删除或更新信息,请邮件至freekaoyan#163.com(#换成@)

活性炭-超滤深度处理工艺对三氯乙醛生成潜能的影响及其对饮用水中有机物的去除

本站小编 Free考研考试/2021-12-31
蔡广强1,2,3,,
刘伟4,
张金松1,2,3,
卢小艳1,
刘丽君1,
黄河洵1,
刘嘉祺1,
刘波1
1.深圳市水务集团有限公司,深圳 518031
2.哈尔滨工业大学深圳土木与环境工程学院,深圳 518055
3.深圳市水资源利用与环境污染控制重点实验室,深圳 518055
4.深圳市深水宝安水务集团有限公司,深圳 518133
基金项目: 国家水体污染控制与治理科技重大专项(2015ZX07406-004)




Influence on chloral hydrate formation potential and removal for organic matter in drinking water by activated carbon and ultrafiltration advanced treatment process

CAI Guangqiang1,2,3,,
LIU Wei4,
ZHANG Jinsong1,2,3,
LU Xiaoyan1,
LIU Lijun1,
HUANG Hexun1,
LIU Jiaqi1,
LIU Bo1
1.Shenzhen Water Affairs Group Co.Ltd., Shenzhen 518031, China
2.School of Civil and Environmental Engineering, Harbin Institute of Technology Shenzhen, Shenzhen 518055, China
3.Key Laboratory of Water Resource Utilization and Environmental Pollution Control in Shenzhen, Shenzhen 518055, China
4.Shenzhen Shenshui Baoan Water Affairs Group Co.Ltd., Shenzhen 518133, China

-->

摘要
HTML全文
(0)(0)
参考文献(22)
相关文章
施引文献
资源附件(0)
访问统计

摘要:以我国南方某活性炭-超滤深度处理工艺水厂为研究对象,对工艺过程中三氯乙醛生成潜能(CHFP)及相关有机物指标进行为期1年每月1次的监测,以明晰活性炭-超滤深度处理工艺对CHFP及有机物的去除能力。结果表明:原水CHFP均呈现一定的季节性变化趋势,高温季节(5—9月)相对较高,范围为15.50~64.00 μg·L-1,活性炭-超滤深度处理工艺对CHFP 、TOC、CODMn和UV254去除率范围分别为37.42%~69.12%、25.25%~66.71%、27.33%~61.25%和21.80%~72.46%,平均去除率分别为54.51%、39.21%、45.04%和42.91%;混凝沉淀单元在CHFP和有机物指标去除中均起主要作用,炭滤单元对TOC有较好的去除作用,超滤单元对CHFP和CODMn有较好的去除作用。建议水厂设计与运行中将臭氧与活性炭滤池联合使用,以协同去除CHFP和有机物,进一步提高供水水质。
关键词: 活性炭-超滤深度处理工艺/
消毒副产物/
三氯乙醛生成潜能/
有机物/
去除

Abstract:To figure out removal capacity for chloral hydrate formation potential (CHFP) and organic matter by the activated carbon and ultrafiltration advanced treatment process, CHFP and related organic indicators during a activated carbon and ultrafiltration advanced treatment process were measured monthly for a year for a drinking water treatment plant in the south of China. The results indicated that CHFP in raw water presented a trend of seasonal variation and high in high temperature season (from May to September), whose scopes were 15.50 to 64.00 μg·L-1. The removal rates range for CHFP, TOC, CODMn and UV254 were 37.42% to 69.12%, 25.25% to 66.71%, 27.33% to 61.25% and 21.80% to 72.46% by the activated carbon and ultrafiltration advanced treatment process, separately. Meanwhile, the mean removal rates for them were 54.51%, 39.21%, 45.04% and 42.91%, respectively. In addition, coagulation sedimentation played an essential role in the removal for CHFP and organics. Especially, activated carbon filter removed TOC and ultrafiltration removed CHFP and CODMn effectively. It is suggested that ozone should combine activated carbon filter to remove CHFP and organic matter in the water plant design and operation as far as possible, which further promotes the improvement of drinking water quality.
Key words:activated carbon and ultrafiltration advanced treatment process/
disinfection by-products (DBPs)/
chloral hydrate formation potential(CHFP)/
organic matter/
removal.

