工业废水之一，活性污泥法是目前最常用的处理方法，但还存在诸多问题。在分析中，主要从生物强化技术、固定化微生物技术和微生物活性增加技术等方面，总结了废水生物处理技术强化研究进展，并讨论了今后的研究方向。     

制药废水中抗生素的去除技术研究进展

发酵类抗生素生产废水中残留抗生素及相关物质(残留效价)含量高,对废水生物处理系统微生物群落结构以及废水处理效果影响显著,同时会导致生物处理细菌耐药基因的产生和排放;因此,如何去除废水中残留抗生素及效价是解决抗生素废水处理难题的关键。在前期研究的基础上,提出高浓度抗生素生产废水残留抗生素效价的水处理控制目标,概述了水中抗生素去除的生物和物化技术的最新研究进展,提出了在废水生物处理之前进行抗生素选择性去除的强化催化水解预处理技术方案,结合生物处理之后采用高级氧化技术保障该类废水安全排放,并对未来该类废水处理技术的发展方向提出了建议,以期为行业的可持续发展提供技术支持和科学依据。     

煤气废水中有机化合物的生物去除特征

好氧/缺氧/好氧生物处理系统是一种新型煤气废水二级处理工艺,该工艺通过改变微生物的生化环境,充分发挥各单元对有机化合物的降解功能,强化了有机化合物总体去除效果.主要采用气相色谱/质谱联用(GC/MS)测试方法,分析对比煤气废水进水及其系统各单元出水中有机化合物的成分,结合生物降解的特点,评价各单元对有机化合物的去除效果...     

混合型污水处理厂原位生物强化脱氮中试及微生物群落结构分析研究

针对混合型污水处理厂进水水质波动大、C/N低、总氮稳定达标困难等共性问题,开发出适宜于低C/N、贫营养等苛刻环境条件的高效脱氮菌剂.现场中试结果表明:经过脱氮菌强化后,生化系统脱氮效率提升8.5百分点,出水平均总氮较强化前下降3 mg/L,出水水质稳定性明显提升,生物强化效果显著.在不补加碳源条件下,深度处理出水总氮完...     

Bioaugmentation of a 4-chloronitrobenzene contaminated soil with Pseudomonas putida ZWL73

The strain Pseudomonas putida ZWL73, which metabolizes 4-chloronitrobenzene (4CNB) by a partial-reductive pathway, was inoculated into lab-scale 4CNB-contaminated soil for bioaugmentation purposes in this study. The degradation of 4CNB was clearly stimulated, as indicated with the gradual accumulation of ammonium and chloride. Simultaneously, the diversity and quantity of cultivable heterotrophic bacteria decreased due to 4CNB contamination, while the quantity of 4CNB-resistant bacteria increased. During the bioaugmentation, denaturing gradient gel electrophoresis analysis showed the changes of diversity in dominant populations of intrinsic soil microbiota. The results showed that Alphaproteobacteria and Betaproteobacteria were not distinctly affected, but Actinobacteria were apparently stimulated. In addition, an interesting dynamic within Acidobacteria was observed, as well as an influence on ammonia-oxidizing bacteria population. These combined findings demonstrate that the removal of 4CNB in soils by inoculating strain ZWL73 is feasible, and that specific populations in soils rapidly changed in response to 4CNB contamination and subsequent bioaugmentation.     

抗生素废水碱回收与生化处理试验研究

为克服抗生素废水难以生化处理的难题,采用废碱液回收利用和生物强化处理的技术手段对废水进行了资源化小试研究。结果显示,经碱液回收后出水的COD、SS、硫酸盐和含盐量分别由13 925、45 700、417和29 900 mg/L降到了2 400、86、25和402 mg/L,色度也由6 000倍降到了5倍;经与综合污水混合后生化强化处理,出水COD、色度和硫酸盐的平均去除率分别达到了91%、84%和96.5%,处理效果理想,资源化技术处理废水可盈利54.19元/t,具有较好的经济性,值得推广应用。     

Impact of Bioaugmentation with a Consortium of Bacteria on the Remediation of Wastewater-Containing Hydrocarbons (5 pp)

