HRT对一体式PTFE膜生物反应器运行效果的影响

针对垃圾渗滤液高COD、高NH4-N,低生化性的特点,开发UASB/缺氧/好氧-膜生物反应器组合处理工艺.在不同水力停留时间(HRT)下,考察了系统对污染物去除效果及其膜污染特性.结果表明,在不同的HRT条件下,UASB/缺氧/好氧-膜生物反应器组合工艺处理垃圾渗滤液出水水质良好且稳定.出水COD除率随HRT的升高先增加后降低,且HRT为12.8h时达到最大值94.96%;系统对NH4-N的平均去除率随HRT的延长而升高; 膜污染实验结果显示: 较低的HRT条件下意味着膜通量较高,会加剧膜污染进程.通过实验得出结论当HRT=15h时,对膜污染的控制最为有利.对膜进行清洗,并进行扫描电镜分析.分析结果显示凝胶层的形成是膜透水性下降的主要原因.     

Microbial nitrogen transformation potential in surface run-off leachate from a tropical landfill

Ammonium is one of the major toxic compounds and a critical long-term pollutant in landfill leachate. Leachate from the Jatibarang landfill in Semarang, Indonesia, contains ammonium in concentrations ranging from 376 to 929 mg N L⁻¹. The objective of this study was to determine seasonal variation in the potential for organic nitrogen ammonification, aerobic nitrification, anaerobic nitrate reduction and anaerobic ammonium oxidation (anammox) at this landfilling site. Seasonal samples from leachate collection treatment ponds were used as an inoculum to feed synthetic media to determine potential rates of nitrogen transformations. Aerobic ammonium oxidation potential (<0.06 mg N L⁻¹ h⁻¹) was more than a hundred times lower than the anaerobic nitrogen transformation processes and organic nitrogen ammonification, which were of the same order of magnitude. Anaerobic nitrate oxidation did not proceed beyond nitrite; isolates grown with nitrate as electron acceptor did not degrade nitrite further. Effects of season were only observed for aerobic nitrification and anammox, and were relatively minor: rates were up to three times higher in the dry season. To completely remove the excess ammonium from the leachate, we propose a two-stage treatment system to be implemented. Aeration in the first leachate pond would strongly contribute to aerobic ammonium oxidation to nitrate by providing the currently missing oxygen in the anaerobic leachate and allowing for the growth of ammonium oxidisers. In the second pond the remaining ammonium and produced nitrate can be converted by a combination of nitrate reduction to nitrite and anammox. Such optimization of microbial nitrogen transformations can contribute to alleviating the ammonium discharge to surface water draining the landfill.     

Removal of nitrogen and phosphorus by eight strains of microalgae and their growth characteristics in Penaeus vannamei sewage北大核心CSCD

Microalgae are the most important primary productive forces in shrimp aquaculture systems. Microalgae not only provide oxygen and natural food for aquaculture objects, but they also absorb nitrogen (N) and phosphorus (P) to reduce water eutrophication. However, there are great differences in N and P absorption among different strains of microalgae. To maintain the sustainable development of shrimp aquaculture, the growth performances of eight microalgal strains in Penaeus vannamei sewage and N and P removal rates were investigated under laboratory conditions. The results indicated that the eight microalgal strains could reduce the N and P content in P. vannamei sewage to some extent. Microcystis aeruginosa, Chlamydomonas sp., and Chlorella pyrenoidosa grew very well, with average growth rates of 0.309 3, 0.246 9, and 0.215 5, respectively. There were significant differences in the removal efficiency among the different strains. The removal rates of total N by M. aeruginosa, Chlamydomonas sp., and C. pyrenoidosa were 74%, 69%, and 60%, respectively, at the end of the experiment, which were higher than the other species. M. aeruginosa and Chlamydomonas sp. had better total P removal efficiency than those of the other microalgal strains and removal rates were greater than 60%, and the second highest total P removal efficiency was by C. pyrenoidosa. Different types of microalgal strains had different absorption rates of different morphological nitrogen. M. aeruginosa and Chlamydomonas sp. had the highest nitrate nitrogen removal rate (approximately 70%). Chlamydomonas sp. had a fast and persistent removal rate of ammonia nitrogen, with the removal rate being as high as 100%. The removal efficiency of M. aeruginosa and C. pyrenoidosa were a little slower, and those of Scenedesmus obliquus, Synedra sp., and Navicula graciloides were the slowest. After 16 d, the removal rate reached more than 90%. Cryptomonas obovate and C. pyrenoidosa displayed the best removal rate of nitrite nitrogen, and the removal rate reached 80% on day 8, and the removal rate of C. obovata was more persistent. These results can provide scientific reference for the orientation and use of microalgae to remove pollutants in tailings water from shrimp aquaculture systems. © 2018 Science Press. All rights reserved.     

