叠式曝气生物滤池在给水预处理中的挂膜启动

针对低污染原水进行叠式曝气生物滤池的自然挂膜启动实验。在HRT为20～30 min,温度为28～33℃,气水比为0.5,滤速为12.5 m/h的条件下,研究分析叠式曝气生物滤池在自然挂膜启动过程中各项水质指标的变化情况与生物膜生长之间的相互关系,判断挂膜启动的进程。结果表明,在南方夏季,叠式曝气生物滤池能够进行快速启动,经过7 d左右自然挂膜启动完成,对CODMn的平均去除率为33%,对氨氮的平均去除率达到85.5%,对亚硝酸盐氮的去除率为82.9%。     

BAF+常规工艺中砂滤池净水效果研究

以广州某水厂源水为处理对象,研究在曝气生物滤池(BAF)+常规工艺中砂滤池的净水效果。研究表明,砂滤池出水CODMn、NH4+-N的平均值分别为1.19 mg/L和0.08 mg/L;相对于沉淀池出水,砂滤池对上述指标的平均去除率分别为27.41%和63.86%;砂滤池出水NO2--N几乎检测不出。砂滤池对分子量(10 K的溶解性有机物有较好的去除作用;砂滤池中DO下降了1.80 mg/L,分析表明在砂滤池中发生了完全硝化反应。     

沸石曝气生物滤池预处理微污染水源水中氨氮的研究

利用沸石曝气生物滤池预处理微污染水源水中的氨氮,研究了沸石的静态吸附性能以及不同运行参数对处理效果的影响.结果表明:(1)沸石具有快速吸附,缓慢平衡的特点.采用氨氮质量浓度为5.00 mg/L的使用溶液进行静态吸附实验,当吸附时间为30 min时,氨氮质量浓度为0.66 mg/L,去除率为86.8%,之后氨氮浓度和去除率基本保持不变.(2)水力负荷对氨氮的去除率影响不大,随着水力负荷的升高,氨氮去除率总体呈小幅度下降趋势.当水力负荷由0.4 m~3/(m~2·h)提高到1.3m~3/(m~2·h)时,氨氮平均去除率降低了13.2%.(3)在实验范围内,随着气水比的增大,氨氮平均去除率略有上升.当气水比为0.5(体积比,下同)、1.0、1.5时,氨氮平均去除率分别为81.8%、85.3%、86.7%.(4)氨氮去除主要发生在填料层200～600 mm处,600mm处的氨氮去除率已经达到89.7%,占总去除率的96.9%,而600 mm处后的氨氮浓度趋于平缓,去除率变化很小.     

曝气生物滤池处理生活污水研究

研究了上向流式曝气生物滤池反应器对生活污水COD和NH3-N的启动性能.结果表明,在启动期间,COD和NH3-N的最佳去除率分别达到了94.8%和93.2%;稳定运行期间,在气水比为3:1的条件下,曝气生物滤池对COD和NH3-N的平均去除率分别为95.9%和93.7%;沿程COD和NH3-N的去除率随着滤层高度的增加...     

污染物负荷对曝气生物滤池处理效果的影响研究

考察了进水有机负荷和氨氮负荷对曝气生物滤池出水水质的影响.结果表明,系统COD、氨氮和TN的去除率随进水有机负荷的增加而下降,在氨氮为28.3～33.6 mg/L、TN为39.0～45.8 mg/L条件下,有机负荷小于3.53 kg/(ms3·d)时,出水COD、氨氮和TN分别小于50、5、15 mg/L,去除率分别在85%、85%和65%以上;氨氮和TN的去除率随氨氮负荷的增加而下降,在COD为287.6～313.4 mg/L、氨氮负荷小于0.56 kg/(m3·d)时,出水氨氮小于8 mg/L,去除率在85%以上,出水TN小于15mg/L,去除率在65%以上.     

