O3-BAC深度处理黄浦江污染原水中试研究

对黄浦江原水进行O3 BAC工艺深度处理中试研究表明 :O3 BAC能在较长时间内保持对水中有机物的去除 ,CODMn的平均去除率为 2 7 5% ;TOC的平均去除率为 34 7% ;UV2 54 的平均去除率为 57%。该工艺还能去除水中的锰、色度等 ,能将Ames试验阳性的水转化为Ames试验阴性。     

上向流O3-BAC工艺处理微污染湖泊水研究

以我国华东地区某湖泊水为原水,进行中试规模的上向流臭氧生物活性炭（O3-BAC ）工艺研究,考察该工艺去除水中有机物的能力,以及工艺出水的生物稳定性和化学安全性。研究结果表明：该工艺能有效去除有机物、氨氮和消毒副产物前体物,同时能提高出水的生物稳定性。该工艺出水CODMn 、UV254和DOC的平均值分别为2.31 mg/L、0.034 cm -1和1.76 mg/L ,平均去除率为53.4％、67.3％和65.1％;三卤甲烷,卤乙酸和亚硝胺类副产物生成潜能的平均去除率分别为50.3％,59％和96.6％;AOC平均去除率为54.5％;工艺出水BDOC仅为0.56 mg/L ;且出水未检出BrO3-。因此,O3-BAC工艺适合处理该湖泊水且出水水质安全。     

改性沸石去除水中有机物特性的研究

沸石是多孔的吸附材料，它的吸附性能与被吸附物质的大小有很大的关系。研究改性沸石去除水中有机物的特性，结果表明：当水中投加足量的沸石时，改性沸石同样能去除水中的有机物；改性沸石主要去除大分子量的有机物，对小分子量的有机物去除效果很差；沸石对原水中有机物的去除率比配水实验低；改性沸石对UV254的去除率比对DOC的去除率高。     

炭砂滤池去除有机物特性的研究

通过现场中试,研究活性炭—石英砂双层滤池(简称炭砂滤池)作为快滤池使用时对水中有机物的去除特性。结果表明:炭砂滤池代替普通砂滤池可有效去除水中的有机物,尤其对中低分子质量有机物去除效果较好。炭砂滤池依靠滤料截留、活性炭吸附和生物降解作用去除CODMn。试验期间炭砂滤池对CODMn去除稳定,平均去除率达50%。炭砂滤池主要依靠活性炭吸附去除UV254,稳定情况下对UV254的去除率在40%～50%。炭砂滤池对于有机物有较强的抗冲击负荷能力,滤速、反冲洗以及水力波动对其去除CODMn和UV254影响不大。     

臭氧-生物活性炭控制有机物和消毒副产物研究

南方某水厂采用的臭氧-生物活性炭给水深度处理工艺稳定运行了6年,为了解工艺长期运行过程中在活性炭性能指标下降后,是否还能有效地去除有机物和消毒副产物,开展了试验研究。重点考察臭氧-生物活性炭对水中有机物和氯化消毒副产物的去除效果,通过与常规处理出水水质的对比,探讨其去除有机物和消毒副产物的优势。结果表明,臭氧-生物活性炭是一个长期有效的去除有机物和氯化消毒副产物的控制手段。该工艺对CODMn、TOC、UV254的去除率分别为43.2%、24.0%、58.8%;对THMsFP去除率为40.1%;对三氯甲烷和三氯乙醛的去除率分别达到54.5%和70.7%。在臭氧-生物活性炭组合处理工艺中,活性炭池是去除有机物和消毒副产物的关键工艺。     

纳滤膜对饮用水中可同化有机碳的去除效果

考察了纳滤膜对饮用水中有机物和可同化有机碳(AOC)的去除效果。对纳滤膜进水和出水进行了AOC的相对分子质量分布测定,分析AOC和有机物相对分子质量分布间的关系,探讨纳滤膜去除AOC的机理。结果表明,纳滤膜能有效地去除TOC和UV254,去除率均高达95%以上;在不同季节,自来水中AOC浓度有显著的变化,其中AOCP17约占AOC总量的60%~70%;纳滤膜对饮用水中AOC的去除率约为60%,其去除效果受到筛分效应和电荷效应的双重影响。AOC多与相对分子质量小于1000的有机物有关。     

