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91.
采用PCR-RFLP技术研究了不同C/N比下亚硝酸盐氧化菌及异养菌混合体系的微牛物多样性,并探讨了微生物菌群结构与其功能(硝化件能)的关系.C/N=0时,混合体系主要由自养菌和寡营养菌(85.1%)组成,包括亚硝酸盐氧化菌(NOB)、拟杆菌门、α-变形菌纲、浮霉菌门和绿色非硫细菌中的一些菌株.C/N=0.44时,混合体系中的自养菌减少,异养菌(主要是γ-变形菌纲的成员)大量出现.C/N=8.82时,γ-变形菌纲的菌株尤其是反硝化菌Pseudomonas sp.占主导(93.8%),与此同时,随着C/N升高,该混合体系的硝化性能也由专一的亚硝酸盐氧化过程转变为同时硝化反硝化过程.微生物菌群结构的转变较好地解释了其硝化性能的改变.本研究揭示了微生物菌群结构与其功能的内在联系,同时表明PCR-RFLP技术与化学分析相结合是研究微生物菌群结构与功能的有力工具.图3表2参13 相似文献
92.
The effect of ammonia inhibition was evaluated during the enhanced anaerobic treatment of digested effluent from a 700 m3 chicken-manure continuous stirred tank reactor (CSTR). A 12.3 L internal circulation (IC) reactor inoculated with an anaerobic granular sludge and operated at 35 ± 1 °C was employed for the investigation. With a corresponding organic loading rate of 1.5-3.5 kg-COD/m3 d over a hydraulic retention time of 1.5 d, a maximum volumetric biogas production rate of 1.2 m3/m3 d and TCOD (total COD) removal efficiency ranging from 70% to 80% was achieved. However, the continual increase in the influent TAN content led to ammonia inhibition in the methanogenesis system. The SCOD/TAN (soluble COD/total ammonia nitrogen) ratio was presented to be the key controlling factor for the anaerobic treatment of semi-digested chicken manure, and further validation through shock loading and ammonia inhibition experiments was conducted. The threshold value of the SCOD/TAN ratio was determined to be 2.4 (corresponding to a TAN of 1250 mg/L) at an influent pH of 8.5-9. 相似文献
93.
工业废水厌氧生物处理中的无机和有机毒性物质 总被引:7,自引:0,他引:7
介绍了有关工业废水厌氧生物处理中无机和有机毒性物质方面的重要研究成果。工业废水中的毒性物质一般会对甲烷菌产生可逆性抑制,驯化能够减轻或消除毒性物质对甲烷菌的抑制作用,厌氧工艺在适当条件下能够有效地去除工业废水中的多种毒性物质。 相似文献
94.
晚期渗滤液脱氮过程中的抑制现象及其消除 总被引:7,自引:0,他引:7
对于垃圾填埋过程中高氨氮浓度、低C/N的晚期渗滤液,反硝化碳源不足会造成A/O脱氮系统的亚硝酸积累,导致对氨氧化和亚硝酸氧化过程的抑制作用.A,2/O流程中的厌氧处理对难降解有机物的水解酸化作用可为后续反硝化提供易降解有机碳源,可消除亚硝酸盐的积累及其对硝化过程的抑制.试验表明,厌氧处理可使氨氧化速率和反硝化速率提高约1倍和1.3倍,分别达0.123mgN/(mgMLSSd)和0.0675mgN/(mgMLSSd),TN去除率由8%提高到15%.使浓度高达1000mg/L的氨氮,在0.138mgN/(mgMLSSd)的进水负荷下较为彻底地氧化为安全的硝酸盐. 相似文献
95.
采用多孔聚合物载体固定化微生物在厌氧流化床(AFB)反应器中处理含硫废水,研究反应器抗硫化物(S2-)毒性抑制和抗硫酸盐毒性抑制的能力;探索解除 S2-毒性的方法.研究表明,当进料基质 COD浓度为 5000mg/L,HRT为5.2-5.4h,S2-<200mg/L时,反应器去除 COD效果不受影响,S2-350mg/L时,厌氧消化受到明显抑制,反应器可容忍530mg/L S2-浓度而未造成消化系统的破坏;SO42-浓度高达3521mg/L,COD去除率仍可达77%-80%,但SO42-去除率明显下降;当COD/SO42-的比值大于1.45时,硫酸盐还原菌和产甲烷菌的生长未受到明显抑制,此时容积负荷为22-24kgCOD/(m3>·d),COD去除率为80%,SO42-去除率为58.8%;向反应器投加适量FeCl2可很好地解除S2-的抑制. 相似文献
96.
97.
IntroductionChlorobenzoic acids ( CBAs ) are important chemicalproducts and extensive used as the intermediate and analysisreagent in many industrial fields(Zhang, 2001). Therefore,CBAs may directly and constantly release into environment,and it was a… 相似文献
98.