白洋淀芦苇型水陆交错带水化学动态及其净化功能研究

于2007年3月-11月对富营养化湖泊一白洋淀进行了现场调查,分析了温度、溶解氧（DO）、叶绿素、总磷（TP）及其他水化学指标的动态变化规律,并讨论了它们之间的相互关系。结果表明：白洋淀芦苇（Phragmites australis var．baiyangdiansis）型水陆交错带对营养物质具有强烈的截留作用,可以达到净化白洋淀水体的效果。从水质指标的空间分布看,污染较重的府河河口区域其水体TP、化学需氧量（CODc,）含量明显高于污染较轻的湖泊中心区域,空间梯度上呈逐步递减趋势。根据水体盐度、总溶解性固体、TP及DO含量进行聚类分析,可以将采样点分为3类：Ⅰ区、污染较重河口区域;Ⅱ区、中间过渡缓冲区域;Ⅲ区、污染较轻中心区域。Ⅰ区其水体DO含量明显低于Ⅲ区,而水体盐度则明显高于Ⅲ区。通过调查发现：在8月份,白洋淀水体DO含量突然增加;相关分析表明：叶绿素含量与DO（P=0．046）及温度（P〈0．01）之间呈显著正相关关系。结合叶绿素等指标的动态变化规律,8月份左右可能是白洋淀藻类爆发的危险时期。     

梯级河滩湿地模型对受污染河水氮磷和CODCr的净化效果

在贾鲁河畔构建3组并联的梯级河滩湿地模型,引种9种不同类型的湿地植物进行筛选试验,将湿地模型串联运行比较研究3种不同植物配置的梯级湿地对受污染河水的净化效果,在此基础上设定12h和24h等两组不同水力滞留时间,研究延长滞留时间对水质净化效果的影响。试验结果表明：对氮磷和有机物的去除效果挺水植物明显好于沉水植物,其中茭草（Zizania caduciflora）、荆三棱（Scirpus fluviatilis）和狭叶香蒲（Typha angustifolia）去除效果最好;沉水植物和挺水植物对氨氮的去除表现好于浮叶植物;延长水力滞留时间对改善水质净化效果明显,滞留时间由12h延长到24h后,TN、TP、氨氮和CODCr去除率分别提高10.2%、21.7%、30.2%和12.9%,对氨氮的净化效果改善最为明显;挺水植物＋沉水植物＋浮叶植物组合较单纯挺水植物组合在对氨氮和TN去除效果方面表现出较明显的优势,主要是由于不同类型湿地植物所营造的好氧、厌氧环境提高了对氨氮和TN去除效果。研究结果证明在湿地植被组建中,根据进水水质,应灵活选择植物种类,进行合理的植物配置,可提高湿地的净化效果。     

敞口地炉内燃烧煤泥饼时氟的逸出规律及控制

利用特制精确控温敞口炉,模拟重病区居民燃烧煤泥饼时氟的排放及控制,分析了停留时间、燃烧温度对氟排放的影响,探讨了CaCO₃添加量及燃烧温度与固氟率的关系.结果表明:随着煤泥饼在炉内停留时间的延长,氟的逸出率逐渐增大,1 h后氟的排放达到平衡;氟逸出率随温度升高而增加,900 ℃时逸出率平均为80%,与病区实际燃烧排氟量相吻合;煤泥饼中添加CaCO₃能有效控制燃烧氟排放,固氟率随CaCO₃添加量的增加而增大,w(CaCO₃)为10%时达到最佳固氟效果;500～800 ℃内固氟率随温度升高而增加,800 ℃时固氟率最高,平均为44.2%,温度继续升高则固氟率下降,900 ℃时为25.0%.      

