浸没式超滤膜替代砂滤处理东江水的中试研究

针对传统饮用水处理工艺的升级改造问题,通过中试实验,系统考察浸没式超滤膜替代砂滤处理东江水的出水水质并研究高通量条件下的膜运行条件。结果表明,浸没式超滤膜出水浊度不受原水水质条件影响,均保持在0.1 NTU以下,与砂滤出水相比具有优势,但有机物去除率与砂滤相差不大。膜系统在高通量条件下运行时,过滤周期应作适当的缩短,采用合理的物理清洗来缓解膜污染,并辅助以有效的在线化学清洗可保证膜过滤的长期稳定运行。     

Performance investigation of membrane bioreactor systems during municipal wastewater reclamation.

Four commercially available membrane bioreactor (MBR) systems were operated at the pilot scale, to investigate performance during the reclamation of municipal wastewater. The MBR performance was evaluated under a variety of operating conditions, including two types of feed wastewater (raw and advanced primary effluent), hydraulic retention times (HRTs) ranging from 2 to 6 hours, and permeate fluxes between 20 and 41 lmh. Test results showed that MBR systems were capable of operating on advanced primary effluent, despite the possible presence of coagulant and/or polymer residual, with minimal membrane fouling. Membrane performance data generated during this study was also used to quantify the relationship between permeate flux and membrane fouling. Cleaning intervals at various flux conditions were estimated as follows: 69 days at 20 lmh, 58 days at 25 lmh, and 30 days for operation between 31 and 41 lmh. It was also demonstrated that the MBR process could be optimized to operate with minimal fouling under high hydraulic (flux = 37 lmh) and organic loading (HRT = 2 hours and food-to-microorganism ratio = 0.33 g COD/g VSS x d) conditions. Water quality monitoring conducted throughout the study showed that each MBR system consistently produced an oxidized (5-day biochemical oxygen demand < 2 mg/L) and nitrified (ammonia < 1 mg-N/L) effluent low in particulate matter (turbidity < 0.1 NTU), under all conditions tested.     

应用于维生素C凝结水处理反渗透膜清洗策略

针对沈阳某药厂维生素C生产工艺中凝结水产量大、处理成本高和杂质复杂等问题,提出了采用反渗透技术对工艺凝结水进行处理。在前期确定的最优操作条件基础上持续运行,研究了运行临界通量、清洗时机和清洗方式等工艺条件。结果表明,在本工艺条件下,反渗透膜系统的临界通量介于1.1 L/(m2.min)到1.2 L/(m2.min)之间,斜率变点分析法确定的可逆膜污染周期为10 d;加强型清洗策略EFM(enhanced flux maintenance)的操作是针对不可逆膜污染的一种有效清洗方式,EFM持续30 min为宜,NaClO和NaOH都是有机污染的有效清洗剂,膜的平均恢复率分别为85.4%和81.6%,显示出实际应用的可行性,具有推广价值。     

不同工艺再生水补给对景观湖水质变化的影响

再生水回用于景观水体过程中,为了比较不同再生水工艺对景观水体富营养化的影响,以"二级出水+BAF+O3+GFH"和"二级出水+O3"作为再生水处理工艺,以岸滤(bank filtration,BF)作为水质维持工艺,进行再生水景观水体水质保障技术研究。结果表明,"二级出水+O3"出水流量较大,水力流动快,每天运行24 h,平均出水流量25.5 m3/d,氮磷含量偏高;"二级出水+BAF+O3+GFH"出水的氮磷指标控制在较低水平,GFH出水流量8～14 m3/d,水力流动较缓,湖中出现蓝藻。2套系统中BF对NH4+-N的去除率分别为30.5%和20.8%。"二级出水+O3+BF"系统中人工湖进水TN平均浓度24.309 mg/L,TP平均浓度0.583 mg/L,N/P=41,适宜水网藻生长,对湖中N(主要是NH4+-N)、P有较强的去除能力;"二级出水+BAF+O3+GFH+BF"系统中人工湖进水TP<0.05 mg/L,适宜蓝藻生长。     

生活垃圾填埋场渗滤液处理工程实例分析

本文通过实例阐述了“混凝沉淀+两级A/O(缺氧/好氧)-MBR系统(膜生物反应器)+SWRO(海水淡化反渗透)”组合工艺在生活垃圾渗滤液处理中的应用。实际运行结果表明,当进水平均COD浓度为2668.7 mg/L、NH₃-N质量浓度为2910 mg/L时,出水平均COD浓度为7.6 mg/L、NH₃-N质量浓度为1.9 mg/L,水质可满足《生活垃圾填埋场污染控制标准》(GB16889-2008)要求,运行成本合计约为60元/m³.本工程实例将为我国生活垃圾填埋场渗滤液处理提供技术支持与经验参考。     