Goals, Scope and Background It has been observed that hydrocarbon treated wastewaters still contain high COD and a number of intermediates. This suggests that the required catabolic gene pool for further degradation might be absent in the system or, that its titer value is not significant enough. By providing the desired catabolic potential, the overall efficiency of the treatment system can be improved. This study aims to demonstrate this concept by bioaugmentation of a lab-scale reactor treating refinery wastewater with a consortium having the capacity to complement the alkB genotype to the available microbial population. Methods Two reactors were set up using activated biomass collected from a refinery treatment plant and operated at a continuous mode for a period of 8 weeks. The feed to both reactors was kept constant. Crude oil was spiked regularly. One reactor was bioaugmented with a consortium previously described for crude oil spill remediation. The efficiency of the bioaugmented reactor was demonstrated by reduced COD. The changes in the microbial population over a period of time were analyzed by RAPD. Catabolic activity of the biomass in both reactors was monitored by PCR. The presence of the catabolic loci was confirmed by Southern Hybridization. Results and Discussion 52.2% removal of COD was observed in the bioaugmented reactor while only 15.1% reduction of COD was observed in the reactor without bioaugmentation. The change in microbial population can be seen from the 4th week, which also corresponds to improved catabolic activity. The presence of the bedA locus was seen in all samples, which indicates the presence of aromatic degraders, but the appearance of the alkB locus, from the 6th week onwards, which was observed only in the samples from the bioaugmented reactor. The results suggest that the gene pool of the bioaugmented reactor has catabolic loci that can degrade accumulated intermediates, thus improving the efficiency of the system. Conclusions In this study, improvement of efficiency of bioremediation was demonstrated by addition of catabolic loci that are responsible for degradation. Bioaugmentation was carried out in biomass that was collected from an ETP (effluent treatment plant) treating hydrocarbon containing wastewater to study the strategies for improvement of the treatment system. Biostimulation, only marginally improved the efficiency, when compared to bioaugmentation. The improved efficiency was demonstrated by COD removal. The presence of the alkB locus suggests the importance of a catabolic gene pool that acts on accumulated intermediates. It is well documented that straight chain aliphatics and intermediates of aromatic compounds after ring cleavage, accumulate in refinery wastewater systems, thereby hindering further degradation of the wastewater. Supplementation of a catabolic gene pool that treats the lower pathway compounds and alkanes will improve the overall efficiency. In this study, results suggest that the alkB locus can also be used to monitor the degradative mode of the activated biomass. Recommendations and Perspective . Pollution from petroleum and petroleum products around the globe are known to have grave consequences on the environment. Bioremediation, using activated sludge, is one option for the treatment of such wastes. Effluent treatment plants are usually unable to completely degrade the wastewater being treated in the biological unit (the aerator chambers). The efficiency of degradation can be improved by biostimulation and bioaugmentation. This study demonstrates the improved efficiency of a treatment system for wastewater containing hydrocarbons by bioaugmentation of a consortium that supports degradation. Further experiments on a pilot scale are recommended to assess the use of bioaugmentation on a large scale. The use of molecular tools, like DNA probes for alkB, to monitor the system also needs to be explored.     

Enzymatic treatment of sanitary landfill leachate

The objective of this investigation was to study the effectiveness of applying enzymes (bioaugmentation) for enhancement of biological treatability of leachates generated in a typical municipal solid waste sanitary landfill. The basic purpose of enzyme use is to enforce the biodecomposition of organic constituents, as well as to reduce nitrogen content. A laboratory-scale sequencing batch (bio)reactor (SBR) was used for the examination of enzymatic application. The effect of different operation strategies on the efficiency of this biological treatment process was studied to optimize performance, especially for the removal of nitrogen compounds and of biodegradable organic matter. It was found that the enzymatic process was able to remove organic matter effectively (expressed as BOD5 and COD) and nitrogen content, color and turbidity.     