曝气生物活性炭滤池深度处理高浓度氨氮原水

实验研究曝气生物活性炭滤池对于高浓度氨氮原水的处理效果以及工艺运行稳定情况。以某自来水厂常规工艺沉淀池出水预加硫酸铵作为研究对象,原水氨氮平均浓度3.67 mg/L,实验条件:温度31.2℃,pH 7.13,滤速8~12 m/h,气水比0.5和1。采用3种不同工况条件进行实验,确定滤速10 m/h和气水比0.5的为最佳运行工况。在此工况下曝气生物活性炭滤池对于氨氮和COD Mn的平均去除率分别达到87.5%和19.2%,亚硝酸盐积累率为0.9%;出水氨氮浓度达到生活饮用水卫生标准GB5749-2006。同时炭滤池的出水浊度相比进水略微上升。     

多级流化床-曝气生物滤池中试处理高氨氮废水

采用多级流化床-曝气生物滤池组合工艺,以高氨氮工业废水为处理对象,研究了中试系统的启动方法、稳定运行阶段对污染物的去除效能及与传统活性污泥法相比的优势。结果表明：采用控制进水流量和逐步增加进水负荷的运行方法,历时近50 d,可实现中试系统的启动;启动阶段,系统对COD和NH₄⁺-N的平均去除率分别为68.74%和97.92%,出水COD和NH₄⁺-N的质量浓度平均分别为176.35 mg·L^-1和13.52 mg·L^-1;稳定运行阶段,系统在进水流量为2.0 m³·d^-1 的工况下,对COD和NH₄⁺-N的平均去除率分别为92.66%和99.32%,出水COD和NH₄⁺-N的质量浓度平均分别为152.24 mg·L^-1和1.32 mg·L^-1,其中,出水的NH₄⁺-N可以稳定达到地表水Ⅳ类水标准。与传统活性污泥法工艺相比较,该中试系统可以实现对COD的去除率从85.37%增加到92.66%,对NH₄⁺-N的去除率从72.53%增加到99.32%。     

臭氧曝气沸石生物滤池处理硝基苯废水

利用臭氧曝气沸石生物滤池处理硝基苯废水,了解了该方法对废水中的硝基苯、氮和磷的去除效果,考察了水力停留时间的变化对污染物去除效果的影响。臭氧曝气沸石生物滤池与空气曝气沸石生物滤池相比,臭氧曝气生物滤池对硝基苯、COD、氨氮的去除效果优于空气曝气沸石生物滤池,对总磷的去除效果与空气曝气沸石生物滤池差别不大。当臭氧曝气沸石生物滤池的HRT=4 h、臭氧浓度为126 mg/L时,对初始浓度为100 mg/L的硝基苯污水去除率接近99%。在相同条件下,空气曝气沸石生物滤池对硝基苯的去除率仅为59%。在HRT=4 h、臭氧浓度为126 mg/L时,臭氧曝气沸石生物滤池与空气曝气沸石生物滤池对COD的去除率为94%和83%,对NH4+-N的去除率为64%和59%,对TP的去除率为42%和45%。     

曝气生物滤池多孔释碳填料的研制及其对氨氮废水的处理研究

以核桃壳、水泥、沸石为原料制备新型多孔释碳填料(WZ填料),并用其装填搭建曝气生物滤池(BAF)处理氨氮废水。结果表明:WZ填料中沸石∶核桃壳∶水泥的最佳配比(质量比)为1.00∶0.02∶0.30,制得的WZ填料比表面积大,适合微生物生长,可长时间稳定释碳,20d内的释碳量稳定保持在80mg/L左右,WZ填料有助于缩短BAF挂膜启动时间,延长水力停留时间(HRT)可提升BAF对污染物的去除效果,BAF对进水氨氮浓度适应范围较广,在进水氨氮为30～50mg/L时,BAF稳定运行期对氨氮的平均去除率达95%以上,COD平均去除率达76%左右。可见,WZ填料释碳量高且持久性强,有助于解决城市污水处理中反硝化碳源不足问题,提高脱氮效率。     