美国ICR数据库有机物去除分析及对我国的借鉴作用

我国《生活饮用水卫生标准》(GB 5749-2006)对有机物指标的要求,给我国给水处理的运行带来了新的挑战。依照美国第一阶段消毒剂与消毒副产物标准中对有机物指标(TOC)的去除率要求,用美国ICR(Information Collection Rule)数据库分析了常规工艺及增加生物活性炭(BAC)的深度处理工艺对水中有机物的去除。结果表明,常规工艺对有机物的去除效果随原水的TOC增大而变好,随碱度增大而变差;对于水中有机物的去除,常规工艺的去除率中位数为32%,BAC的深度处理工艺中位数为40%。混凝和BAC工艺弥补了各自的不足,尤其是当原水碱度较高TOC较低,在混凝工艺后增加BAC工艺可以更好地去除水中的有机物。     

组合工艺控制有机物及消毒副产物前体物的特性研究

通过XAD-8树脂将水中有机物分成疏水性、亲水性两部分,对传统常规处理工艺(混凝气浮、过滤)和深度处理工艺(臭氧氧化、生物活性炭)出水的DOC,UV254THMFP,HAAFP指标以及疏水、亲水有机物去除率进行了检测分析。结果表明,生物活性炭(BAC)单元工艺能同时去除疏水性和亲水性两种有机物,且两者去除率均为最高。其次去除效果较好的是传统的常规工艺。臭氧工艺具有将天然的疏水性有机物氧化成可生化降解的亲水性小分子有机物的特点,在预臭氧+常规以及O3-BAC组合工艺中,起到了强化去除有机物和消毒副产物前体物的效果。     

氨吹脱-A2/O工艺处理高浓度养殖废水

介绍了氨吹脱-A2/O工艺处理高浓度养殖废水的工程实例.运行结果表明,CODCr的平均去除率为97.4%,NH3-N去除率为91.9%,出水的各项指标均符合<畜禽养殖业污染物排放标准>.该工艺具有剩余污泥少,耐冲击负荷能力强,难降解有机物去除效率高等优点.     

沸石-活性炭组合工艺处理微污染原水的研究

为改善水质 ,研究了沸石与活性炭 (GAC)组合的新工艺。沸石不仅具有去除水中浊度的作用 ,而且还可去除水中氨氮和部分有机物。沸石与活性炭的吸附性能有互补特点 ,沸石 活性炭组合工艺可有效去除污染物。试验结果表明 ,沸石对CODMn的去除率在 10 %左右 ,对浊度、氨氮、三氯甲烷的去除率分别在 6 0 % ,95 %和 4 0 %以上。沸石 活性炭组合工艺对水中苯酚、阴离子洗涤剂(LAS)和三氯甲烷的去除率分别在 6 0 % ,89% ,99%以上     

臭氧活性炭深度处理工艺除藻效能研究

通过中试除藻试验,研究了臭氧活性炭深度处理工艺的除藻效能。结果表明,经过预臭 氧化和常规工艺处理后,深度处理工艺可再去除67％的含藻量。工艺参数:臭氧投加量2 mg／L,接 触时间15 min,活性炭滤池滤速10 m／h,停留时间12 min。探讨了预臭氧化和深度处理两种组合工 艺的除藻机理和影响因素。     

Efficient taste and odour removal by water treatment plants around the Han River water supply system.

