PDF下载

[1]宋欣,李燕君,黄慧,等.臭氧-上向流BAC工艺对常规及新污染物的控制效果[J].中国给水排水,2024,40(3):1-8.
　SONGXin,LIYan-jun,HUANGHui,et al.Control of Conventional and Emerging Contaminants by Ozone-Upflow Biological Activated Carbon Process[J].China Water & Wastewater,2024,40(3):1-8.

点击复制

臭氧-上向流BAC工艺对常规及新污染物的控制效果

中国给水排水[ISSN:1000-4062/CN:12-1073/TU] 卷: 第40卷期数: 2024年第3期页码: 1-8 栏目: 出版日期: 2024-02-01

Title:: Control of Conventional and Emerging Contaminants by Ozone-Upflow Biological Activated Carbon Process

作者:: 宋欣¹，李燕君²，黄慧¹，刘奋强¹，许钊¹，王延益²，杨锴³，张锡辉²; （1.深圳市深水龙华水务有限公司，广东深圳 518100；2.清华大学深圳国际研究生院，广东深圳 518055；3.广东省广业装备制造集团有限公司，广东广州 510275）

Author(s):: SONG　Xin¹， LI　Yan-jun²， HUANG　Hui¹， LIU　Fen-qiang¹， XU　Zhao¹， WANG　Yan-yi²， YANG　Kai³， ZHANG　Xi-hui²; （1. Shenzhen Shenshui Longhua Water Co. Ltd.， Shenzhen 518100， China； 2. Shenzhen International Graduate School， Tsinghua University， Shenzhen 518055， China； 3. Guangdong Guangye Equipment Manufacturing Group Co. Ltd.， Guangzhou 510275， China）

关键词:: 自来水厂; 深度处理; 臭氧-上向流生物活性炭; 可同化有机碳; 嗅味物质; 新污染物

Keywords:: water treatment plant; advanced treatment; ozone-upflow biological activated carbon; AOC; odorous substances; emerging contaminants

摘要:: 为了解“臭氧-上向流生物活性炭”深度处理工艺对新污染物及其他痕量污染物的去除效果，对深圳市某深度处理水厂进行了为期一年的调研与监测。结果表明，该深度处理工艺可以有效去除常规污染物，在一年的监测期内，其出水COD_Mn、TOC与氨氮的平均浓度分别为0.49、0.9、0.014 mg/L。荧光类有机物主要由深度处理工艺去除，去除率在50%以上；同时，可将生物可同化有机碳（AOC）的去除率从常规工艺的11.4%提升至41.4%，但在检测期内出厂水的AOC均不能满足生物稳定性要求。经深度处理后，出厂水中二甲基三硫醚（DMTS）、2-甲基异莰醇（2-MIB）和土臭素（GSM）均能满足深圳市饮用水标准要求。“臭氧-上向流生物活性炭”深度处理工艺对37种药品及个人护理品（PPCPs）和8种内分泌干扰物（EDCs）具有较好的去除效果，平均去除率分别为85.9%和80.4%，有效控制了新污染物对人体健康造成的风险，但出水炔雌醇风险熵值仍远高于高风险限值（冬季为27.7，夏季为169.6），需要重点关注。

Abstract:: In order to understand the removal effect of advanced treatment processes on emerging pollutants and other trace pollutants, a one-year investigation and monitoring was conducted on the ozone-upflow biological activated carbon (O₃-BAC) process of a advanced treatment water plant in Shenzhen City. The results indicated that the advanced treatment process could effectively remove conventional pollutants, with average concentrations of COD_Mn, TOC, and ammonia nitrogen in the effluent being 0.49 mg/L, 0.9 mg/L, and 0.014 mg/L, respectively. Fluorescent organic compounds were mainly removed by the advanced treatment process, with a removal rate of over 50%. The advanced treatment process could improve the removal rate of assimilable organic carbon (AOC) from 11.4% in conventional processes to 41.4%, but the AOC in the effluent did not meet the biological stability requirements during the monitoring period. After advanced treatment, the effluent concentrations of DMTS, 2-MIB and GSM met Shenzhen’s drinking water standard. The O₃-BAC process demonstrated good removal efficiency for 37 PPCPs and 8 EDCs, with average removal rates of 85.9% and 80.4%, respectively. The advanced treatment process could effectively control the risk of emerging contaminants on human health, but the risk entropy value of estrone in the effluent was still much higher than the high-risk limit value (27.7 in winter and 169.6 in summer), which required special attention.