PVDF/PMMA与PVDF/TPU共混膜抗污染性能研究及应用

观察新型五孔PVDF共混改性纤维膜SEM形貌特征,采用逐级通量法测定PVDF/PMMA和PVDF/TPU共混改性膜的临界通量,研究在次临界和超临界通量下A(PVDF/PMMA)与B(PVDF/TPU)2种管式膜组件的过滤和抗污染性能,并在次临界通量下处理地表水。结果表明,PVDF共混改性膜具有优良的微观结构,且膜B性能较好;膜A、B的临界通量分别为12 L/(m2.h)和10 L/(m2.h);膜组件B比膜组件A抗污染性能好。次临界通量下膜组件的运行比超临界通量下的稳定。与采用单独超滤处理某市地表水相比,2种膜组件采用混凝+超滤工艺的运行处理效果更好,且膜组件B比膜组件A处理效果佳。     

MFC-MBR耦合系统运行效果

膜生物反应器(MBR)是一种高效的污水处理工艺,而微生物燃料电池(MFC)能有效降解污泥中的胞外生物有机质(EBOM)并回收电能.将MFC与MBR联用,建立了一套能够有效抑制膜污染同时回收电能的新系统——MFC-MBR耦合系统,MBR的剩余污泥经MFC处理后回流.以传统MBR为对照,对耦合系统中污水处理效果、膜污染情况和污泥混合液的性质进行研究.研究表明,耦合系统的污水处理效果没有明显恶化,COD去除率为94％,NH4+-N的去除率为92％.耦合系统能够有效减缓膜污染的发生,清洗周期延长了28％.污泥混合液的MLVSS/MLSS稳定在80％ ～ 88％,系统内几乎没有无机颗粒积累.松散结合态胞外聚合物(LB-EPS)降低了48％,使污泥混合液性质得到改善.较低的污泥比阻(2.69×1012m/kg)和标准化毛细吸水时间(1.67 s·L/g MLSS),证明耦合系统污泥混合液脱水性能提高了.     

印染废水回用微滤膜污染控制研究

采用PVDF中空纤维微滤膜处理某纺织印染厂二级生化出水,研究了膜污染控制及清洗方法。结果表明,合理的膜通量是控制膜污染、保证膜寿命的关键,采用31 L/(m2.h)左右的通量有助于膜污染的控制。氢氧化钠与次氯酸钠可分别用于日常维护清洗与恢复清洗,通过循环正洗不仅能满足清洗要求,且药剂使用量也小于反洗方法,每吨产水清洗用碱费用仅0.06元。化学清洗后再水力正洗,能进一步提高清洗效果。     

Irreversible fouling during multicycle microfiltration of wastewater effluent

This study focused on irreversible fouling during microfiltration of primary and secondary effluents from municipal wastewater treatment plants. Flow resistances were calculated from the sum of clean membrane resistances, resultant cake layer resistances, and consequent irreversible fouling resistances. Results from a dead-end cell experimental system showed that the accumulated cake resistance was dominating for microfiltration of primary/secondary effluents. Suspended solids in the primary and secondary effluents had a similar compressibility index, n, with a value of approximately 0.5, indicating that they were moderately compressible particles. The value of irreversible resistance is dependent on the intensity of membrane cleaning; however, for a given membrane cleaning strategy, this value steadily increased and reached a maximum after approximately 6 cycles of filtration and cleaning. This study provided an explanation for the significant drop of throughput flux in the early application of membrane processes, and a plateau flux approached correspondingly.     

The recovery of copper from a copper mine effluent in a hybrid flotation/microfiltration cell

A new hybrid process for cleaning wastewater, combining flotation and membrane microfiltration, was investigated. The hybrid process combined the advantages of both flotation and membrane separation: the flotation cell removed a large proportion of suspended solid particles, while the membrane module produced clean water permeate effluent. The hybrid cell performance has been studied in depth and reviewed in the current paper. The proof of concept for the hybrid solid/liquid separation process was investigated using an aqueous suspension of fine and ultra fine particles (synthetic adsorbents, ion exchangers). The feasibility of this combined process was investigated in the recovery of metal cations (copper) from a Bulgarian copper mine effluent.     

