长期低聚磷条件对AO-SBR系统Accumulibacter代谢特性的影响

为了考察长期低聚磷(Poly-P)条件下Accumulibacter的菌群结构及其代谢特性的变化,采用两个SBR反应器,分别采用乙酸钠和丙酸钠为有机碳源,接种富含Accumulibacter的活性污泥,在进水PO34--P浓度为2. 5 mg·L~(-1)的低磷进水条件下运行60 d,对系统除磷性能、污泥浓度、主要菌群结构的变化进行研究.结果表明,长期低Poly-P条件下两个SBR系统均表现出良好的除磷和去除有机物的性能,但两个系统内的菌群代谢均表现出聚糖菌代谢特征;运行60 d后,丙酸盐系统中AccumulibacterⅠ型仍保持了较高的丰度(40%±7%),表明丙酸盐SBR系统中AccumulibacterⅠ型不仅具有较高的代谢活性,还能够在长期低聚磷条件下以一种不依赖Poly-P的代谢方式进行生存;对比发现,丙酸盐碳源更有利于Accumulibacter适应低磷负荷的运行环境,且在低磷负荷的运行环境下AccumulibacterⅠ型比Ⅱ型更具竞争优势.     

在模拟酸性海洋大气环境中锌缓蚀剂的研制

目的寻找有效抑制锌大气腐蚀的缓蚀剂配方。方法采用静态失重法、极化曲线法和交流阻抗法,研究模拟酸性海洋大气环境中,多聚磷酸钠单独使用以及分别与香草醛、碘化钾、硫脲复配使用时对锌腐蚀的缓蚀作用。结果多聚磷酸钠单独使用时对腐蚀介质中的锌具有较好的缓蚀作用,多聚磷酸钠与香草醛、碘化钾、硫脲之间有良好的协同缓蚀效应,最佳质量配比分别为3∶1,1∶2,1∶4。多聚磷酸钠以及多聚磷酸钠复配缓蚀剂属于混合抑制型缓蚀剂;它们能够在锌表面形成一层保护膜,从而抑制锌的腐蚀。结论寻找到的缓蚀剂配方能够有效抑制锌的大气腐蚀。     

不同氮磷营养条件下铜绿微囊藻（Microcystis aeruginosa）对正磷酸盐的蓄积效果

铜绿微囊藻是中国湖泊、水库及其它水域生态系统发生、形成富营养化危害的主要藻类。采用了直接显色法对单细胞铜绿微囊藻（〖WTBX〗Microcystis aeruginosa〖WTBZ〗）蓄积正磷酸盐的浓度进行测定,并与传统测定方法进行比较。直接显色法测定的磷浓度值减去溶液中可溶性磷浓度值即得到铜绿微囊藻蓄积的磷浓度值。对用不同处理方式处理过的铜绿微囊藻藻液进行过滤显色和直接显色测定,结果表明聚磷酸盐(正磷酸盐)在铜绿微囊藻体内不是游离存在,而很可能是与细胞内某一活性部分结合。在确立测定方法的基础上,研究了以修改了的MⅢ培养基为基本培养条件,改变氮磷浓度对产毒铜绿微囊藻（FACHB942）蓄积正磷酸盐效果的影响。结果显示,①氮磷比不变时,随着起始磷浓度的增加,铜绿微囊藻对正磷酸盐蓄积量也逐渐增加,成明显正相关;②氮浓度不变时,铜绿微囊藻对正磷酸盐的蓄积效果与磷浓度正相关;③而同一磷浓度下,铜绿微囊藻对正磷酸盐的蓄积效果与氮浓度负相关,但氮浓度超过21 mg/L时,氮浓度对于铜绿微囊藻蓄积磷的效果影响变得不规则。     

不同碳源条件下聚磷菌代谢特性

利用2套SBR系统在厌氧好氧交替条件下对聚磷菌(phosphorus accumulating organisms,PAO)进行富集,分别采用乙酸和丙酸作为碳源。通过对典型周期内磷酸盐,聚羟基烷酸(polyhydroxyalkanoates,PHAs),糖原和多聚磷酸盐变化情况的分析,探讨了不同碳源下,聚磷菌胞内碳源物质的代谢机理以及其对于生物除磷的影响。结果表明,以乙酸为碳源时,PHAs的合成量和分解量都要高于丙酸为碳源,且PHAs主要成分以聚-β-羟丁酸(poly-β-hydroxybutyrate,PHB)为主,污泥的比释磷速率和比吸磷速率都要高于丙酸为碳源的情况。     

Effect of the C:N:P ratio on the denitrifying dephosphatation in a sequencing batch biofilm reactor (SBBR)

