废水处理中的可溶性微生物产物*

可溶性微生物产物(SMP)是污水生物处理中有机物质的主要成分,对出水水质有着重要影响。对污水生物处理中SMP的产生、分子质量分布、生物可降解性、毒性、离子螯合性、吸附性等进行了综述,分析了影响SMP产生的因子。分析表明,SRT、HRT、进水浓度、基质性质、有毒物质的存在以及温度都会对SMP的产生及浓度产生影响,控制系统运行的这些参数,可使出水中SMP量降到最少,从而提高出水质量。     

微生物代谢产物在心血管疾病中的应用

心血管疾病严重威胁着人类健康,研发防治心血管疾病的有效药物一直是广大研究者研究的焦点。微生物的多种代谢产物在预防和治疗心血管疾病方面得到广泛应用,从微生物代谢产物中寻找预防和治疗心血管疾病的药物是比较传统而且简单的方法,文章就微生物代谢产物在心血管疾病方面的应用进行了阐述。     

微生物絮凝剂在养殖废水处理中的应用

微生物絮凝剂作为一种新型的絮凝剂,因其安全、高效等特性,正逐渐成为目前水产养殖废水处理研究的热点。主要从微生物絮凝剂的概念、絮凝机理、特点、研究现状、应用实例等方面,分析了微生物絮凝剂作为水质改良剂在水产养殖中的应用前景,并就今后的研究趋势作了展望。     

固定化微生物在废水处理中的研究及进展

微生物固定化是一种比一般生物处理法更为优越的方法,它具有处理效率高、稳定性强、耐负荷、产污泥量少等优点。作者对固定化技术方法以及不同载体的选择进行了介绍和对比,分析评价了国内外微生物固定化在废水控制中最新研究进展,并对其发展问题做了探讨。     

改性微生物吸附剂在重金属废水处理中的应用进展

高效、低耗、环境友好的重金属废水处理方法是当前的研究热点之一,微生物吸附法因具有优良的吸附性能、不产生二次污染、环境友好性等优点,在重金属废水处理中有巨大的应用潜力。细菌、真菌、藻类等微生物可通过静电吸附、络合作用等将重金属结合到细胞壁表面。但未经处理的微生物往往吸附效果不佳,通过对微生物进行物理、化学等方法的改性处理,能显著增加微生物与重金属离子结合的活性位点,提高去除效果。本文对国内外微生物的改性方法以及改性微生物吸附剂对废水中重金属的吸附能力和影响因素进行阐述,讨论微生物吸附剂存在的相关问题,并对其未来的研究方向做简要展望。     

微生物代谢产物库研究进展

微生物代谢物具有极大的化学结构多样性和复杂性,建立微生物代谢物库对发现新药有重要意义。对几种重要的微生物代谢物库及建库方法作一综述。     

含油污泥微生物处理技术研究

针对胜利油田现河采油厂和滨南采油厂联合站罐底污泥的含油污泥进行了微生物处理技术研究工作。主要是利用微生物分离含油污泥的油、泥和降解污泥中的污染物的性能,达到油泥分离和污染物降解的目的。经过了微生物的分离、筛选和诱导培养,选育到了合适的菌株,利用该菌株对含油污泥经厌氧处理后再进行好氧脱油实验,对污泥中脱出原油进行回收。结果表明：所选菌株可以使含油23000mg/kg的含油污泥在4h内脱油到。10100mg/kg,脱油率达到53．4％;微生物降解实验中,随着时间的延长,油去除率越高,降解效果越明显,当处理时间为60d处理后的污泥达到排放标准。     

固定化微生物细胞技术在废水处理中的应用

近十几年来,随着我国经济的快速发展,也给环境带来较大程度的污染,尤其是污水,严重影响水资源的质量。文章主要针对固定化微生物细胞技术处理废水的基本原理、应用做简要的阐述。     

固定化微生物细胞技术在废水处理中的应用*

固定化微生物细胞技术是一门新兴的生物技术,中较为全面地介绍了其定义、分类及载体选择。该技术用于处理高浓度有机废水,含氨氮、难降解、重金属废水非常有效,在废水处理领域有着广阔的应用前景。     

微生物絮凝剂及其在污水处理中的应用

微生物絮凝剂是一种具有广泛应用前景的天然高分子絮凝剂 ,因其安全、高效、无二次污染等优点受到人们的广泛关注 ,已应用于污水处理、食品和发酵工业等。综述了微生物絮凝剂的主要组成、特点、絮凝机理及应用现状。     

