高藻期太湖水处理工艺的研究

研究了混凝、超滤、臭氧、活性炭等工艺对高藻期太湖水的处理效果,结果表明:当进水浊度波动较大时,混凝超滤最终出水浊度平均为0.02 NTU,大大低于<生活饮用水卫生标准>(GB5749-2006)的上限值3.混凝-超滤-臭氧-活性炭组合工艺对CODMn的平均去除率达到90.5%,原水水质降至平均值1.16 mg/L,达到了<生活饮用水卫生标准>(GB5749-2006)的要求.该组合工艺对UV254的总去除率平均值为94.3%,去除效果明显,最终出水嗅阈值平均值为2,低于管道直饮水水质标准(Q/ZLS001-1998)的上限标准3.组合工艺出水未检测到藻类,保证了水质的生物稳定性.该组合工艺能充分发挥各自的作用,提高处理效果,保障饮用水的安全.     

臭氧/陶瓷膜对生物活性炭工艺性能和微生物群落结构影响

利用处理量为120m3/d的臭氧/陶瓷膜-生物活性炭(BAC)组合工艺处理微污染原水, 对工艺性能和BAC中的微生物多样性和种群结构进行了研究.结果显示,组合工艺可有效去除微污染原水中的有机物和氨氮.臭氧曝气提高了溶解氧浓度,改善了后续BAC工艺对氨氮的去除效果.组合工艺对氨氮和CODMn的总去除率分别约为90%和84%,其中BAC在污染物的去除中发挥了重要作用.组合工艺和传统工艺中BAC床层共检测到36个门类的细菌.与传统BAC工艺相比,臭氧/陶瓷膜降低了后续BAC中微生物群落结构的多样性和均匀度.组合工艺BAC中存在丰度较高的亚硝化单胞菌属和硝化螺旋菌属,可能对氨氮的去除具有重要的作用.臭氧/陶瓷膜对后续BAC中致病菌和条件致病菌有很好的预处理和抑制作用,显著降低了其相对丰度,提高了饮用水的生物安全性.     

臭氧/陶瓷膜对生物活性炭工艺性能和微生物群落结构影响

利用处理量为120m3/d的臭氧/陶瓷膜-生物活性炭(BAC)组合工艺处理微污染原水,对工艺性能和BAC中的微生物多样性和种群结构进行了研究.结果显示,组合工艺可有效去除微污染原水中的有机物和氨氮.臭氧曝气提高了溶解氧浓度,改善了后续BAC工艺对氨氮的去除效果.组合工艺对氨氮和CODMn的总去除率分别约为90%和84%,其中BAC在污染物的去除中发挥了重要作用.组合工艺和传统工艺中BAC床层共检测到36个门类的细菌.与传统BAC工艺相比,臭氧/陶瓷膜降低了后续BAC中微生物群落结构的多样性和均匀度.组合工艺BAC中存在丰度较高的亚硝化单胞菌属和硝化螺旋菌属,可能对氨氮的去除具有重要的作用.臭氧/陶瓷膜对后续BAC中致病菌和条件致病菌有很好的预处理和抑制作用,显著降低了其相对丰度,提高了饮用水的生物安全性.     

环境卫生与卫生工程

X332(X)l(X) 757臭氧一生物活性炭工艺去除水中有机微污染物/于秀娟(哈尔滨工业大学)…//环境污染与防治/浙江省环保局一200。,22(4)一l一3 环图X一3 在臭氧接触反应柱中填装陶粒填料,构成了臭氧一陶粒~生物活性炭饮用水深度净化流程,用该流程对去除水中有机微污染物进行了试验研究。结果表明,臭氧一陶粒~生物活性炭工艺充分发挥了臭氧的强氧化性、陶粒的辅助作用和生物活性炭的吸附过滤及生物降解作用,使cOD。去除率达到近40%,有机物由原来的58种减少到30种,潜在有毒有害物质减少到4种,表明该工艺是一种适宜的饮用水深度净化工艺。图2表…     