C9-AA水溶性石油树脂的制备及其阻垢性能 总被引:7,自引:0,他引:7
以乙烯生产过程中的副产物C9馏分和丙烯酸为原料,采用自由基溶液聚合,合成具有阻垢性能的C9-AA水溶性石油树脂。考察了引发剂AIBN和溶剂的加入量、C9-AA加入量、Ca^2+浓度、循环冷却水pH和养护时间对C9-AA水溶性石油树脂阻垢性能的影响,并对其阻垢效果进行了评价。在Ca^2+质量浓度小于或等于600mg/L、循环冷却水pH小于或等于9.3、C9-AA水溶性石油树脂加入量大于或等于15mg/L的条件下,C9—AA水溶性石油树脂对循环冷却水的阻垢率达到90%以上,其有效作用时间为60h。 相似文献
99.
自催化法合成聚天冬氨酸 总被引:1,自引:0,他引:1
以马来酸酐和乙酸铵为原料,在微波条件下用自催化法合成了聚天冬氨酸(PASP)。通过正交实验确定了最佳合成条件:n(乙酸铵):n(马来酸酐)=1.2,微波功率为1200W,反应时间为10min。在最佳合成条件下,PASP的收率为91.6%,PASP的黏均相对分子质量约为1.5×10^4。经红外光谱表征和核磁共振氢谱测试结果表明,PASP的各种主要官能团表现明显。当Ca^2+质量浓度为250mg/L、PASP加入量为3mg/L时,PASP的阻垢率达到95%,表明PASP具有较好的阻垢性能。 相似文献
100.
Pambrun V Marquot A Racault Y 《Environmental science and pollution research international》2008,15(7):592-599
Background, aims, and scope Sometimes, urban wastewaters convey a more or less significant part of toxic products from industries or the craft industry.
Nitrifying activity can be affected by these substances, implying higher ammonia concentrations in the outlet effluent and
contributing to toxicity for the aquatic environment. Moreover, the more stringently treated wastewater standards now require
a reliable treatment for nitrogen. One of the key issues is the identification of the inhibition behavior of nitrifying bacteria
facing a toxic substance. This new understanding could then finally be integrated into models in order to represent and to
optimize wastewater treatment plants (WWTP) operation in cases involving ‘toxic scenarios’.
Materials and methods The toxic substances studied in this work, cadmium and 3.5-dichlorophenol (3.5-DCP), are representative of chemical substances
commonly found in municipal sewage and industrial effluents and symbolize two different contaminant groups. The effects of
Cd and 3.5-DCP on nitrification kinetics have been investigated using respirometry techniques.
Results IC50 values determination gives concentrations of 3.1 mg/L for 3.5-DCP and 45.8 mg/L for Cd at 21 ± 1°C. The variation to
low temperature seems to have no real effect on IC50 for DCP, but induces a decrease of cadmium IC50 to 27.5 mg/L at 14°C.
Finally, specific respirometric tests have been carried out in order to determine the potential effect of these toxic substances
on the nitrifying decay rate b
a
. No significant effect has been noticed for Cd, whereas the presence of 3.5-DCP (at IC50 concentration) induced a dramatic
increase of b
a
at 20°C. The same behavior has been confirmed by experiments performed in winter periods with a sludge temperature around
12°C.
Discussion The target substances have different modes of action on activity and mortality, notably due to the abilities of the contaminant
to be precipitated, accumulated, or even to be progressively degraded. Studies realized at low temperature confirmed this
assumption, and put in evidence the effect of temperature on toxic substances capable of being biosorbed. However, the change
in the sludge sample characteristics can be pointed out as a problem in the investigation of the temperature effect on nitrification
inhibition, as biosorption, bioaccumulation, and predation are directly linked to the sludge characteristics (VSS concentration,
temperature) and the plant operating conditions (loading rates, sludge age, etc.).
Conclusions This work brings new understandings concerning the action mode of these specific contaminants on nitrifying bacteria and,
in particular, on the role of temperature. The experiments lead to the determination of the IC50 values for both toxic substances
on biological nitrification. The inhibition mechanisms of Cd and 3.5-DCP on nitrifying activity have been simply represented
by a non-competitive inhibition model.
Recommendations and perspectives Other experiments carried out in a continuous lab-scale pilot plant should be done with a proper control of the operating
conditions and of the sludge characteristics in order to better understand the mechanisms of nitrification inhibition for
each contaminant. Finally, these first results show that toxic substances can have an effect on the growth rate but also on
the decay rate, depending on the characteristics of the toxic substance and the sludge. This eventual double effect would
imply different strategies of WWTP operation according to the behavior of the contaminant on the bacteria. 相似文献