厌氧膜生物反应器中亲疏水性有机物的膜污染特征

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摘要

采用树脂吸附脱附的方法对厌氧膜生物反应器（AnMBR）中溶解性微生物代谢产物（SMP）的6种亲疏水性有机物进行了分离，其中，亲水中性物质是SMP的主要成分，占总有机物的74.84%.多糖、蛋白质和腐殖质类物质在亲疏水性有机物中均有分布.采用恒压死端过滤的方式对比分析了6种亲疏水性有机物的微滤特性，发现在TOC浓度相同的条件下，亲水性碱（HIB）是造成膜通量下降最快的物质，其次是亲水中性物（HIN）和疏水性酸（HOA），膜通量下降速率与有机物平均粒径呈指数相关关系（R²=0.9965）.采用过滤模型对微滤过程进行拟合，HOA、HIN和HIB的过滤过程分别符合标准堵塞模型、中间过滤模型和滤饼过滤模型的特征，与其粒径分布特征相对应.试验进一步对比了亲疏水性有机物污染层的可逆性，结果表明HIN造成的膜污染不易通过物理反冲洗得到恢复.

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关键词 ：厌氧膜生物反应器, 溶解性微生物代谢产物, 亲疏水性有机物, 膜污染, 微滤特性, 粒径

Abstract：

In this study, the soluble microbial product (SMP) in an anaerobic membrane bioreactor (AnMBR) was fractionated into six kinds of hydrophilic or hydrophobic fractions through a sequence of adsorption/desorption using DAX-8, Amberlyst^® 15 and Amberlyst^® A21 resins. The hydrophilic neutrals (HIN) was found to be the major component in the SMP, accounting for 74.84% in terms of the total organic carbon (TOC). Polysaccharides, protein, and humic substrates were identified in all the six types of organic fractions. In order to further understand the membrane fouling mechanism of different organic fractions, the fouling propensity was evaluated through a series of batch microfiltration experiments with a stirred dead-end filtration cell under constant pressure. The membrane suffered a quickest flux decline with the hydrophilic base (HIB) solution, next came the HIN solution and hydrophobic acid (HOA) solution. An exponential correlation was found between the flux decreasing rate and mean particle size of the organics (R²=0.9965). Classic filtration models were employed for further analyses of the fouling evolution. The standard blocking, intermediate blocking and cake filtration models were found to fit the HOA, HIN, and HIB filtration behaviors, respectively. The irreversibility of membrane fouling caused by different organic matter was also investigated. The HIN-based fouling was found to be more difficult to be cleaned than other fouling types.

Key words： anaerobic membrane bioreactor soluble microbial product hydrophilic and hydrophobic organic matter membrane fouling microfiltration performance particle size

收稿日期: 2017-11-20

X703

基金资助:

北京市自然科学基金资助项目（8164073）；科技部中日合作课题（2016YFE0118500）

通讯作者: 文湘华,教授,xhwen@tsinghua.edu.cn E-mail: xhwen@tsinghua.edu.cn

作者简介: 余智勇(1986-),男,河北省保定人,博士,主要从事水污染控制技术研究.发表论文10余篇.

引用本文:

余智勇, 文湘华. 厌氧膜生物反应器中亲疏水性有机物的膜污染特征[J]. 中国环境科学, 2018, 38(7): 2471-2476. YU Zhi-yong, WEN Xiang-hua. Fouling of microfiltration membranes by hydrophilic and hydrophobic organic fractions in Anaerobic membrane bioreactors. CHINA ENVIRONMENTAL SCIENCECE, 2018, 38(7): 2471-2476.

链接本文:

http://www.zghjkx.com.cn/CN/ 或 http://www.zghjkx.com.cn/CN/Y2018/V38/I7/2471

[1]	许颖,夏俊林,黄霞.厌氧膜生物反应器污水处理技术的研究现状与发展前景[J]. 膜科学与技术, 2016,36(4):139-149.
[2]	Jarusutthirak C, Amy G. Role of soluble microbial products (SMP) in membrane fouling and flux decline[J]. Environmental Science and Technology, 2006,40:969-974.
[3]	Yu Z Y, Song Z H, Wen X H, et al. Using polyaluminum chloride and polyacrylamide to control membrane fouling in a cross-flow anaerobic membrane bioreactor[J]. Journal of Membrane Science, 2015,479:20-27.
[4]	孙楠,谌燕丽,张颖.投加HCPA对UF-MBR处理低温高色高氨氮水源水效能与膜污染控制的影响[J]. 中国环境科学, 2017,37(4):1339-1348.
[5]	Villamil J A, Monsalvo V M, Lopez J, et al. Fouling control in membrane bioreactors with sewage-sludge based adsorbents[J]. Water Research, 2016,105:65-75.
[6]	赵飞,许柯,任洪强,等.XDLVO理论解析有机物和钙离子对纳滤膜生物污染的影响[J]. 中国环境科学, 2015,35(12):3602-3611.
[7]	Zhou S Q, Shao Y S, Gao N Y, et al. Influence of hydrophobic/hydrophilic fractions of extracellular organic matters of Microcystis aeruginosa on ultrafiltration membrane fouling[J]. Science of The Total Environment, 2014,470-417:210-207.
[8]	苗瑞,王磊,田丽,等.海藻酸及腐殖酸共存对PVDF超滤膜的污染行为[J]. 中国环境科学, 2014,34(10):2568-2574.
[9]	Jacquin C, Teychene B, Lemee L, et al. Characteristics and fouling behaviors of Dissolved Organic Matter fractions in a full-scale submerged membrane bioreactor for municipal wastewater treatment[J]. Biochemical Engineering Journal, 2018,132:169-181.
[10]	Ding Y, Tian Y, Li Z P, et al. A comprehensive study into fouling properties of extracellular polymeric substance (EPS) extracted from bulk sludge and cake sludge in a mesophilic anaerobic membrane bioreactor[J]. Bioresource Technology, 2015,192:105-114.
[11]	Wei D Q, Tao Y, Zhang Z H, et al. Effect of pre-ozonation on mitigation of ceramic UF membrane fouling caused by algal extracellular organic matters[J]. Chemical Engineering Journal, 2016, 294:157-166.
[12]	Shen Y X, Zhao W T, Xiao K, et al. A systematic insight into fouling propensity of soluble microbial products in membrane bioreactors based on hydrophobic interaction and size exclusion[J]. Journal of Membrane Science, 2010,346:187-193.
[13]	Chefetz B, Hatcher P G, Hadar Y, et al. Characterization of dissolved organic matter extracted from composted municipal solid waste[J]. Soil Science Society of America Journal, 1998,62(2):326-332.
[14]	Leenheer J A. Comprehensive approach to preparative isolation and fractionation of dissolved organic carbon from natural wasters and wastewaters[J]. Environmental Science and Technology, 1981,15(5):578-587.
[15]	Bowen W R, Calvo J I, Hernández A. Steps of membrane blocking in flux decline during protein microfiltration[J]. Journal of Membrane Science, 1995,101:153-165.
[16]	Frølund B, Palmgren R, Keiding K, et al. Extraction of extracellular polymers from activated sludge using a cation exchange resin[J]. Water Research, 1996,30(80):1749-1758.
[17]	Wang Z W, Mei X J, Wu Z C, et al. Effect of biopolymer discharge from MBR mixture on sludge characteristics and membrane fouling[J]. Chemical Engineering Journal, 2012,193-194:77-87.
[18]	Fan L H, Harris J L, Roddick F A, et al. Influence of the characteristics of natural organic matter on the fouling of microfiltration membranes[J]. Water Research, 2001,35(10):4455-4463.
[19]	Carroll T, King S, Gray S R, et al. The fouling of microfiltration membranes by NOM after coagulation treatment[J]. Water Research, 2000,34(11):2861-2868.
[20]	王磊,李松山,苗瑞,等.Mg2+对腐殖酸在EVOH膜面微观作用过程的影响[J]. 中国环境科学, 2017,37(4):1380-1385.
[21]	Kim H C, Dempsey B A. Removal of organic acids from EfOM using anion exchange resins and consequent reduction of fouling in UF and MF[J]. Journal of Membrane Science, 2010,364:325-330.
[22]	Lyko S, Wintgens T, Al-Halbouni D, et al. Long-term monitoring of a full-scale municipal membrane bioreactor-characterisation of foulants and operational performance[J]. Journal of Membrane Science, 2008, 317:78-87.
[23]	Gray S R, Ritchie C B, Bolto B A. Effect of fractionated NOM on low-pressure membrane flux declines[C]//3rd International Conference on Natural Organic Material Research, 2014, March, 02-05.