采用超滤膜( UF)为核心,以混凝作为预处理措施,对混凝?超滤工艺处理径流雨水的特性和膜通量变化与污染现象进行了研究,并对聚合硫酸铁( PFS)单独混凝、UF、PFS?UF组合工艺进行了对比;在优化混凝基础上,考察了混凝?UF 对常规水质指标及总磷、生物可同化有机碳( AOC )、可生物降解溶解性有机碳( BDOC)等生物稳定性指标的去除效果.结果表明,混凝可有效去除TOC、UV254和总磷,混凝剂投加量与污染物去除近似呈线性关系.各混凝剂除浊效能均良好.综合考虑混凝处理效率与经济性,实验采用混凝方案为10 mg·L-1的PFS.PFS、UF、PFS?UF工艺除浊率均在95%以上,PFS和UF对TOC和UV254的去除较为接近,采用PFS?UF可提高去除率13%—15%;PFS?UF 处理后雨水的 AOC、BDOC 分别降低至61.8μg·L-1、0.19 mg·L-1,残余总磷可降至3.8μg·L-1,雨水生物稳定性明显提高.PFS、UF和PFS?UF对颗粒物的去除率分别达80.5%、99.6%和99.9%.膜通量的变化和SEM图分析表明,混凝在一定程度上减轻了UF膜污染;形成的凝胶层具有一定整体强度,水力清洗时易于清除,膜通量恢复较好;但同时凝胶层的产生也增大了透膜阻力, PFS?UF工艺的周期内膜通量衰减有增加的趋势.
As an available water resource, rainwater has drawn growing concerns. UF membrane was adopted as a core technique and coagulation as a pretreatment process in this study. The characteristic of purification and the variation of membrane flux were studied, and PFS, UF, PFS?UF process were compared. Removal of routine water indexes and biological stability indexes such as phosphorus, AOC, BDOC was examined on the basis of coagulation optimization. Results indicated that coagulation was efficient to remove TOC, UV254 and phosphorus. There was a linear dependence between the coagulant dosage and removal efficiency. Turbidity could be eliminated efficiently by AS, PAC and PFS. 10 mg·L-1 PFS was considered as the preferable coagulation scheme in this study. Removal of turbidity was above 95% using PFS, UF, PFS?UF. A similar removal rate of TOC and UV254 was achieved by PFS and UF process respectively. But in PFS?UF process it increased by 13% to 15%. AOC and BDOC was cut down to 61.8μg·L-1 and 0.19 mg·L-1 , which contributed to biological stability considerably. Removal of particulate matters by PFS, UF and PFS?UF was 80?5%, 99. 6% and 99. 9%, respectively. The variation of membrane flux and SEM experiments stated that coagulation eased the contamination of UF membrane. The formed gel layer had a certain strength and was removed easily by backwash, which was propitious to the recovery of membrane flux. But the resistance was accreted and the attenuation of membrane flux was accelerated also.
参考文献
| [1] | Seyed M;Seyed S;Amin R .Optimization of operating conditions in ultrafiltration process for produced water treatment via the full factorial design methodology[J].Separation and purification technology,2014,132(20):50-61. |
| [2] | 罗慧英,丘玉蓉,王耀堂,赵世明,赵昕,高峰,钱江峰.广州亚运村杂用水专项研究--雨水综合利用[J].给水排水,2008(05):70-78. |
| [3] | 徐钟骏,刘晋民.上海世博会伦敦案例馆展示的雨水利用技术案例分析[J].净水技术,2012(03):36-39. |
| [4] | 杜欣,李波,孙钢.节水及水资源利用技术在三星级绿色建筑设计中的应用--以都江堰大熊猫疾控中心为例[J].给水排水,2013(11):64-68. |
| [5] | 王立存,张文杰,牛俊怡.天津滨海新区某建筑区雨水利用实例[J].中国给水排水,2013(04):43-46. |
| [6] | 尹滔.昆明呈贡白龙潭B地块的市政道路雨水利用措施[J].中国给水排水,2011(24):64-67. |
| [7] | 邓卓智,赵生成,宗复破,冯永忠.基于水体自然净化的北京奥林匹克公园中心区雨水利用技术[J].给水排水,2008(09):96-100. |
| [8] | 顾正斌,侯毅凯,王慧勇.邯郸市城区雨水利用途径探索[J].水科学与工程技术,2006(06):12-14. |
| [9] | 董蕾,车伍,李海燕,李俊奇,何建平,汪宏玲,孟光辉.我国部分城市的雨水利用规划现状及存在问题[J].中国给水排水,2007(22):1-5. |
| [10] | Kyoung Hoon Chu;Sung Soo Yoo;Jae Young Ahn.Determining flux behavior via a modified flux-step method for surface water treatment: pilot-scale ultrafiltration membrane operation[J].Desalination: The International Journal on the Science and Technology of Desalting and Water Purification,2014:19-26. |
| [11] | Langming Bai;Fangshu Qu;Heng Liang.Membrane fouling during ultrafiltration (UF) of surface water: Effects of sludge discharge interval (SDI)[J].Desalination: The International Journal on the Science and Technology of Desalting and Water Purification,2013:18-24. |
| [12] | Nishi L;Salcedo Vieira A M;Fernandes Vieira M et al.Hybrid process of coagulation/flocculation with Moringa oleifera followed by ultrafiltration to remove Microcystis sp. cells from water supply[J].Procedia Engineering,2012,42:865-872. |
