臭氧与氯联合消毒对钱塘江水源水DBPs形成及溴取代的影响

本文研究了在pH 6～8、反应时间2～72 h、反应温度10～30℃条件下,钱塘江水源水在臭氧-氯消毒联合作用下,三卤甲烷(THMs)、二卤乙酸(DHAAs)、三卤乙酸(THAAs)、二卤乙腈(HANs)、三卤硝基甲烷(THNMs)等5类消毒副产物(DBPs)的形成和溴取代特征.结果显示,臭氧-氯消毒下DBPs的形成与氯消毒有较多相似之处:①大部分DBPs形成量均随着温度的升高、时间的延长而增加,相应的溴取代因子(BSFs)则随着时间的延长、温度的上升而呈下降趋势;②氯代DHANs倾向于在酸性条件下形成多,而溴代DHANs则倾向于在碱性条件下形成多;③不管是氯消毒还是臭氧-氯消毒,也不管是哪种消毒条件,5类DBPs的BSF值顺序均为BSF_(HNMs)BSF_(DHANs) BSF_(THAAs)BSF_(THMs)≈BSF_(DHAAs).但与氯消毒不同的是,臭氧-氯消毒下THMs、DHAAs、THAAs、HANs的形成产量更低,而THNMs的产量则更高;而且与氯消毒相比,臭氧-氯消毒普遍增加了DBPs的溴取代程度,也改变了溴离子在不同DBPs之间的分配,即减少了THMs、DHAAs、THAAs、DHANs对溴的利用率,但大幅增加了HNMs的溴利用率.鉴于溴代HNMs的极高毒性,因此对于钱塘江水源水,臭氧-氯消毒要注意HNMs带来的健康风险.     

煮沸对氯、氯胺模拟消毒饮用水中六大类DBPs的去除规律研究

以陆生来源有机物为原料制备了模拟氯、氯胺消毒饮用水,系统研究了煮沸对六大类46种消毒副产物（disinfection by-products, DBPs）的去除规律.结果显示,相比氯消毒,氯胺消毒可有效减少三卤甲烷（THMs）、卤乙酸（HAAs）、卤乙醛（HALs）、卤代硝基甲烷（HNMs）、卤乙腈（HANs）等DBPs的生成,但会提高碘代DBPs (I-DBPs)、卤乙酰胺（HAcAms）的生成.煮沸对于绝大多数DBPs （除了二卤乙酸）有良好的去除效果,并发现如下规律：(1)就单种DBP而言,消毒方式对煮沸去除DBPs并无显著影响;(2)在同类型的DBPs中,取代程度高的DBPs普遍比取代程度低的DBPs容易去除;(3)取代程度相同的同类型DBPs,煮沸后DBPs去除率大部分遵循I-DBPs> Br-DBPs> Cl-DBPs的规律;(4)少部分DBPs （如Cl/Br-THMs、二卤乙腈）,煮沸去除率表现出沸点或亨利常数依赖性.总体来看,DBPs去除率排序为THMs≈HANs≈HALs≈HNMs> HAcAms>>HAAs.此外,煮沸后各类DBPs的...     

太湖、钱塘江取水口底泥及周边土壤有机物形成消毒副产物的特征研究

底泥、土壤均是水体有机物的重要来源,但目前相关消毒副产物(DBPs)形成方面的研究偏少.本研究以长三角重要水源地太湖、钱塘江取水口的底泥和周边土壤的浸出液为研究对象,探索氯、臭氧+氯、氯胺、臭氧+氯胺4种消毒方式下,三卤甲烷(THMs)、卤代酮(HKs)、卤乙腈(HANs)、卤代硝基甲烷(HNMs)的形成情况.结果表明,太湖、钱塘江取水口的底泥、周边土壤有机物的芳香度均很低(SUVA254(即比紫外吸光值)2),与腐殖质(Sigma)相比,底泥、土壤有机物不是氯消毒中THMs的重要前驱物,但却是HANs特别是HNMs的重要前驱物.相比氯消毒,氯胺消毒能大幅降低土壤、底泥有机物THMs、HKs、HANs、HNMs的生成量,而且也可抑制含溴DBPs的形成.臭氧预处理大幅提高了氯、氯胺消毒中HKs、HNMs的产量,但对THMs、HANs则不一定.太湖、钱塘江的土壤、底泥存在一定的溴污染,但不管是哪种消毒方式,均是HNMs的溴嵌入因子最大.     