臭氧-活性炭对某市饮用水中消毒副产物和生物稳定性控制的研究

为了研究臭氧-活性炭工艺对某市饮用水中消毒副产物和生物稳定性的影响,在原有工艺的基础上,于反应池前增加了预臭氧氧化工艺,分两级投加臭氧,同时将臭氧尾气回收,以增加水体中臭氧的吸收率以及混凝、反应、沉淀的效果。系统稳定运行6个月,出水浊度为0．2NTU左右,出水色度为2～3度,CODM。出水浓度为0．6mg／L,平均去除率为88％,氨氮经折点加氯后可降至0．2mg／L以下,均达到饮用水标准。对于试验水质条件下,臭氧化与活性炭吸附联合作用能够有效地去除水中AOC和氯化消毒副产物前质。     

臭氧生物活性炭工艺运行中产生溴酸盐的可能性分析

为合理评估应用臭氧生物活性炭工艺中溴酸盐的生成情况,提出既能保证出水水质又能降低溴酸盐超标风险的方案.进行了小试与中试试验,系统地从原水水质和工艺参数两个方面入手,研究水质因素、初始溴离子浓度和臭氧氧化条件等对溴酸盐生成的影响,同时分析生物活性炭对溴酸盐的去除能力.结果表明:高初始溴离子浓度水平和臭氧接触程度(Ct值)促使更多BrOx-生成.在相同Ct值条件下,升高臭氧投加浓度可使溴酸盐生成量增高200%左右.以长江南京段江心洲夹江下游原水进行臭氧生物活性炭深度处理不会产生溴酸盐超标风险.生物活性炭(BAC)对于溴酸盐去除效果并不明显.运用臭氧生物活性炭工艺进行深度处理时,工艺中应着重注意控制溴酸盐在臭氧化过程中的生成而非依靠后续生物活性炭将其去除.     

臭氧预氧化对饮用水处理作用的实验研究

目前,饮用水污染严重,常规工艺处理出现了水质不能达标的现象.本文主要研究在常规工艺增加预臭氧-活性炭过滤工艺,对不同的预臭氧投加量进行实验.结果表明:预臭氧投加量,对工艺各单元的处理效果有一定关系,随着投加量的增加,各单元对浊度、CODMn、UV254的去除呈现增大后趋于平缓甚至下降的趋势,而最佳臭氧的投加量为0.65 mg/L.为实际预臭氧-活性炭过滤工艺的运行提供指导.     

饮用水微污染处理技术研究进展

概述了饮用水微污染的现状及危害;综述化学氧化,吸附及生物等饮用水微污染的预处理技术,着重介绍强化混凝,臭氧活性炭,生物活性炭,臭氧生物活性炭,光化学催化,膜法及新型生物反应器等深度处理的方法原理及应用前景,并阐明各自的优缺点。     

生物活性炭法初步探讨

近年来,国内外对有机物污染饮用水的问题颇为重视,而用传统的水处理工艺难以有效地去除水中可溶性有机物.西欧国家在七十年代后期研究采用臭氧氧化-活性炭吸附净化饮用水新工艺,并逐渐形成所谓“生物活性炭法”. “生物活性炭法”能延长活性炭的使用寿命,为价格昂贵的粒状活性炭用于水处理技术开辟了广阔     

净水工艺对饮用水生物稳定性控制的研究

利用现场中试装置,系统比较了预处理单元、常规处理单元及深度处理单元中可生物降解有机物BDOC和AOC的生成和去除特性.结果表明:常规工艺+活性炭过滤对CODMn的去除率仅能达到30%,无法有效保证出水水质要求,而常规工艺+臭氧活性炭可以很好地满足水质标准,去除率可达50%以上.以控制生物稳定性为目的时,氧化剂的投加会增加AOC和BDOC浓度,降低生物稳定性.不投加氧化剂,直接采用常规工艺+普通活性炭过滤可将出水AOC含量控制在50μg/L以下.但要实现对COD_Mn和生物稳定性的同时控制,常规工艺+臭氧+生物活性炭的工艺组合是本研究中的最佳工艺组合.     