改进式曝气生物滤池处理高氨氮废水的研究

针对化肥氨氮废水排放量大、氨氮浓度高、C/N低等特点,通过实验研究探讨了添加高效菌种后采用改进式曝气生物滤池对化肥氨氮废水的处理性能、机理及实用性,并与SBR、普通BAF(Biofor)工艺和未添加高效菌种的改进式曝气生物滤池进行了对比。实验结果表明,添加高效菌种后改进式曝气生物滤池可以将氨氮≤200 mg/L,COD≤150 mg/L的化肥废水有效地处理至氨氮≤5 mg/L,COD≤50 mg/L,同时对总氮去除率达60%以上。     

琼脂碳源生物反硝化去除水源水中硝酸盐

针对受硝酸盐污染的水源水,以琼脂为反硝化细菌的碳源和微生物载体,通过生物反硝化作用脱除水源水中的硝酸盐,并利用曝气生物滤池(BAF)去除琼脂反应器出水中残留的少量CODMn和NO2--N等污染物。实验结果表明,水源水自然接种的条件下,可以顺利启动琼脂反应器;在温度为25℃左右,琼脂反应器在进水NO3--N约25 mg/L、水力停留时间1.5 h时,能获得70%的硝酸盐氮去除率;曝气生物滤池在水力停留时间0.5 h、气水比2.8时,可控制最终出水的CODMn和NO2--N分别在5.0 mg/L和0.10 mg/L以下;琼脂反应器的脱氮效果与温度、进水NO3--N浓度及水力停留时间等有关。研究指出,琼脂反应器与曝气生物滤池构成的组合系统能较好地脱除水源水中的硝酸盐并且能控制最终出水水质,不会导致二次污染,从而获得合格的饮用水源水。     

微污染水源水生物处理工艺中IAL-CHS与三相流化床的初步比较

初步比较气升式内循环蜂窝陶瓷反应器(IAL-CHS)和内循环三相流化床反应器(ITFB)对微污染水源水进行生物预处理的效果。IAL-CHS反应器比ITFB反应器挂膜启动速度快,但是在挂膜期承受冲击负荷能力较ITFB反应器差。在进水相同条件下,两者所能达到的最小水力停留时间、最大体积负荷和容积负荷相差不大,但是ITFB反应器的曝气强度却为IAL-CHS反应器的3.33倍,并且比IAL-CHS反应器出水SS高,浊度去除率低,单位载体的生物量及活性生物量小。     

Comparison of nitrification rates in conventional and membrane-assisted biological nutrient removal processes

A membrane-assisted and a conventional activated sludge system, both operated in an enhanced biological phosphorus removal (EBPR) mode and under identical operating conditions, were studied to investigate the effect of the membrane solids-liquid separation on nitrification activity. Both the membrane EBPR (MEBPR) and conventional EBPR (CEBPR) processes achieved stable and complete removal of ammonium-nitrogen from the influent wastewater. However, when the intrinsic nitrification activity was assessed in offline batch tests, the CEBPR mixed liquor exhibited 15 to 75% greater nitrification potential than the MEBPR counterpart. These results were further validated by monitoring nitrification rates of conventional mixed liquor as it evolved toward a membrane mixed liquor. It was also demonstrated that the larger aerobic mass fraction of the MEBPR system could not be the only factor influencing the reduced intrinsic nitrification rate. The present study strongly suggests that the presence of a membrane solids-liquid separation per se may be sufficient to alter the nitrification kinetics of an EBPR mixed liquor and that this possibility should be considered in arriving at an appropriate process design.     

密云水源水的预臭氧化及强化常规处理研究

针对北京密云水库水的水质特征,分别进行了实验室烧杯和现场中试研究.实验结果表明,预臭氧化能使原水中较大粒径颗粒数目减少,并能显著降低原水中不饱和有机物的含量;高效聚合氯化铝在颗粒物及有机物的去除上明显优于传统的聚合氯化铝和硫酸铝;预臭氧化与常规处理的联合工艺对浑浊度、有机物和大肠菌群有很高的去除率.     