操作条件及水质对海水氯消毒过程中消毒副产物生成的影响

氯消毒广泛应用于海水利用的预处理过程中,以减少生物膜淤积,而消毒过程会导致各类消毒副产物(DBPs)的生成,可能会对海洋生态环境具有潜在危害。系统研究了操作条件和水质对海水氯化消毒过程中生成三卤甲烷(THMs)、卤乙腈(HANs)和卤乙酸(HAAs)的影响。结果表明,氯投加量对DBPs生成的影响最大,随着投氯量的增加,THMs、HANs和HAAs的生成量显著增加,在反应初期随反应时间的延长而增加,随后HANs和HAAs的生成量开始缓慢降低而THMs基本保持不变。随着温度升高,THMs的生成量稳步增加,而HAAs和HANs在分别达到30,25℃后生成量达到最大值,之后随温度的升高而降低。p H对THMs、HANs和HAAs生成的影响相反,在酸性条件下HANs和HAAs的生成量最多,而在碱性条件下THMs的生成量最多。THMs、HANs和HAAs的生成量随溴离子浓度的改变无明显变化,但是随着氨氮浓度的升高,THMs、HANs和HAAs的生成种类和生成量均有明显降低。     

两点短时游离氯后转氯胺的顺序氯化消毒工艺研究

基于顺序氯化消毒工艺的原理,采用两点短时游离氯后转氯胺的两点顺序氯化消毒工艺,即在过滤和清水池前的两点分别加氯,并在清水池加氯后立即加氨转化为氯胺消毒的工艺,该工艺在常规处理工艺的给水厂进行了消毒试验.结果表明,加氯点的适当提前,不仅有利于控制消毒副产物的生成量,而且有效抑制了滤池中的生物膜滋生.两点顺序氯化消毒工艺中生成的卤代消毒副产物比相同条件下一次性加入等量的氯消毒剂的消毒方法产生的三卤甲烷(THMs)平均减少了51.6％,卤乙酸(HAAs)平均减少了46.7％.细菌学指标HPC的结果也显示出了该工艺在保障水质的微生物安全方面的优势.     

南水北调丹江口水库水氯(胺)化消毒副产物产生特性与消毒工艺对比

系统研究了南水北调中线工程水源——丹江口水库水在氯(胺)化消毒条件下,常规消毒副产物的产生特性,考察了消毒方式、消毒剂投加量、接触时间、p H和溴离子浓度等因素的影响,并对消毒工艺参数进行了优化.结果发现,丹江口水库水经氯化消毒可产生三氯甲烷、二氯一溴甲烷等常规含碳和较低浓度二氯乙腈、三氯硝基甲烷等含氮消毒副产物,而氯胺化消毒仅产生三氯甲烷和三氯硝基甲烷等消毒副产物(disinfection by-products,DBPs).自由氯消毒过程产生的各类型DBPs浓度约为氯胺消毒的7.5倍,短时自由氯转氯胺方式DBPs产生量介于两者之间;随着自由氯投加量增加,各类型消毒副产物均呈现增加趋势,投加量大于2 mg·L-1后DBPs增加量较少.随氯胺投加量增加,三氯甲烷生成量变化不大,投加量大于2mg·L-1后可产生三氯硝基甲烷等副产物.随反应时间延长,自由氯的衰减速率明显大于氯胺,同时消毒副产物增长量明显快于氯胺消毒.随着p H升高,自由氯消毒后三卤甲烷含量呈现增加趋势,而氯胺消毒后变化不明显.随溴离子浓度的增加,自由氯和氯胺消毒后副产物类型均向溴代DBPs转变,同时总生成量明显增加,自由氯消毒DBPs增长量明显大于氯胺消毒过程.丹江口水库水采用氯胺化消毒可以降低消毒副产物的生成风险,如采用自由氯消毒方式,水厂需根据实际常规处理工艺重点控制自由氯的投加量等参数.     

饮用水消毒副产物分析及相关研究进展

饮用水消毒副产物（DBPs）是消毒剂和一些天然有机物（NOM）反应生成的化合物,主要包括三卤甲烷（THMs）、卤代G@（HAAs）、卤代乙腈（HANs）和致诱变化舍物（MX）4类。本文针对氯、氯胺、二氧化氯、臭氧4种主要消毒方式产生的消毒副产物,讨论了有关分析技术的发展过程,从DBPs的前处理技术、分析技术等角度,介绍了DBPs研究领域近期所取得的进展,并展望了今后研究的发展方向。     