臭氧对生物活性炭中微生物及出水消毒副产物的影响

为探究饮用水处理过程中臭氧(O_3)对生物活性炭(BAC)中微生物及出水消毒副产物(DBPs)的影响,以饮用水小试装置的O_3-BAC工段开展研究,系统分析在不同O_3浓度下的水质变化,溶解性有机物(DOM)特征,微生物活性和DBPs产生情况.结果表明,O_3对BAC过滤的影响主要表现为提升微生物对DOM的利用效率,但O_3浓度过高会导致出水中蛋白质和微生物代谢产物(SMPs)等有机物增加.当O_3浓度从0 mg·L~(-1)提升到2. 0 mg·L~(-1)时,BAC中微生物存活率从95. 10%降至62. 60%,但O_3将出水中难降解有机物转变为易生物降解物质,使得微生物活性提高了62. 52%,BAC的生物过滤得到强化;当O_3浓度增加到4. 0 mg·L~(-1)时,微生物存活率降至49. 90%,同时微生物产生的蛋白质和SMPs增加,导致含碳消毒副产物(CDBPs)和含氮消毒副产物(N-DBPs)的生成浓度与不通O_3相比分别上升41. 93%和7. 18%,大大增加水体潜在危险.综上,合适O_3浓度有利于O_3-BAC对DOM的去除,O_3浓度过高会导致BAC过滤效果变差并产生新的DBPs前体物.     

O3-BAC深度处理石化废水厂尾水的特性及菌群结构分析

采用连续流O_3-BAC对华北某石化废水处理厂尾水进行了中试处理实验,研究了O_3氧化对COD及UV254处理效果的影响,同时对处理过程中有机物的变化特性及稳定运行30 d时BAC填料中的微生态环境进行了分析.结果表明,在O_3接触时间为40 min,O_3投加量为20 mg·L-1,BAC单元空床停留时间为1.5 h条件下,O_3-BAC工艺出水COD为24 mg·L-1,平均去除率为40.4%,相对于单独BAC工艺去除率提高10.0%,UV254的平均去除率为55.1%,且COD与UV254之间呈一定的相关性,相关系数R2为0.89;O_3氧化后相对分子质量1×103的比例由尾水中的69.0%提高到了87.0%,O_3-BAC工艺中NPOC的去除率为45.8%,较单独BAC工艺提高23.0%,且BAC单元去除的NPOC主要由相对分子质量1×103的组分所贡献;经GC-MS图谱及有机物统计分析,经O_3氧化后烷烃类、不饱和酯类及酚类等有机物得到明显的去除;O_3氧化后BAC单元的微生态环境得到明显改善,其中微生物种类(丰度在1.0%以上)由6种增加到了11种.O_3-BAC工艺可以有效应用于石化尾水的深度处理中.     

臭氧-生物活性炭对微污染原水中典型持久性有机物的去除效果

以长三角地区J市典型有机微污染水源P水厂为研究对象,考察了臭氧-生物活性炭深度处理工艺对微污染水源水中有机物的去除效果.结果表明,臭氧-生物活性炭深度处理使高锰酸盐指数、总有机碳(TOC)和UV254的平均去除率分别提升19. 2%、10. 4%和23. 0%.水厂原水中检出8种多环芳烃(polycyclic aromatic hydrocarbon,PAHs)、16种有机氯农药(organochlorine pesticides,OCPs)、5种卤乙酸(haloacetic acids,HAAs),其总浓度分别为53. 9~100. 0、6. 5~41. 8、2. 5×103~1. 1×104ng·L~(-1),臭氧-生物活性炭深度处理对多环芳烃和有机氯农药的平均去除率分别为32. 5%和25. 9%,比常规处理工艺出水的水质有显著提升.卤乙酸的去除率为33. 8%~87. 0%,主要通过常规处理工艺去除;臭氧-生物活性炭深度处理对氯代乙酸略有去除,溴代乙酸有少量生成.     