流速对河道系统截留氮、磷的影响

为有效阻控太湖湖西地区小流域河流中的氮、磷进入太湖,对比了不同流速下河道对河流上覆水和间隙水中NH₄＋-N,NO₃－-N,NO₂－-N和可溶磷的截留情况,同时通过实验室模拟河道探讨了不同流速下氮、磷截留的机理. 结果表明,河道系统本身不太稳定,在有外界条件(如其他河流的汇入)作用下可以引起一系列的变化. 流速对河道中NH₄＋-N,NO₃－-N,NO₂－-N和可溶磷的截留有较大影响,在保证初始条件和外部条件相同的前提下,快速流(流速为1.00 cm/min)对氮、磷的截留量最小,中速流(流速为0.35 cm/min)次之,慢速流(流速为0.17 cm/min)对氮、磷的截留量最大. 在整个过程中流速对氮的截留基本上是先增加再略有下降,而对磷的截留是先增加再逐渐趋于平稳.      

Basic principles and ecological consequences of changing water regimes on nitrogen cycling in fluvial systems

Understanding the environmental consequences of changing water regimes is a daunting challenge for both resource managers and ecologists. Balancing human demands for fresh water with the needs of the environment for water in appropriate amounts and at the appropriate times are shaping the ways by which this natural resource will be used in the future. Based on past decisions that have rendered many freshwater resources unsuitable for use, we argue that river systems have a fundamental need for appropriate amounts and timing of water to maintain their biophysical integrity. Biophysical integrity is fundamental for the formulation of future sustainable management strategies. This article addresses three basic ecological principles driving the biogeochemical cycle of nitrogen in river systems. These are (1) how the mode of nitrogen delivery affects river ecosystem functioning, (2) how increasing contact between water and soil or sediment increases nitrogen retention and processing, and (3) the role of floods and droughts as important natural events that strongly influence pathways of nitrogen cycling in fluvial systems. New challenges related to the cumulative impact of water regime change, the scale of appraisal of these impacts, and the determination of the impacts due to natural and human changes are discussed. It is suggested that cost of long-term and long-distance cumulative impacts of hydrological changes should be evaluated against short-term economic benefits to determine the real environmental costs.     

Cost-effective nutrient reductions to coupled heterogeneous marine water basins: An application to the Baltic Sea

In this paper, the role of nutrient transports between marine basins is investigated for cost-effective solutions to predetermined marine basin targets. The interdependent advective nutrient transports as well as retentions among the seven major marine basins of the Baltic Sea are described by input-output analysis. This is in contrast to prior economic studies of transboundary water pollution that include only direct transport between the basins. The analytical results show that the difference in impacts between transport specifications depends mainly on the openness of the basins, that is, their transports with other basins. The application on Baltic Sea shows significant differences in costs and policy design between the nutrient transport specifications. The reason is that the Sea is characterized by long water and nutrient residence times, so relatively large part of nutrients are transported among basins.     

Nutrient fluxes in a eutrophic coastal Louisiana freshwater lake

Nitrogen and phosphorus cycling in a eutrophic Louisiana freshwater lake system (Lac des Allemands) was studied. Nutrients from runoff entering the lake, as well as sediment-interstitial and lake water nitrogen and phosphorus fractions, were measured seasonally. Sedimentation rates in the lake were determined using¹³⁷Cs dating.Phosphorus levels in the lake were found to be largely dependent on concentrations in the incoming bayou water from upland drainage. Lake water concentrations appear to respond to fluctuations in incoming waters. Laboratory equilibrium studies showed bottom sediments in the lake are a major sink for the incoming dissolved orthophosphate phosphorus. Total nitrogen concentrations in the lake water generally exceeded incoming runoff concentrations, suggesting fixation by the large blue-green algae population in the lake as being the major source of nitrogen to the system.Sedimentation ranged from 0.44 cm/year to 0.81 cm/year, depending on the proximity to the inlet bayous. Even though the lake is eutrophic the sediment served as a buffer by removing large amounts of carbon, nitrogen, and phosphorus through sedimentation processes. Carbon, nitrogen, and phosphorus were accumulating in the sediment at rates of 60, 7.1, and 1.1 g/m²/year, respectively.The water quality of the lake is likely to continue to decline unless measures are taken to reduce municipal, industrial, and agricultural inputs of phosphorus into the lake.