海水淡化超滤-反渗透工艺沿程溴代消毒副产物变化规律

研究了海水淡化超滤-反渗透(UF-RO)工艺沿程有机物和溴代消毒副产物(Br-DBPs)变化特征.该海水中含有较高浓度的Br-(45.6~50.9 mg·L-1)和较多的芳香类化合物[比紫外吸收值SUVA为3.6~6.0 L·(mg·m)-1];色氨酸类芳香族蛋白质、富里酸类有机物和溶解性微生物代谢产物是海水中主要的荧光特征有机物.UF-RO工艺进水海水经Na Cl O消毒后,DBPs的种类和浓度显著增加,且增加的主要为Br-DBPs,其中三溴甲烷(CHBr3)占总三卤甲烷(THMs)的70.48%~91.50%,二溴乙酸(Br2CHCO2H)占总卤乙酸(HAAs)的81.14%~100%,二溴乙腈(C2HBr2N)占总卤乙腈(HANs)的83.77%~87.45%.UF膜对THMs、HAAs和HANs的去除率分别为36.63%~40.39%、73.83%~95.38%和100%.RO膜可以完全去除HAAs,但是对THMs不能完全去除.进水海水的抗雌激素活性为0.35~0.44 mg·L-1,氯消毒后增加了32%~69%.海水淡化UF-RO系统生成的DBPs和其他生物毒性物质最终被截留到了UF浓水和RO浓水中.     

供水管网终端消毒副产物分布特征及预测模型

消毒副产物(disinfection by-products, DBPs)是影响饮用水水质的重要指标.以浙江省H市某区域供水点为调查目标,考察终端龙头水及加热器处理后饮用水中DBPs的含量特征,结合水质理化指标,初步确定管网终端DBPs预测模型,评估经口摄入的健康风险.结果表明,H市某供水点龙头水中共检出THMs、HANs和HAAs这3类共计10种DBPs.龙头水中目标DBPs检出率均为100%,THMs、HANs和HAAs质量浓度分别为10.12～28.39、 0.98～5.19和2.65～7.83μg·L~(-1);热水中TBM、TCAN和DBAN的检出率分别为46.43%、 82.14%和92.86%,BCAN未检出,其它DBPs检出率为100%,THMs、HANs和HAAs质量浓度分别为0.60～12.58、 0.02～0.52和2.42～5.86μg·L~(-1).加热处理后THMs和HANs的含量有所降低,总量分别降低84.22%和91.45%,HAAs变化不明显.水质理化指标pH值和SUVA与DBPs呈正相关关系,余氯和氨氮与DBPs呈负相关关系.根据常规指标与DBPs相关性建立THMs多元线性预测模型,相对误差小于10.00%,准确度较高,可用于管网供水终端THMs的预测.基于美国环保署推荐的健康风险评价模型对经口摄取途径时氯消毒副产物的致癌和非致癌风险进行计算,发现H市龙头水和热水中DBPs通过饮水途径的致癌风险分别为(17.24～84.63)×10~(-6)和(25.49～258.82)×10~(-7);非致癌风险分别为(4.17～50.32)×10~(-2)和(6.52～107.74)×10~(-3).龙头水中BDCM对致癌风险的贡献率最大,而热水系统中TCM贡献率最大;龙头水及热水中非致癌风险主要来自于TCM.热水中THMs的削减量最高达到94.38%,致癌风险降低79.00%.     

海水淡化低温多效蒸馏工艺(LT-MED)沿程溴代消毒副产物的生成

研究了海水淡化低温多效蒸馏(LT-MED)工艺沿程水质和溴代消毒副产物(Br-DBPs)变化特征.LT-MED工艺进水海水的Br-浓度和比紫外吸收值(SUVA)分别为54.6 mg·L~(-1)和1.7 L·(mg·m)-1,其荧光特征有机物主要有色氨酸类芳香族蛋白质、富里酸类有机物和溶解性微生物代谢产物.进水海水经Na Cl O消毒后,DBPs的种类和浓度显著增加,且增加的主要为Br-DBPs,三溴甲烷(CHBr3)占总三卤甲烷(THMs)的100%;一溴乙酸(C2H3Br O2)和二溴乙酸(C2H2Br2O2)分别占总卤乙酸(HAAs)的31.9%和68.1%;四溴苯酚(C6H5Br O)占总卤代酚(HPs)的100%.LT-MED海水淡化产品水中THMs、HAAs和HPs均未检出,但是其浓水中的THMs、HAAs和HPs浓度分别为56.9、35.0和0.1μg·L~(-1).     