Seven major water treatment plants in Seoul Metropolitan Area, which are under Korea Water Resources Corporation (KOWACO)'s management, take water from the Paldang Reservoir in the Han River System for drinking water supply. There are taste and odour (T&O) problems in the finished water because the conventional treatment processes do not efficiently remove the T&O compounds. This study evaluated T&O removal by ozonation, granular activated carbon (GAC) treatment, powder activated carbon (PAC) and an advanced oxidation process in a pilot-scale treatment plant and bench-scale laboratory experiments. During T&O episodes, PAC alone was not adequate, but as a pretreatment together with GAC it could be a useful option. The optimal range of ozone dose was 1 to 2 mg/L at a contact time of 10 min. However, with ozone alone it was difficult to meet the T&O target of 3 TON and 15 ng/L of MIB or geosmin. The GAC adsorption capacity for DOC in the three GAC systems (F/A, GAC and O3 + GAC) at an EBCT of 14 min is mostly exhausted after 9 months. However, substantial TON removal continued for more than 2 years (>90,000 bed volumes). GAC was found to be effective for T&O control and the main removal mechanisms were adsorption capacity and biodegradation.     

Evaluating ozone dose for AOC removal in two-step GAC filters

Upgrading an existing post-ozonation plant with two-step granular activated carbon (GAC) filtration for assimilable organic carbon (AOC) removal was studied. The effects of ozone dose on AOC formation and its removal in the subsequent two-step GAC filtration was studied using chemically pretreated 2 to 14° C humic lake water. Two parallel pilot-plant trains with different ozone doses (0 to 1.2 mgO₃/mgTOC) and a shortterm ozonation study were performed. The optimum ozone dose for maximum AOC formation was 0.4–0.5 mgO₃/mgTOC. The AOC-P17 of ozonated water was three-fold higher and AOC-NOX over ten-fold higher than in non-ozonated water, while the following biofiltration (first step) removed 51 % and 72 % of AOC-P17 and AOC-NOX, respectively. The adsorber (second step) contributed to less than 10% of the overall AOC reduction. It appeared that biofiltration is a feasible method in upgrading water treatment plants for AOC removal even when treating cold humic waters, while the subsequent adsorber seems to have less significance for AOC removal.     

Removal of geosmin and 2-methylisoborneol by biological filtration.

The quality of drinking water is sometimes diminished by the presence of certain compounds that can impart particular tastes or odours. One of the most common and problematic types of taste and odour is the earthy/musty odour produced by geosmin (trans-1, 10-dimethyl-trans-9-decalol) and MIB (2-methylisoborneol). Taste and odour treatment processes including powdered activated carbon, and oxidation using chlorine, chloramines, potassium permanganate, and sometimes even ozone are largely ineffective for reducing these compounds to below their odour threshold concentration levels. Ozonation followed by biological filtration, however, has the potential to provide effective treatment. Ozone provides partial removal of geosmin and MIB but also creates other compounds more amenable to biodegradation and potentially undesirable biological instability. Subsequent biofiltration can remove residual geosmin and MIB in addition to removing these other biodegradable compounds. Bench scale experiments were conducted using two parallel filter columns containing fresh and exhausted granular activated carbon (GAC) media and sand. Source water consisted of dechlorinated tap water to which geosmin and MIB were added, as well as, a cocktail of easily biodegradable organic matter (i.e. typical ozonation by-products) in order to simulate water that had been subjected to ozonation prior to filtration. Using fresh GAC, total removals of geosmin ranged from 76 to 100% and total MIB removals ranged from 47% to 100%. The exhausted GAC initially removed less geosmin and MIB but removals increased over time. Overall the results of these experiments are encouraging for the use of biofiltration following ozonation as a means of geosmin and MIB removal. These results provide important information with respect to the role biofilters play during their startup phase in the reduction of these particular compounds. In addition, the results demonstrate the potential biofilters have in responding to transient geosmin and MIB episodes.     

Aerobic bacterial spores as process indicators for protozoa cysts in water treatment plants.

The possibility of using aerobic spores as indicators (surrogates) of water treatment efficiency for the removal of Giardia cysts and Cryptosporidium oocysts was evaluated in a water treatment plant that supplies the Barcelona area of Spain. The water treatment consists of pre-chlorination, flocculation-sedimentation, double filtration (sand and granular activated carbon, GAC) with intermediate ozonation and post-chlorination. Aerobic spores significantly increased after GAC filtration, which indicated an active propagation of aerobic spore-formers. However, anaerobic (Clostridium) spores could be a good surrogate for Cryptosporidium oocysts, especially if their detection in samples at low concentrations was improved.     