相似文献/References:

[1]黄仲均,刘佳伟.基于一体化净水装置的自来水厂改造扩能案例分析[J].中国给水排水,2018,34(22):82.
　HUANG Zhong-jun,LIU Jia-wei.Reconstruction and Expansion Design of Waterworks Based on Integrated Water Purification Device[J].China Water & Wastewater,2018,34(3):82.
[2]刘彦华,苏锡波,高迎亮,等.城镇自来水厂平流沉淀池改造技术与实践[J].中国给水排水,2020,36(14):131.
　LIU Yan-hua,SU Xi-bo,GAO Ying-liang,et al.Renovation Technology and Practice of Horizontal Flow Sedimentation Tank in Urban Waterworks[J].China Water & Wastewater,2020,36(3):131.
[3]李丰庆.我国超大超滤水厂——广州北部水厂工艺设计[J].中国给水排水,2021,37(10):66.
　LI Feng-qing.Process Design of the Super Large Ultrafiltration Waterworks in China: Guangzhou Beibu Waterworks[J].China Water & Wastewater,2021,37(3):66.
[4]赵新娟,刘伯一.短流程超滤膜工艺在凌庄水厂的应用[J].中国给水排水,2021,37(10):71.
　ZHAO Xin-juan,LIU Bo-yi.Application of Short Process Ultrafiltration Membrane in Lingzhuang Waterworks[J].China Water & Wastewater,2021,37(3):71.
[5]黄孟斌,武洋,王梅芳,等.深圳长流陂水厂网格絮凝池提升改造应用实践[J].中国给水排水,2021,37(12):116.
　HUANG Meng-bin,WU Yang,WANG Mei-fang,et al.Application Practice of Grid Flocculation Tank Upgrading and Reconstruction in Shenzhen Changliupi Waterworks[J].China Water & Wastewater,2021,37(3):116.
[6]何嘉莉,袁耀芬,周沛良,等.自来水厂混凝剂自动精准投加系统建设与运行[J].中国给水排水,2021,37(18):139.
　HE Jia-li,YUAN Yao-fen,ZHOU Pei-liang,et al.Construction and Operation of Automatic and Accurate Coagulant Dosing System in Waterworks[J].China Water & Wastewater,2021,37(3):139.
[7]杨存满,鞠佳伟,袁芳,等.基于PSO-BP神经网络的水厂智能消毒预测模型[J].中国给水排水,2022,38(3):57.
　YANGCun-man,JUJia-wei,YUAN Fang,et al.Research on Intelligent Disinfection Prediction Model of Waterworks Based on PSO-BP Neural Network[J].China Water & Wastewater,2022,38(3):57.
[8]常尧枫,谢嘉玮,谢军祥,等.城镇污水处理厂提标改造技术研究进展[J].中国给水排水,2022,38(6):20.
　CHANGYao-feng,XIEJia-wei,XIEJun-xiang,et al.Research Progress on Upgrading and Reconstruction Technology of Urban Sewage Treatment Plants[J].China Water & Wastewater,2022,38(3):20.
[9]陈仁杰,刘明辉,丁陈龙,等.基于水厂砂滤填料附着物的BAF启动及其硝化性能[J].中国给水排水,2022,38(8):25.
　CHENRen-jie,LIUMing-hui,DINGChen-long,et al.Startup of Biological Aerated Filter Seeded with Attached Microbes from Sand Filter in a Waterworks and Its Nitrification Performance[J].China Water & Wastewater,2022,38(3):25.
[10]赵志太,李建,孔晓光,等.新型气浮设备去除污水厂二沉池出水TP和SS中试[J].中国给水排水,2022,38(9):18.
　ZHAOZhi-tai,LIJian,KONGXiao-guang,et al.Removal of TP and SS from Effluent of Secondary Sedimentation Tank with Novel Air Flotation Equipment[J].China Water & Wastewater,2022,38(3):18.

更新日期/Last Update: 2024-02-01