Advances and perspective in bioremediation of polychlorinated biphenyl-contaminated soils

In recent years, microbial degradation and bioremediation approaches of polychlorinated biphenyls (PCBs) have been studied extensively considering their toxicity, carcinogenicity and persistency potential in the environment. In this direction, different catabolic enzymes have been identified and reported for biodegradation of different PCB congeners along with optimization of biological processes. A genome analysis of PCB-degrading bacteria has led in an improved understanding of their metabolic potential and adaptation to stressful conditions. However, many stones in this area are left unturned. For example, the role and diversity of uncultivable microbes in PCB degradation are still not fully understood. Improved knowledge and understanding on this front will open up new avenues for improved bioremediation technologies which will bring economic, environmental and societal benefits. This article highlights on recent advances in bioremediation of PCBs in soil. It is demonstrated that bioremediation is the most effective and innovative technology which includes biostimulation, bioaugmentation, phytoremediation and rhizoremediation and acts as a model solution for pollution abatement. More recently, transgenic plants and genetically modified microorganisms have proved to be revolutionary in the bioremediation of PCBs. Additionally, other important aspects such as pretreatment using chemical/physical agents for enhanced biodegradation are also addressed. Efforts have been made to identify challenges, research gaps and necessary approaches which in future, can be harnessed for successful use of bioremediation under field conditions. Emphases have been given on the quality/efficiency of bioremediation technology and its related cost which determines its ultimate acceptability.     

Bioremediation of a weathered and a recently oil-contaminated soils from Brazil: a comparison study

The facility with which hydrocarbons can be removed from soils varies inversely with aging of soil samples as a result of weathering. Weathering refers to the result of biological, chemical and physical processes that can affect the type of hydrocarbons that remain in a soil. These processes enhance the sorption of hydrophobic organic contaminants (HOCs) to the soil matrix, decreasing the rate and extent of biodegradation. Additionally, pollutant compounds in high concentrations can more easily affect the microbial population of a recently contaminated soil than in a weathered one, leading to inhibition of the biodegradation process. The present work aimed at comparing the biodegradation efficiencies obtained in a recently oil-contaminated soil (spiked one) from Brazil and an weathered one, contaminated for four years, after the application of bioaugmentation and biostimulation techniques. Both soils were contaminated with 5.4% of total petroleum hydrocarbons (TPHs) and the highest biodegradation efficiency (7.4%) was reached for the weathered contaminated soil. It could be concluded that the low biodegradation efficiencies reached for all conditions tested reflect the treatment difficulty of a weathered soil contaminated with a high crude oil concentration. Moreover, both soils (weathered and recently contaminated) submitted to bioaugmentation and biostimulation techniques presented biodegradation efficiencies approximately twice as higher as the ones without the aforementioned treatment (natural attenuation).     

Minimal pesticide-primed soil inoculum density to secure maximum pesticide degradation efficiency in on-farm biopurification systems

Addition of pesticide-primed soil containing adapted pesticide degrading bacteria to the biofilter matrix of on farm biopurification systems (BPS) which treat pesticide contaminated wastewater, has been recommended, in order to ensure rapid establishment of a pesticide degrading microbial community in BPS. However, uncertainties exist about the minimal soil inoculum density needed for successful bioaugmentation of BPS. Therefore, in this study, BPS microcosm experiments were initiated with different linuron primed soil inoculum densities ranging from 0.5 to 50 vol.% and the evolution of the linuron mineralization capacity in the microcosms was monitored during feeding with linuron. Successful establishment of a linuron mineralization community in the BPS microcosms was achieved with all inoculum densities including the 0.5 vol.% density with only minor differences in the time needed to acquire maximum degradation capacity. Moreover, once established, the robustness of the linuron degrading microbial community towards expected stress situations proved to be independent of the initial inoculum density. This study shows that pesticide-primed soil inoculum densities as low as 0.5 vol.% can be used for bioaugmentation of a BPS matrix and further supports the use of BPS for treatment of pesticide-contaminated wastewater at farmyards.     

国内外重金属废水处理新技术的研究进展

有毒重金属对环境的严重威胁正逐渐成为全球性问题，着重综述了近年来国内外重金属污染处理技术的研究与进展。除了改进传统的化学、物理方法外，各种廉价高吸附性能的吸附剂、新型可选择性重金属捕集剂都是研究的焦点。特别是随着生物技术的发展，利用功能菌和植物处理含重金属污染已取得相当成效，并在工业上进行了实际应用。研究和发展新型天然吸附剂、重金属捕集剂和生物技术，加强多种技术的综合应用，是治理重金属污染的有效途径。