Formation of regulated and unregulated disinfection byproducts during chlorination and chloramination: Roles of dissolved organic matter type, bromide, and iodide

Algal blooms and wastewater effluents can introduce algal organic matter (AOM) and effluent organic matter (EfOM) into surface waters, respectively. In this study, the impact of bromide and iodide on the formation of halogenated disinfection byproducts (DBPs) during chlorination and chloramination from various types of dissolved organic matter (DOM, e.g., natural organic matter (NOM), AOM, and EfOM) were investigated based on the data collected from literature. In general, higher formation of trihalomethanes (THMs) and haloacetic acids (HAAs) was observed in NOM than AOM and EfOM, indicating high reactivities of phenolic moieties with both chlorine and monochloramine. The formation of haloacetaldehydes (HALs), haloacetonitriles (HANs) and haloacetamides (HAMs) was much lower than THMs and HAAs. Increasing initial bromide concentrations increased the formation of THMs, HAAs, HANs, and HAMs, but not HALs. Bromine substitution factor (BSF) values of DBPs formed in chlorination decreased as specific ultraviolet absorbance (SUVA) increased. AOM favored the formation of iodinated THMs (I-THMs) during chloramination using preformed chloramines and chlorination-chloramination processes. Increasing prechlorination time can reduce the I-THM concentrations because of the conversion of iodide to iodate, but this increased the formation of chlorinated and brominated DBPs. In an analogous way, iodine substitution factor (ISF) values of I-THMs formed in chloramination decreased as SUVA values of DOM increased. Compared to chlorination, the formation of noniodinated DBPs is low in chloramination.     

A balancing act: Optimizing free chlorine contact time to minimize iodo-DBPs, NDMA, and regulated DBPs in chloraminated drinking water

Many drinking water treatment plants in the U.S. have switched from chlorination to chloramination to lower levels of regulated trihalomethane (THM) and haloacetic acid (HAA) disinfection byproducts (DBPs) in drinking water and meet the current regulations. However, chloramination can also produce other highly toxic/carcinogenic, unregulated DBPs: iodo-acids, iodo-THMs, and N-nitrosodimethylamine (NDMA). In practice, chloramines are generated by the addition of chlorine with ammonia, and plants use varying amounts of free chlorine contact time prior to ammonia addition to effectively kill pathogens and meet DBP regulations. However, iodo-DBPs and nitrosamines are generally not considered in this balancing of free chlorine contact time. The goal of our work was to determine whether an optimal free chlorine contact time could be established in which iodo-DBPs and NDMA could be minimized, while keeping regulated THMs and HAAs below their regulatory limits. The effect of free chlorine contact time was evaluated for the formation of six iodo-trihalomethanes (iodo-THMs), six iodo-acids, and NDMA during the chloramination of drinking water. Ten different free chlorine contact times were examined for two source waters with different dissolved organic carbon (DOC) and bromide/iodide. For the low DOC water at pH 7 and 8, an optimized free chlorine contact time of up to 1 h could control regulated THMs and HAAs, as well as iodo-DBPs and NDMA. For the high DOC water, a free chlorine contact time of 5 min could control iodo-DBPs and NDMA at both pHs, but the regulated DBPs could exceed the regulations at pH 7.     

饮用水含氮与含碳消毒副产物的生成潜能及其毒性

消毒副产物生成潜能测试常用于表征水中消毒副产物的前体物含量.不同于三氯甲烷等含碳消毒副产物,二卤代乙腈（DHANs）与二卤代乙酰胺（DHAcAms）等含氮消毒副产物在氯消毒的余氯存在下易分解,并且在氯胺消毒过程中可由氯胺提供氮源生成,因此常用于含碳消毒副产物的生成潜能测试方法（如Krasner提出的测试法）可能无法有效揭示DHANs与DHAcAms的前体物水平.本研究以三氯甲烷和氯醛两种含碳消毒副产物为对比,考察DHANs与DHAcAms在饮用水氯消毒与氯胺消毒过程中不同投氯量与反应时间下的生成量,识别最大生成量对应的消毒条件,以便更好地评估水样中DHANs与DHAcAms的前体物浓度.同时,对消毒过程中生成的这些挥发性消毒副产物进行毒性评价.结果显示,两个水样氯消毒的DHANs与DHAcAms生成量分别为6.19~40.08、1.34~15.75 nmol·mg^-1（mg^-1以TOC计）;氯胺消毒的DHANs与DHAcAms生成量分别为2.63~21.46、18.43~49.99 nmol·mg^-1.Krasner测试法条件下的DHANs与DHAcAms生成量均最低.在投氯量为TOC+8×NH₃-N、反应时间为24 h的氯消毒条件下,氯胺投加量20×TOC、反应时间为3 d的氯胺消毒条件下,两个水样具有最高水平的DHANs与DHAcAms生成量,并且消毒副产物毒性也高于Krasner法测试条件下的毒性水平.因此,氯消毒采用投氯量TOC+8×NH₃-N、反应时间24 h,氯胺消毒采用投加量20×TOC、反应时间3 d的生成潜能测试条件可能更好地揭示水中DHANs和DHAcAms的前体物浓度水平.     