单级和两级串联臭氧-生物活性炭深度处理垃圾渗滤液的比较研究

使用单级和两级串联臭氧-生物活性炭(O3-BAC)处理垃圾焚烧渗滤液的二级生物处理尾水,比较研究了污染物去除效果.结果表明,臭氧投加量为200 mg·L-1时,两级串联O3-BAC对COD、UV254和色度的去除率分别为75.9%±2.1%、78.8%±2.9%和96.8%±0.9%,处理出水COD基本保持在100 mg·L-1以下,色度低于40倍,满足GB 16889-2008排放要求;而单级O3-BAC对COD、UV254和色度的去除率分别为68.2%±1.3%、69.7%±0.5%和92.5%±1.1%,处理出水COD和色度分别为150 mg·L-1和60倍,不能达到排放要求.单级O3-BAC在290 mg·L-1臭氧投加量下,才能达到两级串联O3-BAC在200mg·L-1臭氧投加量下的污染物去除效果.此外,两级串联O3-BAC在臭氧投加量200 mg·L-1时的总磷去除率为63.5%±4.4%,出水总磷浓度稳定在1 mg·L-1以下,直接满足GB 16889-2008排放要求.     

饮用水处理过程中全氟化合物的分布、转化及去向

全氟和多氟烷基物质(PFASs)存在于地表水、自来水甚至商业饮用水中,对人类健康构成威胁.在以太湖为源头的某大型饮用水处理厂(DWTPs)中研究了14种PFASs的检出和转化.结果表明,共有10种PFASs在水样中被检测到,说明PFASs在饮用水中分布广泛.原水中的PFASs总浓度为127.4ng·L^-1,其中最高浓度为全氟辛酸(PFOA, 49.8ng·L^-1).预臭氧会导致PFASs的浓度反向升高,这可能是由于前体物的存在或由短链向长链进行转化导致.常规处理工艺无法有效去除PFASs, O₃-BAC在DWTPs的处理过程中对PFASs的去除(20.74%)具有主导作用.O₃-BAC作为DWTPs的主要去除工艺,其反冲洗水中含有浓度较高的PFASs,分布特征与原水相似.利用中试装置,对比了5种常见的滤池反冲洗水处理工艺,结果表明,GAC-超滤可以在保证浊度较高去除率(99.08%)的基础上,吸附并截留一定量的PFASs.从三维荧光分析可得,GAC-超滤也可去除大部分荧光微污染物,对于原水含有较高浓...     

Pilot plant study on ozonation and biological activated carbon process for drinking water treatment

A study on advanced drinking water treatment was conducted in a pilot scale plant taking water from conventional treatment process. Ozonation-biological activated carbon process （O3-BAC） and granular activated carbon process （GAC） were evaluated based on the following parameters： CODMn, UV254, total organic carbon （TOC）, assimilable organic carbon （AOC） and biodegradable dissolved organic carbon （BDOC）. In this test, the average removal rates of CODMn, UV254 and TOC in O3-BAC were 18.2%, 9.0% and 10.2% higher on （AOC） than in GAC, respectively. Ozonation increased 19.3-57.6 μg Acetate-C/L in AOC-P17, 45.6-130.6 μg Acetate-C/L in AOC-NOX and 0.1-0.5 mg/L in BDOC with ozone doses of 2 8 mg/L. The optimum ozone dose for maximum AOC formation was 3 mgO3/L. BAC filtration was effective process to improve biostability.     

Revealing the changes of bacterial community from water source to consumers tap: A full-scale investigation in eastern city of China

This study profiled the bacterial community variations of water from four water treatment systems, including coagulation, sedimentation, sand filtration, ozonation-biological activated carbon filtration (O₃-BAC), disinfection, and the tap water after the distribution process in eastern China. The results showed that different water treatment processes affected the bacterial community structure in different ways. The traditional treatment processes, including coagulation, sedimentation and sand filtration, reduced the total bacterial count, while they had little effect on the bacterial community structure in the treated water (before disinfection). Compared to the traditional treatment process, O₃-BAC reduced the relative abundance of Sphingomonas in the finished water. In addition, ozonation may play a role in reducing the relative abundance of Mycobacterium. NaClO and ClO₂ had different effects on the bacterial community in the finished water. The relative abundance of some bacteria (e.g. Flavobacterium, Phreatobacter and Porphyrobacter) increased in the finished water after ClO₂ disinfection. The relative abundance of Mycobacterium and Legionella, which have been widely reported as waterborne opportunistic pathogens, increased after NaClO disinfection. In addition, some microorganisms proliferated and grew in the distribution system, which could lead to turbidity increases in the tap water. Compared to those in the finished water, the relative abundance of Sphingomonas, Hyphomicrobium, Phreatobacter, Rheinheimera, Pseudomonas and Acinetobacter increased in the tap water disinfected with NaClO, while the relative abundance of Mycobacterium increased in the tap water disinfected with ClO₂. Overall, this study provided the detailed variation in the bacterial community in the drinking water system.     