Muskegon Wastewater Land Treatment System: Fate and Transport of Phosphorus in Soils and Life Expectancy of the System

The build‐up of phosphorus (P) in soil is a major factor limiting the operating life of a wastewater land treatment system. In this study, effects of long‐term wastewater application on changes in chemical properties, P profiles, and P adsorption capacity were evaluated in soils of the Muskegon wastewater land treatment plant that has been treating wastewater for > 30 years. Results indicate that the major soil properties have been changed. In the 15 cm topsoil, the pH increased from ～ 5–6 in 1973 to ～ 7.4–7.8 in 2003; the soil's total organic carbon (TOC) increased by 10–71 %; and the level of exchangeable Ca in 2003 is 8–9 times higher than that in 1973. The amount of Ca/Mg absorbed in the soil affects the P adsorption capability of the soil; Ca‐ and Mg‐bound P accounts for > 70 % of the total P adsorbed in the soil. The net P accumulated in the Rubicon soil increased from ～ 700 in 1993 to ～ 1345 kg/ha soil in 2001, but the plant available P varied between ～ 100–500 kg/ha soil during the same period, indicating a large amount of the applied P has become the fixed P that is unavailable to plants. P sorption in the soil consists of a fast adsorption and a slow transformation process. The soil's maximum P sorption capacity (P_max) (based on 1‐day isotherm tests) has been increased by ～ 2–4 times since 1973; the actual P_max of the Muskegon soils could be much higher than the 1‐day P_max. Therefore, the life expectancy of the Muskegon system has been extended significantly with the application of wastewater.     

酵母菌在废水处理中的应用现状和进展

酵母菌作为一种极为宝贵的微生物资源,由于它具有良好的耐酸、耐渗透压等特点,因此它广泛被应用于高浓度有机废水的处理,包括有毒、含难降解污染物废水的处理,其处理能力优于驯化后的活性污泥系统,同时具有吸附重金属的作用;酵母菌能将大部分有机物转化成无毒且营养丰富的细胞蛋白供人类利用。随着酵母菌研究的深入和其他相关水处理技术的开发,酵母菌在废水处理中将得到更多、更好、更深的应用,实现环境、社会和经济等可持续发展。     

Characterization of Microbial Communities and Composition in Constructed Dairy Wetland Wastewater Effluent

Constructed wetlands have been recognized as a removal treatment option for high concentrations of contaminants in agricultural waste before land application. The goal of this study was to characterize microbial composition in two constructed wetlands designed to remove contaminants from dairy washwater. Water samples were collected weekly for 11 months from two wetlands to determine the efficiency of the treatment system in removal of chemical contaminants and total and fecal coliforms. The reduction by the treatment was greatest for biological oxygen demand, suspended solids, chemical oxygen demand, nitrate, and coliforms. There was only moderate removal of total nitrogen and phosphorus. Changes in the total bacterial community and ammonia-oxidizing bacterial composition were examined by using denaturing gradient gel electrophoresis (DGGE) and sequencing of PCR-amplified fragments of the gene carrying the α subunit of the ammonia monooxygenase gene (amoA) recovered from soil samples and DGGE bands. DGGE analysis of wetlands and manure samples revealed that the total bacterial community composition was dominated by bacteria from phylogenetic clusters related to Bacillus, Clostridium, Mycoplasma, Eubacterium, and Proteobacteria originally retrieved from the gastrointestinal tracts of mammals. The population of ammonia-oxidizing bacteria showed a higher percentage of Nitrosospira-like sequences from the wetland samples, while a higher percentage of Nitrosomonas-like sequences from manure, feces, raw washwater, and facultative pond was found. These results show that the wetland system is a natural process dependent upon the development of healthy microbial communities for optimal wastewater treatment.     

2株耐低温微生物处理污水模拟试验初报

从下水管道的污泥中分离筛选到耐冷细菌H6和耐冷酵母菌J1,采用此2菌株进行模拟污水低温(8℃)处理试验。H6和J1菌株对模拟污水COD的去除率分别为66.6%和72.2%;H6、J1菌株对有机氮去除率分别为76.9%和64.5%;H6、J1菌株对总磷去除率分别为53.9%和14.0%。说明低温微生物在低温环境的污水处理具有广阔的应用前景。     

Effluent application to the land: Changes in soil properties and treatment potential