Combined biological and photocatalytic treatment for the mineralization of phenol in water

Phenol is degraded by biological treatment, however mineralization requires long time. To decrease the time and operational cost necessary for the mineralization of phenol, an optimum operation condition of the combined biological–photocatalytical treatment was investigated. The mineralization of phenol (50 mg l⁻¹) was conducted in a flow-type biomembrane tank combined with a batch-type TiO₂-suspended photocatalytic reactor. Phenol was degraded biologically to the concentration of 6.8 mg l⁻¹, an effective concentration for further photocatalytic treatment. After the biological treatment, the biotreated phenol was treated photocatalytically to complete the mineralization of phenol. The combined treatment shortened the mineralization time compared to the biological treatment and electric cost compared to the photocatalytic treatment only. The combined treatment may be suitable for a short-time mineralization of phenol in wastewater.     

Comparison of two biological treatment processes using attached-growth biomass for sanitary landfill leachate treatment

The objective of this investigation was to compare two biological systems using attached-growth biomass, for treatment of leachates generated in a typical municipal solid waste sanitary landfill. A moving-bed biofilm process, which is a relatively new type of biological treatment system, has been examined. It is based on the use of small, free-floating polymeric (polyurethane) elements, while biomass is being grown and attached as biofilm on the surface of these porous carriers. A granular activated carbon (GAC) moving-bed biofilm process was also tested. This method combines both physico-chemical and biological removal mechanisms for the removal of pollutants. The presence of GAC offers a suitable porous media, which is able to adsorb both organic matter and ammonia, as well as to provide an appropriate surface onto which biomass can be attached and grown. A laboratory-scale sequencing batch reactor (SBR) was used for the examination of both carriers. The effects of different operation strategies on the efficiency of these biological treatment processes were studied in order to optimize their performance, especially for the removal of nitrogen compounds and of biodegradable organic matter. It has been found that these processes were able to remove nitrogen content almost completely and simultaneously, the removal of organic matter (expressed as BOD5 and COD), color and turbidity were sufficiently achieved.     

反硝化生物滤池用于再生水脱氮效能及动力学研究

采用反硝化生物滤池处理城市污水厂二级出水,研究了反硝化生物滤池脱氮效能及其影响因素,构建了反硝化生物滤池脱氮动力学模型。结果表明,反硝化生物滤池启动7d后出水水质稳定,对NO3--N的去除率达到90%以上,NO2--N积累现象消失;当外加乙酸钠作碳源并使C/N ≥ 4.7时,对NO3--N的去除率达到90%以上,出水NO3--N浓度在1.0 mg/L以下;反硝化生物滤池具有较高的处理负荷,当HRT ≥ 5 min时,对NO3--N的去除率能达到90%以上;在实验水质条件下,滤池反硝化反应遵循一级反应动力学,且反应速率常数与流速成正比。     

利用生物曝气滤池修复受污染水源

利用生物曝气滤池(BAF)对微污染水源水去除氨氮及有机物进行了试验研究。试验表明,在进水氨氮为6mg／L左右时,BAF可在8m／h的滤速下运行,氨氮去除率大于88％;在氨氮进水为2mg／L时,BAF可在16m／h的滤速下运行,氨氮去除率大于84％。BAF对水中的三氯甲烷前体物去除率较低(16％),对AOC的去除率为58％。BAF中载体上的生物膜主要聚集在表面的凹陷和孔洞处,不能完全覆盖载体表面。     

常规水处理厂中小隐孢子虫卵囊的去除效果

介绍了小隐孢子虫卵囊的特点及其对人体的危害，分析了pH、混凝剂种类与投加量、电导率和天然有机物含量等对小隐孢子虫卵囊的Zeta电位的影响，总结了混凝－沉淀－过滤和直接过滤对小隐孢子虫卵囊的去除效果，探讨了水温、水质、混凝剂种类与投加量、滤料层组成和滤速等对去除效果的影响。     

常规水处理厂中小隐孢子虫卵囊的去除效果

介绍了小隐孢子虫卵囊的特点及其对人体的危害,分析了pH、混凝剂种类与投加量、电导率和天然有机物含量等对小隐孢子虫卵囊的Zeta电位的影响,总结了混凝-沉淀-过滤和直接过滤对小隐孢子虫卵囊的去除效果,探讨了水温、水质、混凝剂种类与投加量、滤料层组成和滤速等对去除效果的影响.