A series of investigations were conducted using sequencing batch biofilm reactor(SBBR) to explore the influence of C:N:P ratio on biological dephosphatation including the denitrifying dephosphatation and the denitrification process.Biomass in the reactor occurred mainly in the form of a biofilm attached to completely submerged disks.Acetic acid was used as the source of organic carbon.C:N:P ratios have had a significant effect on the profiles of phosphate release and phosphate uptake and nitrogen removal.The highest rates of phosphate release and phosphate uptake were recorded at the C:N:P ratio of 140:70:7.The C:N ratio of 2.5:1 ensured complete denitrification.The highest rate of denitrification was achieved at the C:N:P ratio of 140:35:7.The increase of nitrogen load caused an increase in phosphates removal until a ratio C:N:P of 140:140:7.Bacteria of the biofilm exposed to alternate conditions of mixing and aeration exhibited enhanced intracellular accumulation of polyphosphates.Also,the structure of the biofilm encouraged anaerobic–aerobic as well as anoxic–anaerobic and absolutely anaerobic conditions in a SBBR.These heterogeneous conditions in the presence of nitrates may be a significant factor determining the promotion of denitrifying polyphosphate accumulating organism(DNPAO) development.     

多孔矿物-聚磷酸铵对甲烷爆炸的协同抑制研究

为探究新型多孔矿物(MTS)-聚磷酸铵(APP)复合粉体对甲烷-空气预混气爆炸的抑制效果,采用20 L球形爆炸装置开展多孔矿物、APP及其复合粉体在不同组成、不同添加浓度条件下的甲烷爆炸抑制试验,并使用热分析仪研究其热解行为.研究结果表明:当粉体添加量为0.100 g/L,多孔矿物与APP质量组成比为1∶3时,复合粉体...     

GP/APP膨胀阻燃体系对硅橡胶复合材料阻燃及抑烟性能的影响

为了探究石墨粉 (GP) 与聚磷酸铵 (APP) 膨胀阻燃体系对硅橡胶复合材料的阻燃及抑烟特性的影响,采用锥形量热仪 (CCT)、热重分析仪 (TG) 及极限氧指数测试仪 (LOI) 对阻燃硅橡胶复合材料进行表征。研究结果表明:与单独添加膨胀阻燃剂APP的阻燃硅橡胶相比,添加GP/APP膨胀阻燃体系可有效提升燃烧过程中形成的膨胀碳层的致密度,降低阻燃硅橡胶复合材料的热释放速率及总烟释放量,提高阻燃硅橡胶复合材料高温阶段的热稳定性,提升阻燃硅橡胶复合材料的燃烧成炭率和质量保持率; 使阻燃硅橡胶复合材料的氧指数值增大。     

聚磷菌生物除磷机理研究进展

废水中过量磷酸盐是引起水体富营养化的主要原因之一,生物除磷是一项新型的水处理技术。聚磷菌生物在多聚磷酸盐的合成和降解过程中发挥重要作用。文章综述了目前聚磷菌生物除磷的生化机理,聚磷过程中涉及的主要酶类及磷酸盐转运过程相关基因的表达调控。     

转聚磷激酶基因的大肠杆菌去除水体中的磷

为探索有效的生物除磷方法,构建了聚磷激酶基因(ppk)的表达载体pET28a(+),并转化大肠杆菌(Escherichiacoli)BL21,获得了可过表达ppk基因的工程菌BL-PPK.RT-PCR结果表明,ppk基因在转化的大肠杆菌中得到了高效表达.聚磷试验结果表明,培养10h后,转化了ppk基因的大肠杆菌细胞内聚磷含量比对照菌株高20倍,而培养液中可溶性磷浓度为对照菌株的约1/9.     

Effect of temperature on anoxic metabolism of nitrites to nitrous oxide by polyphosphate accumulating organisms

Temperature is an important physical factor, which strongly influences biomass and metabolic activity. In this study, the effects of temperature on the anoxic metabolism of nitrite(NO-2) to nitrous oxide(N2O) by polyphosphate accumulating organisms, and the process of the accumulation of N2O(during nitrite reduction), which acts as an electron acceptor, were investigated using 91% ± 4% Candidatus Accumulibacter phosphatis sludge. The results showed that N2O is accumulated when Accumulibacter first utilize nitrite instead of oxygen as the sole electron acceptor during the denitrifying phosphorus removal process. Properties such as nitrite reduction rate, phosphorus uptake rate, N2O reduction rate, and polyhydroxyalkanoate degradation rate were all influenced by temperature variation(over the range from 10 to 30°C reaching maximum values at 25°C). The reduction rate of N2O by N2O reductase was more sensitive to temperature when N2O was utilized as the sole electron acceptor instead of NO2, and the N2O reduction rates, ranging from 0.48 to 3.53 N2O-N/(hr·g VSS), increased to 1.45 to 8.60 mg N2O-N/(hr·g VSS). The kinetics processes for temperature variation of 10 to 30°C were(θ1 = 1.140–1.216 and θ2= 1.139–1.167). In the range of 10°C to 30°C, almost all of the anoxic stoichiometry was sensitive to temperature changes. In addition, a rise in N2O reduction activity leading to a decrease in N2O accumulation in long term operations at the optimal temperature(27°C calculated by the Arrhenius model).