中常温变化对PN-ANAMMOX联合工艺脱氮效果的影响

通过接种成熟的亚硝化膜和厌氧氨氧化污泥,研究了中常温变化对PN-ANAMMOX联合工艺脱氮速率的影响及微生物群落的变化.结果表明,常温下能够实现PN-ANAMMOX联合脱氮,并且脱氮速率达到0.5 kg·(m~3·d)~(-1).但是PN过程亚硝化速率下降,ANAMMOX菌活性未得到充分发挥,导致PN-ANAMMOX联合工艺脱氮速率远低于中温条件下的1.75kg·(m~3·d)~(-1),出水水质较差.温度的上升易导致NOB的快速生长,PN过程失稳,但是通过增加回流量可对NOB的活性进行有效地控制.QPCR分析结果进一步表明接种中温环境下的AOB和ANAMMOX微生物在常温条件下不利于生长,出现部分死亡;当恢复到中温的环境时,相应的功能微生物出现了快速地生长.因此,在PN-ANAMMOX联合工艺的运行过程中应尽可能地满足功能微生物适宜的温度.     

Addition of hydrogen peroxide for the simultaneous control of bromate and odor during advanced drinking water treatment using ozone

Complete removal of the characteristic septic/swampy odor from Huangpu River source water could only be achieved under an ozone dose as high as 4.0 mg/L in an ozone-biological activated carbon （O3- BAC） process, which would lead to the production of high concentrations of carcinogenic bromate due to the high bromide content. This study investigated the possibility of simultaneous control of bromate and the septic/swampy odor by adding H2O2 prior to the O3-BAC process for the treatment of Huangpu River water. H2O2 addition could reduce the bromate concentration effectively at an H2O2/O3 （g/g） ratio of 0.5 or higher. At the same time, the septic/swampy odor removal was enhanced by the addition of H2O2, although optimization of the H2O2/O3 ratio was required for each ozone dose. At an ozone dose of 2.0 mg/L, the odor was removed completely at an H2O2/O3 ratio of 0.5. The results indicated that H2O2 application at a suitable dose could enhance the removal of the septic/swampy odor while suppressing the formation of bromate during ozonation of Huangpu River source water.     

Microbial community characterization, activity analysis and purifying efficiency in a biofilter process

The growth and metabolism of microbial communities on biologically activated carbon(BAC) play a crucial role in the purification of drinking water.To gain insight into the growth and metabolic characteristics of microbial communities and the efficiency of drinking water treatment in a BAC filter,we analyzed the heterotrophic plate count(HPC),phospholipid,dehydrogenase,metabolic function and water quality parameters during start-up and steady-state periods.In the start-up process of the filter with natural biofilm colonization,the variation in heterotrophic plate count levels was S-curved.The total phospholipid level was very low during the first 5 days and reached a maximum value after 40 days in the filter.The activity of dehydrogenase gradually increased during the first 30 days and then reached a plateau.The functional diversity of the microbial community in the filter increased,and then reached a relatively stable level by day 40.After an initial decrease,which was followed by an increase,the removal rate of NH4+-N and COD Mn became stable and was 80% and 28%,respectively,by day 40.The consumption rate of dissolved oxygen reached a steady level after 29 days,and remained at 18%.At the steady operation state,the levels of HPC,phospholipid,dehydrogenase activity and carbon source utilization had no significant differences after 6 months compared to levels measured on day 40.The filter was shown to be effective in removing NH4+-N,NO2--N,COD Mn,UV 254,biodegradable dissolved organic carbon and trace organic pollutants from the influent.Our results suggest that understanding changes in the growth and metabolism of microorganisms in BAC filter could help to improve the efficiency of biological treatment of drinking water.