再生颗粒活性炭在果园桥水厂的应用实践

桐乡市果园桥水厂采用臭氧-生物活性炭深度处理工艺,为了强化处理效果、降低制水成本、减少环境污染,对饱和生物活性炭进行了再生.通过检测,再生炭的碘值恢复率达90%以上,亚甲基蓝值恢复率接近90%,强度略有下降,但仍高达93%,灰分增长了91.5%.再生炭运行当月CODMn去除率高达78.4%,运行半年至今去除率仍达50%左右,处理效果接近新炭水平.采用再生方式比全部更换新炭节省费用50%以上.最后阐述了饱和活性炭再生利用的可行性及必要性.     

臭氧生物活性炭技术的工艺设计与运行管理

针对臭氧生物活性炭工艺应用中的关键问题,首先对工艺设计中的活性炭滤料选择、活性炭滤层结构设计、活性炭滤池选择、臭氧系统选择、臭氧接触池优化设计和复合预氧化设计等内容进行了分析和总结.然后对运行中存在的微生物安全性、大型微生物控制、活性炭滤池初滤水管理及pH控制、预臭氧和主臭氧工艺的运行管理等问题进行了总结,并提出了相应的解决方案.最后,建议今后应重点注意微生物安全性、臭氧副产物控制和工艺运行控制标准等问题.     

臭氧-活性炭工艺去除饮用水中典型内分泌干扰物试验研究

通过对臭氧-活性炭工艺和活性炭吸附等温线的研究,探讨了臭氧-活性炭工艺去除饮用水中微量典型内分泌干扰物的可行性.壬基酚(NP)、辛基酚(OP)和双酚A(BPA)被选作目标物质.研究发现臭氧氧化能去除30%以上的NP、OP和BPA;活性炭对NP、OP和BPA也有良好的去除效果,在空床停留时间4～12 min条件下能完全去除水中未被臭氧氧化的NP、OP和BPA;吸附等温线的数据可以用Freundlich公式拟合,并用来估算活性炭的饱和时间.试验证明臭氧-活性炭工艺是去除饮用水中微量典型内分泌干扰物的有效方法.     

微污染水库水处理工艺研究

通过中试,研究了生物预处理-常规处理-GAC(或O3-BAC)深度处理以及预加氯一常规处理-GAC(或O3-BAC)深度处理对微污染水库水的处理效果。结果表明,对于可生物降解性较好的原水,采用生物预处理可以明显地改善后续常规处理及深度处理的出水水质。对于氨氯、CODMn和UV254较高的水库水,处理工艺流程中应包括生物预处理或O3-BAC工艺。生物预处理-常规处理-GAC工艺的总处理效果好于预加氯-常规处理-O3-BAC工艺。此外,GAC能吸附氯仿、致突变物。当GAC再生周期过长时,出水的氯仿浓度高于进水,且Ames试验呈阳性。GAC的去臭有效期在16个月以上。     

纳滤、反渗透工艺深度处理饮用水研究

利用纳滤和反渗透膜深度处理工艺进行长江原水水质净化中试研究,工艺流程为长江原水→混凝沉淀→沙滤→颗粒活性炭→纳滤/反渗透,比较纳滤、反渗透膜工艺对污染物特别是微量有机物苯系物、三氯乙烯及消毒副产物等的去除效果。结果表明膜工艺预处理能够有效地去除原水的浊度和部分污染物,有利于纳滤、反渗透的稳定运行。纳滤膜工艺的最佳操作压力是0.4 MPa,此压力下产水量为250 L/h,回收率为24%,SO₄^2-,Cl^-,NO₃^-和总硬度的去除率分别为91.7%,85.4%,85.2%,89.3%;采用浓缩水回流能兼顾较高的回收率和良好的去除率。2种膜工艺对苯系物与三氯乙烯的去除率均在95.7%以上;对消毒副产物也有较好的控制效果,其中大部分的削减率在63.7%以上。与反渗透膜工艺比较,纳滤膜工艺具有较低的生产成本。纳滤膜工艺净化出水中可部分保留对人体有益的矿物质,使得净化后的出水成为优质健康饮用水。