ABR工艺预处理木薯酒糟废水的工程应用

木薯酒糟废水有机物浓度高、悬浮物含量大、pH呈酸性、可生化性能较差 ,通常直接采用固液分离—厌氧 (UASB)—好氧曝气生化法处理效果并不理想 ,而采用ABR工艺进行厌氧水解酸化预处理木薯酒糟废水迄今为止未见报道。经绵阳市酒厂废水治理工程证明 ,强化ABR预处理工序是保证后续处理措施能否正常运行的关键     

ABR-生物接触氧化法处理果汁废水实验分析

厌氧式折流反应器(Anaerobic Baffled Reactor,简称ABR)是一种新型高效厌氧反应器,具有工艺技术简单、建设投资费用低、运行管理方便、固液分离效果好、出水水质好、运行稳定可靠、对有毒物质适应性强等优点,是一种极具开发应用前景的废水生物处理新技术。ABR最大的特点是在反应器中设置上下折流板而在水流方向上形成依次串联的隔室,从而使其中的微生物种群沿长度方向的不同隔室实现产酸和产甲烷相的分离。该反应器具有结构简单,截留污泥能力强,系统处理效果稳定,运行管理方便等优点。分析了ABR及ABR与其它工艺的联合在果汁废水处理方面的应用。     

厌氧水解酸化处理含高浓度聚丙烯酰胺污水

运用厌氧瓶和厌氧折流板反应器(ABR)对含部分水解聚丙烯酰胺(HPAM)的污水进行厌氧水解酸化生物处理.选取PAM-F1和PM-2两株厌氧菌为HPAM降解菌,并优化了单株菌和混合菌的降解条件.结果发现,最佳降解条件为降解9 d,连续活化3次,温度35~40℃,初始pH=7.5.此时,混合菌对500 mg·L-1HPAM污水的降解效果最好,降解率可达到40.69%.通过生理生化特征和16S rDNA分析,确定PAM-F1为红球菌(Rhodococcus sp.).混合菌降解前后的HPAM傅里叶-红外光谱图分析表明,细菌能够降解并利用HPAM的部分胺基和碳作为生长所需的氮源和碳源,并推断出HPAM的降解过程发生在厌氧水解酸化阶段.扫描电镜(SEM)图片显示,ABR中形成了能有效促进HPAM生物降解的颗粒污泥.而经过ABR处理的HPAM污水,CODCr去除率和HPAM降解率可分别达到89.96%和75.48%.研究表明,厌氧水解酸化法是一项能够有效处理含高浓度HPAM污水的技术.     

ABR反应器的两种快速启动方法对比

ABR反应器的启动是ABR反应器能否高效稳定运行的关键,其影响因素很多。为了更好地实现ABR反应器的启动,提出了通过2种不同启动方法的对比,即1^#反应器采用好氧预挂膜的方法,2^#反应器采用低负荷启动法,得出的结论为,好氧预挂膜启动法的启动时间短,COD去除率高,出水pH稳定,颗粒状污泥生长情况较好,是一种可推广的启动方法。     

ABR处理硫酸盐有机废水的BP神经网络建模

通过厌氧折流板反应器(ABR)处理硫酸盐有机废水的实验数据对BP神经网络进行训练,建立了ABR处理硫酸盐有机废水的BPNN模型,通过测试对比,找出了较优训练函数为traingda,较优训练次数为1 900.利用分割连接权值法(PCW)对影响出水SO42-和COD的主要因素进行分析,结果显示进水COD、SO42-、pH、COD/SO42-和HRT对出水SO42-和COD均产生一定影响,其中进水pH对出水SO42-和COD的影响最大,相对重要性(RI)指数分别为30.79％和23.44％;并通过样本试验数据分别建立了对SO42-和COD去除率的限制因子仿真模型,为预测硫酸盐有机废水的厌氧处理过程提供指导.     