| [13] | Karin Lautenschlager;Chiachi Hwang;Wen-Tso Liu;Nico Boon;Oliver Koester;Hans Vrouwenvelder;Thomas Egli;Frederik Hammes .A microbiology-based multi-parametric approach towards assessing biological stability in drinking water distribution networks[J].Water research: A journal of the international water association,2013(9):3015-3025. |
| [14] | E.I. Prest;F. Hammes;S. Koetzsch;M.C.M. van Loosdrecht;J.S. Vrouwenvelder .Monitoring microbiological changes in drinking water systems using a fast and reproducible flow cytometric method[J].Water research: A journal of the international water association,2013(19):7131-7142. |
| [15] | Wijekoon K C;Hai F I;Kang J G et al.A novel membrane distillation-thermophilic bioreactor system:Biological stability and trace organic compound removal[J].BIORESOURCE TECHNOLOGY,2014,159:334-341. |
| [16] | Parinda Thayanukul;Futoshi Kurisu;Ikuro Kasuga;Hiroaki Furumai .Evaluation of microbial regrowth potential by assimilable organic carbon in various reclaimed water and distribution systems[J].Water research: A journal of the international water association,2013(1):225-232. |
| [17] | 鲁巍,唐峰,张晓健,何文杰,韩宏大,胡建坤.净水工艺对饮用水生物稳定性控制的研究[J].环境科学,2005(06):71-74. |
| [18] | Meiting Guo;Hongying Hu;Wenjun Liu .Preliminary investigation on safety of post-UV disinfection of wastewater: bio-stability in laboratory-scale simulated reuse water pipelines[J].Desalination: The International Journal on the Science and Technology of Desalting and Water Purification,2009(1/3):22-28. |
| [19] | 李欣,马建薇.生物可降解溶解性有机碳(BDOC)降解动力学研究[J].哈尔滨工业大学学报,2005(09):1183-1184,1199. |
| [20] | 刘文君;吴红伟;王占生 .饮用水中BDOC测定动力学研究[D].环境科学,1999. |
| [21] | 岳志芳 .混凝—沉淀—砂滤—超滤工艺对城市小区雨水处理与回用实验研究[D].兰州交通大学,2013. |
| [22] | 纪桂霞,王平香,邱卫国.上海市雨水径流水质监测与混凝沉淀试验研究[J].给水排水,2007(02):47-51. |
| [23] | 陈桂霞,胡承志,朱灵峰,童华卿.铝盐混凝除砷影响因素及机制研究[J].环境科学,2013(04):1386-1391. |
| [24] | 任刚,崔福义,林涛,安全.常规混凝沉淀工艺对阴离子表面活性剂的去除研究[J].给水排水,2004(07):1-6. |
| [25] | 王立立,刘焕彬,胡勇有,周勤.生活污水二级生物处理后的铁盐混凝除磷试验研究[J].环境污染与防治,2002(06):361-364. |
| [26] | Jia-yu Tian;Mathias Ernst;Fuyi Cui;Martin Jekel .Correlations of relevant membrane foulants with UF membrane fouling in different waters[J].Water research: A journal of the international water association,2013(3):1218-1228. |
| [27] | Heng Liang;Weijia Gong;Jie Chen .Cleaning of fouled ultrafiltration (UF) membrane by algae during reservoir water treatment[J].Desalination: The International Journal on the Science and Technology of Desalting and Water Purification,2008(1/3):267-272. |
| [28] | 刘成,高乃云,蔡云龙.强化混凝去除黄浦江原水中有机物研究[J].中国给水排水,2006(01):84-87. |
| [29] | 李爽,张晓健.优化混凝控制水中可生物降解有机物[J].中国给水排水,2003(04):39-41. |
| [30] | 方华 .饮用水生物稳定性和净水工艺对有机物去除的研究[D].东南大学,2006. |
| [31] | 马颖,龙腾锐,方振东.饮用水生物稳定性的评价体系[J].中国给水排水,2004(12):96-98. |
| [32] | J. Y. HU;Z. S. WANG;W. J. NG .THE EFFECT OF WATER TREATMENT PROCESSES ON THE BIOLOGICAL STABILITY OF POTABLE WATER[J].Water research: A journal of the international water association,1999(11):2587-2592. |
| [33] | Lauren A. Weinrich;Patrick K. Jjemba;Eugenio Giraldo;Mark W. LeChevallier .Implications of organic carbon in the deterioration of water quality in reclaimed water distribution systems[J].Water research: A journal of the international water association,2010(18):5367-5375. |
| [34] | V. Singh, C. Das.Comparison of spiral wound UF membrane performance between turbulent and laminar flow regimes[J].Desalination: The International Journal on the Science and Technology of Desalting and Water Purification,2014:43-51. |
| [35] | 方绪亮,何义亮,徐培.膜表面形貌对厌氧膜生物反应器膜污染影响的试验研究[J].环境化学,2006(01):65-68. |
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