Four pilot land treatment systems (LTS) planted with different plant species were investigated as a means of managing wastewater in small communities. The effects of effluent application on soil properties during three years of operation are presented. LTS were planted with Eucalyptus camaldulensis, Acacia cyanophylla, Populus nigra and Arundo donax. Wastewater was pre-treated in a septic tank and applied to LTS at suitable rates to meet crop water requirements. Effluent application was found to increase soil organic matter, P and TKN content, particularly, in the topsoil but plant species had no effect on these parameters. Increases were also observed for salinity and sodium adsorption ratio which were found to depend on hydraulic loading. Winter precipitation leached the majority of the salts accumulated during the application period. Nitrates accumulated in the soil profile throughout the application period and this increase was dependent on plant species. LTS planted with A. donax showed the lowest NO₃-N concentration in soil pore water, an effect which cannot be explained by differences in application rates or plant uptake. This may imply stimulated denitrification rates induced by the rhizosphere of reeds. Effluent application also increased total and macro porosity compared to their initial values and bulk density.     

New Aspects of Microbial Nitrogen Transformations in the Context of Wastewater Treatment – A Review

Over the past few years, new technologies for nitrogen removal have been developed mainly because of the increasing financial costs of the traditional wastewater treatment technologies. Newly discovered pathways, like the anaerobic oxidation of ammonium (ANAMMOX), and uses for nitrogen removal technologies are under discussion. Processes and technologies such as: Partial nitrification; Single reactor systems for High Ammonium Removal Over Nitrite (SHARON); Anammox; Aerobic/anoxic deammonification; Oxygen Limited Autotrophic Nitrification‐Denitrification (OLAND); Completely Autotrophic Nitrogen Removal Over Nitrite (CANON); wetland based systems, all have a high potential for nitrogen removal. However, the pathways of nitrogen transformation processes are very complex. An understanding of how various environmental factors affect these processes and a sound knowledge of existing, worldwide experience pertaining to these novel technologies are the key if the nitrogen removal rates are to be improved and success is to be realized in full‐scale applications. This review describes the present knowledge of the new treatment technologies for wastewater with high nitrogen loads. Special emphasis is given to the influence of environmental factors and the reactor configuration on the nitrogen transformation process and microbial activity.     

Influence of Nitrate and Sulfate on the Anaerobic Treatment of Pharmaceutical Wastewater

Anaerobic treatment of wastewater from the pharmaceutical industry, which contained about 3.2 g/L of sulfate, was carried out in an Upflow Anaerobic Sludge Blanket (UASB) reactor. After a startup period of 120 days, a chemical oxygen demand (COD) removal efficiency of more than 90 % was obtained along with an organic loading rate (OLR) of 1.5 g COD/(L day). During the same period, the sulfate removal was about 90 %. However, the performance of the reactor was affected when the loading rate was increased to 2.09 g COD/(L day). It was found that the accumulation of sulfides, combined with a decrease in the pH, affected the reactor performance. In batch reactor studies with pharmaceutical wastewater it was observed that methane production began only after the initiation of nitrate consumption. The denitrification process can inhibit sulfate reduction at high nitrate concentrations, but compared to reactors without nitrate, the sulfate reduction process and sulfide formation were quickly initiated at low nitrate concentrations. The methanogenic activity was however affected by the presence of more than 2 g/L of sulfate.     

Modeling of an Aerobic Membrane Bioreactor for Wastewater Treatment

The goal of this work is to develop a mathematical model to describe a continuous aerobic membrane bioreactor (MBR) for the treatment of different kinds of wastewater. Firstly, the experimental setup and the materials and methods to obtain data for the model verification are described. Secondly, a black box model is developed and verified for size containing wastewater. The model calculates output streams and concentrations from input streams and compositions using distribution coefficients. These coefficients are derived from experimental data. In a third step, two shortcut models of different complexity are developed. Both shortcut models use the black box balancing as a basis. However, the component balances for carbon and oxygen are no longer modeled by constant distribution coefficients. The basic shortcut model introduces Monod kinetics to modify the carbon balance. The enhanced shortcut model introduces transport laws for dissolved oxygen supply and combines the Monod kinetics with an additional term for oxygen limitation to model biological growth. The models show an increasing degree of agreement.     

New Process to Minimize Effluent Water in the Production of DNT

Until recently, freshwater had to be used for “neutral washing” in the DNT production. Using the new process outlined in this communication, it is now possible to recycle process condensate from the concentration of sulfuric acid. No additional freshwater is needed and the effluent water stream to be treated is also correspondingly reduced. MNT and DNT are recovered and recycled to the production process. Losses are minimized.