不同预氧化剂对长江原水氯(胺)化DBPs生成潜能的影响

以取自上海市杨树浦水厂的长江原水为研究对象,对比分析了3种常见预氧化剂二氧化氯(ClO2)、高锰酸钾(KMnO4)及氯(Cl2)预氧化对削减氯化和氯胺化消毒副产物(DBPs)生成潜能的效果情况.氯化培养实验结果表明,3种预氧化剂的处理对DBPs总量的去除效果均不显著,经ClO2、Cl2及KMnO4作用后可分别削减8.4%、5.7%及3.9%,效果为ClO2>Cl2>KMnO4.对于长江原水使用氯化消毒时,采用ClO2作为预氧化剂可取得对消毒副产物较好的去除效果.氯胺化培养实验结果表明,3种预氧化剂处理对长江原水氯胺化DBPs的生成潜能影响有较大差异,经ClO2和KMnO4作用后可分别削减18.1%及4.1%,而预氯化后则增高12.3%,对于长江原水使用氯胺化消毒时,采用ClO2作为预氧化剂可取得对消毒副产物较为明显的去除效果.同时,应尽量避免使用预氯化后加氯胺化的组合,以防止在水处理过程中生成更多的DBPs而影响出水水质.     

Formation and control of disinfection byproducts and toxicity during reclaimed water chlorination: A review

Chlorination is essential to the safety of reclaimed water; however, this process leads to concern regarding the formation of disinfection byproducts (DBPs) and toxicity. This study reviewed the formation and control strategies for DBPs and toxicity in reclaimed water during chlorination. Both regulated and emerging DBPs have been frequently detected in reclaimed water during chlorination at a higher level than those in drinking water, indicating they pose a greater risk to humans. Luminescent bacteria and Daphnia magna acute toxicity, anti-estrogenic activity and cytotoxicity generally increased after chlorination because of the formation of DBPs. Genotoxicity by umu-test and estrogenic activity were decreased after chlorination because of destruction of toxic chemicals. During chlorination, water quality significantly impacted changes in toxicity. Ammonium tended to attenuate toxicity changes by reacting with chlorine to form chloramine, while bromide tended to aggravate toxicity changes by forming hypobromous acid. During pretreatment by ozonation and coagulation, disinfection byproduct formation potential (DBPFP) and toxicity formation potential (TFP) occasionally increase, which is accompanied by DOC removal; thus, the decrease of DOC was limited to indicate the decrease of DBPFP and TFP. It is more important to eliminate the key fraction of precursors such as hydrophobic acid and hydrophilic neutrals. During chlorination, toxicities can increase with the increasing chlorine dose and contact time. To control the excessive toxicity formation, a relatively low chlorine dose and short contact time were required. Quenching chlorine residual with reductive reagents also effectively abated the formation of toxic compounds.     

顺序氯化消毒工艺的研究

研究了短时游离氯后转氯胺的顺序消毒工艺.结果表明,该消毒工艺对指示微生物的灭活效果优于游离氯消毒,游离氯和氯胺存在协同消毒作用;对脊髓灰质炎病毒和大肠杆菌f₂噬菌体的灭活效果与游离氯相同.相同原水条件下,顺序氯化消毒工艺产生的三卤甲烷浓度比游离氯消毒工艺减少35.8%～77.0%;卤乙酸减少36.6%～54.8%.消毒进水水质越差,顺序氯化消毒工艺在消毒副产物(DBP)控制方面就越具优势.     

Formation potentials of typical disinfection byproducts and changes of genotoxicity for chlorinated tertiary effluent pretreated by ozone

The effects of ozonation on the formation potential of typical disinfection byproducts (DBPs) and the changes of genotoxicity during post chlorination of tertiary effluent from a sewage treatment plant were investigated. Ozonation enhanced the yields of all detected chlorine DBPs except CHCl3. At a chlorine dose of 5 mg/L, the three brominated THMs and five HAAs increased, while chloroform decreased with the increase of ozone dose from 0 to 10 mg/L (ozone dose in consumption base). At a chlorine dose of 10 ...