实际重力流排水管道中微生物群落对管道的腐蚀影响

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摘要

通过在实际重力流排水管道中选取10个典型的腐蚀区域作为研究对象，通过对排水管道对应腐蚀区域的生物膜和水体进行采样，探究实际排水管道不同空间位置上微生物群落分布的差异性以及水质因素对微生物群落多样性分布影响.采用高通量测序方法反映腐蚀区域微生物群落的多样性.结果表明，在排水管道中10个典型腐蚀区域中的微生物群落分布结构基本相似，在门水平上主要是变形菌占绝对优势，其次是放线菌门，在纲水平上主要是a-变形菌纲，其次是β-变形菌纲两者相对含量之和占到43.56%，在属水平上的硫酸盐还原菌对管道具有严重的局部腐蚀，包含有Desulforhabdus，Desulfuromonas，Desulfobacter.RDA环境影响因子研究发现，在门水平上硫化氢、溶解氧与微生物群落存在一定的相关性，在纲水平上与微生物群落存在相关性的主要是铵根离子、pH值和COD.

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	申屠华斌
	张逸夫
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	王浩
	柳景青

关键词 ：排水管道, 微生物群落, 高通量测序, 管道腐蚀

Abstract：

To explore the differences in microbial community distribution and the influences of water quality on the correlation of microbial community diversity distribution, the biofilms and bulk water in 10 typical corrosive segments in actual gravity flow drainage pipes were sampled as the research objects. The diversities of microbial communities in corroded areas were presented by high-throughput sequencing. The results showed the microbial community structures in these 10typical corrosive parts were basically similar. Proteobacteria were the dominant bacteria in phylum level, followed by Actinobacteria. Alpha-proteobacteria and Beta-proteobacteria account for 43.56% in class level. In genus level, Sulfate reducing bacterium caused severe localized corrosion in pipes, including Desulforhabdus, Desulfuromonas and Desulfobacter. RDA Environmental impact factor analysis pointed out there was certain correlation between sulfuretted hydrogen, dissolve oxygen and microbial community in phylum level. Besides, ammonium ion, pH and COD are the main chemical factors in class level which have correlations with microbial communities.

Key words： drainage pipe microbial community high-throughput sequencing pipe corrosion

收稿日期: 2018-07-23

X172

基金资助:

国家自然科学基金面上资助项目（51678520）；水体污染控与治理国家科技重大专项资助项目（2017ZX07201004）

通讯作者: 柳景青,教授,Liujingqing@zju.edu.cn E-mail: Liujingqing@zju.edu.cn

作者简介: 申屠华斌(1991-),浙江金华人,男,浙江大学硕士研究生.主要从事给排水设计与研究工作.发表论文3篇.

引用本文:

申屠华斌, 张逸夫, 钱栋, 王浩, 柳景青. 实际重力流排水管道中微生物群落对管道的腐蚀影响[J]. 中国环境科学, 2018, 38(11): 4284-4288. SHENTU Hua-bin, ZHANG Yi-fu, QIAN Dong, WANG Hao, LIU Jing-qing. Effect of microbial community on pipe corrosion in the actual gravity flow drainage pipe. CHINA ENVIRONMENTAL SCIENCECE, 2018, 38(11): 4284-4288.

链接本文:

http://www.zghjkx.com.cn/CN/ 或 http://www.zghjkx.com.cn/CN/Y2018/V38/I11/4284

[1]	Hong H P. Inspection and maintenance planning of pipeline under external corrosion considering generation of new defects[J]. Strctural Safety. 1999,21(3):1123-1131.
[2]	Vlyssides A, Barampouti E M, Mai S, et al. Degradation of methylparathion in aqueous solution by electrochemical oxidation[J]. Environmental Science and Technology, 2004,22(38):6125-6131.
[3]	Whobbsa M G. Nature of the thaumasite sulfate attack mechanism in field concrete[J]. Cement and Concrete Research, 2000,4(30):529-533.
[4]	Wang H, Hu C, Zhang L, et al. Effects of microbial redox cycling of iron on cast iron pipe corrosion in drinking water distribution systems[J]. Water Research, 2014,65:362-370.
[5]	Fabbricino M, Korshin G V. Changes of the corrosion potential of iron in stagnation and flow conditions and their relationship with metal release[J]. Water Research, 2014,62:136-146.
[6]	Zhang X, Mi Z, Wang Y, et al. A red water occurrence in drinking water distribution systems caused by changes in water source in Beijing, China:mechanism analysis and control measures[J]. Frontiers of Environmental Science & Engineering, 2014,8(3):417-426.
[7]	Sun H, Shi B, Bai Y, et al. Bacterial community of biofilms developed under different water supply conditions in a distribution systems[J]. Science of the Total Environment, 2014,472(1):99-107.
[8]	Chen L, Jia R, Li L. Bacterial community of iron tubercles from a drinking water distribution system and its occurrence in stagnant tap water[J]. Environmental Science:Processes & Impacts, 2013,15(7):1332-1339.
[9]	Shamsaei H, Jaafar I O, Basri N. Effects Velocity Changes on the Water Quality in Water Distribution Systems[J]. Research Journal of Applied Sciences Engineeri, 2013,(12):678-685.
[10]	Ren H X, Wang W, Liu Y. Pyrosequencing analysis of bacteria communities in biofilm from different pipe materials in a city drinking water distribution systems of East China[J]. Environmental Biotechnology, 2015,99:10713-10724.
[11]	Gerke T L, Maynard J B, Schock M R, et al. Physiochemical characterization of five iron tubercles from a single drinking water distribution system:Possible new insights on their formation and growth[J]. Corrosion Science, 2008,50(7):2030-2039.
[12]	Caporaso J G, Kuczynski J, Stombaugh J, et al. QⅡME allows analysis of high-throughput community sequencing data[J]. Nat. Methods, 2010,7(5):335-336.