印染生化尾水反渗透深度处理工艺膜污染成因分析简

为阐明印染生化尾水反渗透膜处理时膜污染的成因,使用小试装置进行40 h膜污染实验,研究膜污染速率、污染程度以及可逆性,同时应用扫描电子显微镜-EDS能谱仪、傅里叶变换红外光谱仪、电感耦合等离子发射光谱仪、总有机碳测定仪等仪器对进水水质、膜表面污染物的形态和组成等进行表征。结果表明,膜表面主要是碳酸钙无机污染和钙与有机物络合污染,无机污染占主导,且可逆性差,有机污染物主要含有—OH和—CC官能团;单一去除废水中有机物污染物（TOC去除率达88%）对膜污染缓解不明显,但钙离子的去除可显著缓解膜污染,膜通量可增加72.6%;同时去除有机物和钙离子,膜通量可增加80.4%。     

膜蒸馏处理糖精钠生产废水

采用直接接触式膜蒸馏(DCMD)工艺处理糖精钠生产废水。分析了经过活性炭吸附预处理前后,膜蒸馏连续循环运行的效果。实验结果表明,未经预处理的废水在膜蒸馏过程中,废水中所含有机物不仅导致膜材料的润湿,引起产水电导率升高及膜孔润湿,促进盐晶体在膜表面附着,使产水通量下降。经吸附预处理后,膜蒸馏过程中产水通量介于10.40～11.24 kg/(m2.h)。吸附预处理能有效减缓产水通量的衰减,提高产水水质。废水经过活性炭预处理后进行膜蒸馏浓缩处理,当浓缩倍数达到5倍时,通量保持在10.55 kg/(m2.h)左右;产水水质稳定,截留率在99.5%以上。研究结果表明,吸附-膜蒸馏工艺可以应用于糖精钠生产废水的回用处理,有明显的应用前景。     

Analyzing the uncorrected error of dilution water demand for the dilution biochemical oxygen demand method.

Dilution water demand (DWD) can cause a positive error when the dilution biochemical oxygen demand (BOD) method is used. Dilution water demand may be attributed to oxidation of organic impurities in the dilution water and nitrification of ammonia added as a nutrient. To minimize the error associated with these sources, the standard BOD method requires that DWD be less than 0.2 mg/L in 5 days and does not allow correction for DWD when calculating test results. This study derives a set of theoretical equations to analyze the uncorrected errors with and without seeding. The authors concluded that DWD can be completely corrected if seeded dilution water is used for the sample dilution. When seeding individual bottles, the uncorrected error approaches 8.3 to approximately 8.8% at a 5-day depletion of 2 mg/L for a typical secondary effluent. Tests without seeding show an almost 1% higher uncorrected error than seeded tests. The analysis also suggests that these errors can be effectively reduced to less than 3% when the 5-day depletion approaches 6 mg/L. even for 5-day biochemical oxygen demand concentrations exceeding I x 10(4) mg/L. Further analysis indicates that, if not inhibited, the ammonium added to dilution water as a nutrient may contribute additional error due to nitrification.     

印染生化尾水反渗透深度处理工艺膜污染成因分析

为阐明印染生化尾水反渗透膜处理时膜污染的成因,使用小试装置进行40h膜污染实验,研究膜污染速率、污染程度以及可逆性,同时应用扫描电子显微镜一EDS能谱仪、傅里叶变换红外光谱仪、电感耦合等离子发射光谱仪、总有机碳测定仪等仪器对进水水质、膜表面污染物的形态和组成等进行表征。结果表明,膜表面主要是碳酸钙无机污染和钙与有机物络合污染,无机污染占主导,且可逆性差,有机污染物主要含有--OH和～c-c官能团;单一去除废水中有机物污染物（TOC去除率达88％）对膜污染缓解不明显,但钙离子的去除可显著缓解膜污染,膜通量可增加72．6％;同时去除有机物和钙离子,膜通量可增加80．4％。     