加载中
[1] CHU W, LI D, DENG Y, et al.Effects of UV/PS and UV/H2O2 pre-oxidations on the formation of trihalomethanes and haloacetonitriles during chlorination and chloramination of free amino acids and short oligopeptides[J].Chemical Engineering Journal,2016,1:65-72
[2] CHU W, LI X, BOND T, et al.The formation of haloacetamides and other disinfection by-products from non-nitrogenous low-molecular weight organic acids during chloramination[J].Chemical Engineering Journal,2016,5:164-171
[3] POSTIGO C, JEONG C H, RICHARDSON S D, et al.Analysis, Occurrence, and Toxicity of Haloacetaldehydes in Drinking Waters: Iodoacetaldehyde as an Emerging Disinfection By-Product[M].New York:Oxford University Press,2015:25-43
[4] JEONG C H, POSTIGO C, RICHARDSON S D, et al.Occurrence and comparative toxicity of haloacetaldehyde disinfection byproducts in drinking water[J].Environmental Science & Technology,2015,9(23):13749-13759
[5] 袁希慧.福州市自来水厂原水氯化消毒副产物的生成特性研究[D].福州: 福建师范大学, 2012
[6] 蔡广强,张金凤,刘丽君,等.南方某市饮用水中氯化消毒副产物超标风险评估[J].中国给水排水,2017,3(3):37-41
[7] 宋必伟.活性炭滤池-超滤联用对引黄水库水深度处理试验研究[D].哈尔滨: 哈尔滨工业大学,2014
[8] 乔铁军,张锡辉,张金松.活性炭-超滤组合工艺处理南方微污染原水的研究[J].给水排水,2011,7(4):15-18
[9] 李圭白,杨艳玲.第三代城市饮用水净化工艺:超滤为核心技术的组合工艺[J].给水排水,2007,3(4):1
[10] 李凤.超滤膜净水组合工艺中膜污染控制技术研究[D].哈尔滨: 哈尔滨工业大学, 2012
[11] 黄瑾辉,曾光明,刘萍,等.颗粒活性炭-超滤膜联用工艺去除管网水中微量有机物[J].水处理技术,2007,3(1):74-78
[12] 杨颂.超滤处理微污染水源水的运行效果及机理研究[D].哈尔滨: 哈尔滨工业大学, 2010
[13] 蔡广强,刘丽君,张金松,等.水合三氯乙醛前体物的分子量分布和荧光特性[J].净水技术, 2014,3(5):17-23
[14] 蔡广强.河库型水源三氯乙醛前体物分析与水质风险评估[D].哈尔滨: 哈尔滨工业大学, 2014
[15] 卢小艳,蔡广强,刘丽君,等.南方某河流原水中消毒副产物前体物的季节性变化[J].中国给水排水, 2015,1(11):51-55
[16] 蔡广强,傅学敏,刘丽君,等.曝气炭砂滤池对消毒副产物三氯乙醛的控制作用[J].中国给水排水, 2016,2(5):1-3
[17] DE VERA G A, KELLER J, GERNJAK W, et al.Biodegradability of DBP precursors after drinking water ozonation[J].Water Research,2016,6:550-561
[18] 唐晓会.炭砂滤池-超滤膜联用去除饮用水中污染物的试验研究[D].哈尔滨: 哈尔滨工业大学, 2008
[19] 杨忆新,刘文君,尹艳敏.超滤/粉末活性炭组合工艺深度处理黄河源水[J].中国给水排水,2010,6(15):48-50
[20] 石柳青.超滤在饮用水净化和城市污水深度处理中的应用研究[D].北京: 清华大学, 2011
[21] 孔令宇, 张晓健, 王占生.臭氧-生物活性炭与单独活性炭工艺处理效果比较[J].中国给水排水,2006,2(11):49-51
[22] 刘博才.臭氧-生物活性炭工艺对微污染水源水运行效果分析及其工程应用[D].天津:河北工业大学, 2015



加载中


Turn off MathJax -->
WeChat 点击查看大图

计量

文章访问数:1102
HTML全文浏览数:715
PDF下载数:574
施引文献:0
出版历程

刊出日期:2018-02-08



-->








活性炭-超滤深度处理工艺对三氯乙醛生成潜能的影响及其对饮用水中有机物的去除

蔡广强1,2,3,,
刘伟4,
张金松1,2,3,
卢小艳1,
刘丽君1,
黄河洵1,
刘嘉祺1,
刘波1
1.深圳市水务集团有限公司,深圳 518031
2.哈尔滨工业大学深圳土木与环境工程学院,深圳 518055
3.深圳市水资源利用与环境污染控制重点实验室,深圳 518055
4.深圳市深水宝安水务集团有限公司,深圳 518133
基金项目: 国家水体污染控制与治理科技重大专项(2015ZX07406-004)
关键词: 活性炭-超滤深度处理工艺/
消毒副产物/
三氯乙醛生成潜能/
有机物/
去除
摘要:以我国南方某活性炭-超滤深度处理工艺水厂为研究对象,对工艺过程中三氯乙醛生成潜能(CHFP)及相关有机物指标进行为期1年每月1次的监测,以明晰活性炭-超滤深度处理工艺对CHFP及有机物的去除能力。结果表明:原水CHFP均呈现一定的季节性变化趋势,高温季节(5—9月)相对较高,范围为15.50~64.00 μg·L-1,活性炭-超滤深度处理工艺对CHFP 、TOC、CODMn和UV254去除率范围分别为37.42%~69.12%、25.25%~66.71%、27.33%~61.25%和21.80%~72.46%,平均去除率分别为54.51%、39.21%、45.04%和42.91%;混凝沉淀单元在CHFP和有机物指标去除中均起主要作用,炭滤单元对TOC有较好的去除作用,超滤单元对CHFP和CODMn有较好的去除作用。建议水厂设计与运行中将臭氧与活性炭滤池联合使用,以协同去除CHFP和有机物,进一步提高供水水质。

English Abstract






全文HTML

--> --> --> 参考文献 (22)
相关话题/工艺 深圳 哈尔滨工业大学 指标 污染

Free考研考试FreeKaoYan.Com
欢迎来到Free考研考试,"为实现人生的Free而奋斗"

© 2020 FreeKaoYan! . All rights reserved.