An experimental study on the influence of zeolite on changes of pH and alkalinity in anaerobic treatment of compost leachate

With the increase of urbanization, municipal solid waste has also increased. Therefore, the need for solid waste management is also increasing compared with earlier decades. Composting is a good option for the recycling of solid waste; however, it produces leachate, which requires proper treatment systems to prevent environmental degradation. Due to high chemical oxygen demand (COD) concentrations in compost leachate, anaerobic treatment is the best option for handling the effluent, and an anaerobic baffled reactor (ABR) is one such anaerobic reactor that can be used for its treatment. Because of high ammonia and heavy metal concentrations, as well as the possibility of sludge washout in ABRs, it is important to use proper media, such as zeolite, which can reduce inhibition effects and sludge washout from the reactor. Anaerobic treatment, especially during the methanogenesis phase, is sensitive, and pH and alkalinity are parameters that influence the treatment. Therefore, adjusting these parameters within a normal range is very important to the proper functioning of anaerobic systems. In this study, a pilot‐scale ABR was used, and the last 4 of the 8 ABR compartments were filled with zeolite. The bioreactor was operated at hydraulic retention times (HRT) of 3, 4, and 5 days, with zeolite filling ratios of 10%, 20%, and 30%, and influent COD concentrations of 10,000, 20,000, and 30,000 milligrams per liter (mg/L). In this study, pH value was 6.43 ± 0.1, 6.96 ± 0.3, and 6.96 ± 0.25 at filling ratios of 10%, 20%, and 30%, respectively. According to the results, in all filling ratios, no significant changes were observed in the pH value when the organic loading rate increased and its amount was within a constant range. Influent alkalinity was equal to 2015 ± 510, 2884 ± 505, and 4154 ± 233 milligrams of calcium carbonate per liter (mg CaCO₃/L) at influent COD concentrations of 10,000, 20,000, and 30,000 mg/L, respectively, and in effluent, they were 2536 ± 336, 3379 ± 639, and 4377 ± 325 mg CaCO₃/L, respectively. The amount of alkalinity in the effluent increased compared with the alkalinity in the influent. The results show that the amount of alkalinity in the influent and effluent was similar, and the alkalinity enhancement was lower when the filling ratio was increased from 10% to 20%, and 20% to 30%. Comparisons of the results from zeolite with and without biofilm showed that, in cases of zeolite with biofilm, the amounts of silica and oxygen decreased and the amount of carbon increased, and it showed the formation of biofilm on the surface of zeolite. In addition, the absence of sodium in the zeolite with the biofilm indicated that sodium was exchanged with ammonium ions. According to the results, zeolite can be used in anaerobic reactors as a medium, and it also reduces fluctuations in pH and alkalinity at different organic loading rates, providing a normal range for anaerobic treatment.     

改进型ABR+复合生物反应器处理糕点残渣废水

介绍了改进型ABR+复合生物反应器在糕点残渣废水处理工程实例中的应用,运行结果表明:该工艺运行稳定、操作简便、运行成本低,处理糕点残渣废水可获得良好的效果,出水水质达GB 8978—1996《污水综合排放标准》中的一级排放标准。     

高效厌氧折流板反应器分区进水的启动实验

分区进水厌氧折流板反应器内设填料,以二沉池活性污泥接种挂膜培养厌氧酸化菌,反应器四个格室的进水比为4:3:2:1,以单侧进水ABR作比较。实验研究了在HRT=8h,有机负荷约为0.8kgCOD/m·3d,运行15d后,改变运行参数为HRT=4h,在条件相同的情况下,实验第23d后,分区进水ABR反应器的出水COD效果好于单侧进水。在运行60d时COD去除率平均保持在35%,可认为分区进水ABR的启动成功。     

缺氧折流板反应器（ABR）运行影响因素分析

ABR（Anaerobic Baffled Beactor）由于其具有结构简单,出水水质好,运行稳定可靠等优点,在废水处理中得到广泛的应用。本文结合近年来对ABR的研究和试验分析,对影响ABR运行效果的因素作了较全面的论述。     

ABR反应器的设计

类似于多个UASB反应器串联起来运行的ABR反应器具有多种其它反应器不具备的优点，在处理化工颜料黄高盐生产废水的工程中，结合将高效复合微生物技术用于厌氧水解一连续曝气生化工艺取得成功；对ABR反应器而言，正确的设计参数是工程运行成功的保证。