Effect of cycle time on biodegradation of azo dye in sequencing batch reactor

The effects of cycle time on the biodegradation of the azo dye remazol brilliant violet 5R (RBV-5R) were investigated in an anaerobic–aerobic sequencing batch reactor (SBR). System performance was determined by monitoring chemical oxygen demand (COD), color, anaerobic enzyme (azo reductase) and aerobic enzyme (catechol 2,3-dioxygenase), and aromatic amine concentration. SBR was operated in three different total cycle times (48 h, 24 h and 12 h), fed with a synthetic textile wastewater. In this study, the anaerobic period of SBR was found to allow the reductive decolorization of azo dye and the aerobic period was found to be effective on further COD removal after the anaerobic period. The percentage reductions in color by the anaerobic stage of the SBR were at 72%, 89% and 86% for the 24-h, 12-h and 6-h cycle times, respectively. Total COD removal efficiencies were over 75% for all operational conditions and about 70% of the COD removal was achieved in the first 3 h of anaerobic stages. During the decolorization of RBV-5R, two sulfonated aromatic amines (benzene-based and naphthalene-based) were formed and detected by HPLC. Aerobic phases of SBR with total cycle times of 48 h, 24 h and 12 h were able to remove benzene-based aromatic amines with removal efficiency of 64%, 92% and 89%, respectively. The results indicated that the best SBR performance in terms of color removal and aromatic amine degradation was achieved from total cycle time of 24 h.     

Biological treatment of tannery wastewater in the presence of chromium

Experiments were carried out to determine the feasibility of treating tannery wastewater containing chromium, an inhibiting compound, with sequencing batch reactors (SBR). The maximum chromium concentration tolerated by microorganisms was determined through aerobic and anoxic batch experiments, and the biomass inhibition process was analyzed in a lab scale reactor at increasing chromium concentrations. The results obtained, in batch experiments and in the SBR reactor, have demonstrated that chromium addition had less influence on the denitrification bacteria than on the nitrification bacteria. In addition, it was observed that nitrification and denitrification rates, at the same chromium concentration, were higher in the SBR reactor than in batch experiments with unacclimated biomass. Experimental results confirm that sequencing batch reactors are able to produce a more resistant biomass, which acclimates quickly to inhibiting conditions. A large amount of chromium was found in the sludge from the reactor, while the effluent was devoid of the inhibiting metal.     

连续流序批式活性污泥法

连续流序批式活性污泥法是一种新型污水生物处理工艺，介绍了该工艺的结构组成、流程控制、生物脱氮除磷基本原理、自动化管理以及与其它处理工艺的比较。     

间歇式活性污泥法处理1-4丁二醇废水的研究

用间歇式活性污泥法(SBR法)对高浓度1-4丁二醇废水进行了处理研究。实验测定了污泥沉降性能,测试了最佳曝气时间、最佳pH值范围以及SBR处理系统耐污染的负荷。实验结果表明:SBR法的污泥沉降比为15%～30%,完全符合活性污泥正常运行时的沉降标准。处理污水的最佳曝气时间为5h,最佳pH值范围为7～8。该处理系统耐冲击,能承受较高的污染负荷,对水质的波动有较强的承受能力。利用SBR法可以处理1-4丁二醇、聚丙烯酰胺和顺丁烯二酸酐三套装置排放的混合污水。     

半经验生物滴滤器模型研究

生物滴滤(BTF)净化有机废气是一个复杂的过程,其数学模型往往形式繁琐、参数众多,实际应用比较困难.半经验生物滴滤模型是基于生物酶促反应基本原理(米-门方程),并在含苯废气的生物滴滤净化动态实验和生物膜静态实验等研究的基础上建立和完善的一个应用模型.为了符合生物滴滤器内的实际状况,在建模过程中引入了微生物质量浓度沿床层深度变化的函数等合理假设.模型的检验采用将静态实验所得参数代入模型计算,并与生物滴滤动态实验结果进行对比的方法.检验结果表明:在较宽的负荷、表观过滤气速范围内,该模型对滴滤器的模拟值均较符合实验值.该模型的数学形式简单,参数也较少,且主要参数,如生物膜最大净化速率,K值及微生物质量浓度分布等均可通过生物膜静态实验测得.      

AnSBR法处理生活污水中典型环境雌激素的研究

为评价和考察厌氧序批式反应器(AnSBR)对生活污水中9种典型环境雌激素的去除效果和机制,采用固相萃取(SPE)——LC/MS/MS分析方法,分析所选环境雌激素的浓度和污泥吸附量. 结果表明:大豆苷元,4-t-辛基酚(OP),4-n-壬基酚(NP)和染料木素的检出浓度高于其他5种环境雌激素;厌氧污泥对NP,OP,雌酮(E1),17α-乙炔基雌二醇(EE2)和17β-雌二醇(E2)的吸附作用明显;大豆苷元和染料木素的去除率在60%以上;大豆苷元、染料木素和雌三醇(E3)的主要去除机制为生物降解作用,EE2,OP和NP的去除是生物降解、污泥吸附的共同作用.      

序批式接触氧化反应器中细菌多样性及其功能

采用分子生物学手段,通过构建16S rDNA基因文库,对新型剩余污泥减量化处理系统——序批式生物砾间接触氧化反应器中细菌多样性进行了系统发育分析,并讨论了多种细菌共存对剩余污泥减量化的贡献.共有72个克隆子用于细菌系统发育分析. 结果表明:填料表面附着细菌与孔隙内细菌由变型菌属、噬纤维菌-屈挠杆菌-拟杆菌组(CFB)、硝化杆菌科、低G+C革兰氏阳性细菌、高G+C革兰氏阳性细菌、疣微菌科和绿菌科等七大类细菌组成. 其中,优势菌群分别是以兼具呼吸/发酵代谢方式的β变形菌纲(分别占生物膜和内泥中克隆子总量的18%和35%)和δ变形菌纲,以及以呼吸/发酵为主要代谢方式的CFB(分别占克隆子总量的24%和23%). 多种细菌对剩余污泥减量化的主要功能可归纳为能量解偶联、共代谢作用、生物溶胞作用和慢性生长种群的影响.      

强化膜生物反应器脱氮除磷性能对比试验研究

对序批式运行方式强化膜生物反应器脱氮除磷效果进行了研究.在试验过程中逐渐降低进水COD TN值,提高总氮负荷,比较序批式膜生物反应器和传统膜生物反应器的脱氮除磷性能与膜污染状况.试验结果表明,进水COD TN降至3 8～8 3,总氮负荷提高至0 22kg·m-3·d-1时,传统膜生物反应器无法脱氮,而序批式膜生物反应器通过改变周期、提高交换比等方式,TN和氨氮去除率分别保持在67 6%和93 1%.序批式的运行方式还可以减轻膜污染.     

序批式膜反应器同步硝化和反硝化的特性

为提高污水生物脱氮处理的效率和减少外加碳源,研究了序批式膜反应器(SBBR)在有氧情况下处理生活污水中同步硝化和反硝化的特性.试验表明,原水TN为80～110mg/L和溶解氧浓度为0.8～4.0mg/L情况下,出水TN小于15mg/L,NH₃^-N去除率达100%,TN去除率54%～77%,NH₃^-N容积负荷率为47～94mg/(L·d),TN容积负荷率为56～113mg/(L·d).TN的变化规律为在NH₃^-N降到零或最小之前,TN持续降低之后,TN有短时的上升后再缓慢降低.在较大的溶解氧浓度范围内,SBBR具有同步硝化和反硝化的能力,建议将NH₃^-N降解到零或最小值的时刻,作为同步硝化和反硝化的结束点.