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污泥驯化和共代谢对吡啶和苯降解特性的研究 被引量:2

Study on Biodegradation Characteristics of Pyridine and Benzene by Activated Sludge Acclimation and CO-metabolism
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摘要 利用瓦氏呼吸仪测定微生物耗氧量的方法,研究了焦化废水及其中难降解有机污染物吡啶、苯的降解特性,并对吡啶和苯分别与苯酚共基质条件下的可生化性进行了研究。结果表明,pH值为7.2时,焦化废水降解率最高;当浓度小于40mg/L时,吡啶和苯可以部分被降解,浓度大于60mg/L时微生物呼吸作用明显地被抑制;污泥驯化有利于有机污染物降解速率的提高。初步分析了共代谢降解焦化废水中难降解有机污染物的生理生化特性。 Adopting Warburg respirometer to measure oxygen consuming, biodegradation characteristics of coke plant wastewater and the refractory organics of pyri-dine and benzene, under the condition of co-substrate with chlorobenzene has been studied. The result showed that when pH was 7.2, the rate of coke plant waste-water biodegrading was encouraging. Under lower concentration of 40mg/L, pyridine and benzene could be degraded partly, and when concentration was higher than 60mg/L, they inhibited microorganism respiration obviously. Acclimation of activated sludge is helpful for improving the degrading speed of refractory organics. The characteristics of co-metabolism of refractory organics in coke plant wastewater was known preliminarily, which is important and useful for the deeply treatment of coke plant wastewater.
作者 葛红光 孙先锋 习艳丽
机构地区 西安建筑科技大学环境与市政工程学院 西安市卫生防疫站
出处 《上海环境科学》 CAS CSSCI CSCD 北大核心 2002年第3期169-171,共3页 Shanghai Environmental Sciences
关键词 降解特性 焦化废水 吡啶 苯酚 共代谢 污泥驯化 瓦氏呼吸仪 废水处理 Coke plant wastewater Pyridine Benzene Phenol Co-metabolism Activated sludge acclimation Warburg respirometr
分类号 X784 [环境科学与工程—环境工程]
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  • 1何苗,张晓健,瞿福平,顾夏声.焦化废水中芳香族有机物及杂环化合物在活性污泥法处理中的去除特性[J].中国给水排水,1997,13(1):14-17. 被引量:73
  • 2Azhar N G, Stuckey D C. The influence of chemical structure on the anaerobic catabolism of refractory compounds: A case study of instant coffee wastes. Water Science and Technology, 1994, 30(12): 223-232
  • 3Sims G K, Sommers L E, Konopka A. Degradation of pyridine by Micrococcus luteus isolated from soil. Applied and Environmental Microbiology, 1986, 51(5): 963-968
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  • 5Rhee S K, Lee G M, Yoon J H, et al. Anaerobic and aerobic degradation of pyridine by a newly isolated denitrifying bacterium. Applied and Environmental Microbiology, 1997, 63(7): 2578-2585
  • 6Yoon J H, Kang S S, Cho Y G. Rhodococcus pyridinovorans sp nov., a pyridine-degrading bacterium.International Journal of Systematic and Evolutionary Microbiology, 2000, 50:2173-2180
  • 7Brinkmann U, Babel W. Simultaneous utilization of pyridine and fructose by Rhodococcus opacus UFZ B 408 without an external nitrogen source. Applied Microbiology and Biotechnology, 1996, 45 (1-2): 217-223
  • 8Mohana S V, Sistla S, Gurua R K, et al. Microbial degradation of pyridine using Pseudomonas sp. and isolation of plasmid responsible for degradation. Waste Management, 2003, 23(2) : 167-171
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上海环境科学
2002年 第3期

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