好氧颗粒污泥动态膜生物反应器工艺参数及运行性能

以一体式尼龙筛网动态膜生物反应器(DMBR)为研究体系,与好氧颗粒污泥相结合,形成新的好氧颗粒污泥动态膜生物反应器(AGDMBR),探讨了在新工艺条件下对COD、氨氮的去除,以及出水浊度的变化,与活性污泥动态膜生物反应器(DMBR)做比较,研究了进水流量、曝气量等工艺运行参数与膜污染之间的关系,并对系统中污泥的EPS进行分析。结论表明,AGDMBR系统对COD和NH4+-N的平均去除率分别为91%和95%,出水浊度为6 NTU,处理效果均优于DMBR系统;AGDMBR系统在运行过程中膜污染速度随进水流量的增大而加快;曝气量为125～150 L/h时,膜通量持续时间最长;AGDMBR系统比DMBR系统在膜污染的延缓上具有明显的优势。     

A/O-MBR中MLSS浓度对污泥性能及膜通量的影响

采用国产聚丙烯中空纤维帘式膜组件,进行了A/O-MBR系统处理生活污水的实验研究,主要探讨了系统中污泥浓度(MLSS)与膜通量变化过程的关系。实验结果表明,MLSS由3 805 mg/L升高到6 912 mg/L时,污泥混合液胞外聚合物(EPS)由43 mg/g VSS增加到81 mg/g VSS,EPS中多糖与蛋白质的比例从0.87增加到1.08。同时,污泥相对疏水性(RH)的降低与Zeta电位的升高也在一定程度上共同促进了膜污染速率的上升。实验条件下,当运行时间为60 d左右,MLSS升高至6 200 mg/L时,跨膜压差上升迅速,膜组件清洗周期由初始的22 d缩短为11 d。A/O-MBR中由于MLSS浓度变化而导致的活性污泥混合液特性的变化,是影响膜通量变化的重要原因。     

A2／O-MBR工艺处理低负荷污水并回用

将A2／O生物处理单元与MBR相结合构建了的处理能力为2000m3／d的A2／O—MBR工艺,并应用于缺水地区校园生活污水的处理与回用。该系统运行稳定,运行阶段的实验结果表明,在进水COD为100-200mg／L、NH4＋-N为19～33mg／L、TN为25-43mg／L、TP为35mg／L和低碳氮比的情况下,出水水质优于《城市污水再生利用城市杂用水水质》（GB／T18920-2002）的要求,且全部用于杂用及校园绿化等。经分析该工艺运行成本为0．96元／m3,每年可节省自来水73万t,获得较好的环境效益与经济效益。     

铁炭微电解-Fenton氧化-A/A/O生化等联合工艺处理酚类、硝基苯类废水的探讨

采用酸化沉淀-超滤-铁炭微电解-Fenton氧化-混凝沉淀-A/A/O生化处理等联合工艺处理酚类、硝基苯类废水。设计处理水量:物化预处理2 m^3/h、生化处理3 m^3/h。运行结果表明,该工艺处理效果良好,出水pH6~9,COD≤500 mg/L,SS≤400 mg/L,NH3-N≤50 mg/L,TP≤2 mg/L,酚类≤0.5 mg/L,硝基苯类≤2,盐分≤5000 mg/L,出水水质优于设计指标要求。     

A2O-MBR工艺处理城市污Z作农业灌溉用水中试研究

为开发一种污水再生利用于农田灌溉领域的新型技术,本实验以城市污水为研究对象,采用A2O—MBR工艺进行中试研究,并将系统出水水质与《农田灌溉水质标准（GB5084—2005）》的主要水质指标进行对比分析。结果表明,系统COD和BOD,出水浓度范围分别为3．2～59．6mg／L、1．0～7．6mg／L,系统出水pH为7．16～7．54,悬浮物浓度几乎为0,上述指标均符合标准;TP、TN和氨氮的出水范围分别为0．03～0．79mg／L、1．6～17．7mg／L和0．8～10．3mg／L。《农田灌溉水质标准》没有对上述3个指标提出具体要求,且少量的氮磷是植物生长的营养元素。该系统出水的主要水质指标符合标准兽求．     

纳滤膜在垃圾渗滤液深度处理中应用

利用纳滤膜技术处理MBR二级处理后出水,研究纳滤膜在垃圾渗滤液应用中回收率及进出水COD变化情况。工程试验结果表明:当MBR出水COD小于800 mg/L～900 mg/L,纳滤膜出水COD小于100 mg/L;纳滤系统直通式运行回收率40%～50%;内循环式运行回收率75%～80%,浓缩段回收率9.3%～11.8%,总回收率80.4%～82.0%;根据膜面运行流速要求,进膜的流量需大于8 m3/h;进膜压力、进水流量和循环流量是影响膜通量大小的关键因素。