Effect of SRB on Corrosion of Q235 Steel During Vaporation of Water in Soil

J Chin Soc Corr Pro

2005, Vol. 25

Issue (5): 307-311 DOI:

Research Report

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Effect of SRB on Corrosion of Q235 Steel During Vaporation of Water in Soil

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中国科学院金属研究所

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Abstract The effects of sulfate reducing bacterial (SRB) on corrosion of Q235 steel during the evaporation of water in soils have been studied by using bacterial analyses,polarization curves,electrochemical impedance spectroscopy(EIS),scanning electron microscopy (SEM) and EDS. The results showed that the number of SRB gradually decreased with the naturally evaporating of water in soil,and the corrosion rate of Q235 steel gradually increases along with the evaporation of water in soils,and the increasing of corrosion rate in soil with SRB was more severe than that in soil without SRB.

Key words: sulfate reducing bacterial(SRB) soil water Q235 steel MIC

Received: 11 February 2004

ZTFLH:

TG172.4

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;. Effect of SRB on Corrosion of Q235 Steel During Vaporation of Water in Soil. J Chin Soc Corr Pro, 2005, 25(5): 307-311 .

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https://www.jcscp.org/EN/ OR https://www.jcscp.org/EN/Y2005/V25/I5/307

[1]Weng Y J.Effect of soil moisture on corrosion velocity of pipelinesteel[J].Corros.Prot.,1990,11(6):285-288(翁永基.土壤湿度对管道钢腐蚀速率的影响[J].腐蚀与防护,1990,11(6):285-288)
[2]The Selected Information of the National Soil Corrosion Test Net-works&Stations,No.1,1987:101(国家科委全国土壤腐蚀试验网,全国土壤腐蚀试验网站资料选编,第一集,1987:101)
[3]Li M C,Lin H C,Cao C N.Influence of moisture content on soil cor-rosion behavior of carbon steel[J].Corros.Sci.Prot.Technol.,2000,12(4):218-233(李谋成,林海潮,曹楚南.湿度对钢材料在中性土壤中腐蚀行为的影响[J].腐蚀科学与防护技术,2000,12(4):218-233)
[4]Tang H Y,Song G L,Cao C N,Lin H C.Study on corrosion of car-bon steel in soils by polarization measurements[J].Corros.Sci.Prot.Technol.,1995,7(4):285-292(唐红雁,宋光铃,曹楚南,林海潮.用极化曲线评价钢铁材料土壤腐蚀行为研究[J].腐蚀科学与防护技术,1995,7(4):285-292)
[5]Li S,Kim Y,Jeon K,Kho Y.Microbiologically influenced corrosionof underground pipeline under the disbanded coatings[J].Metals andMaterials-Korea,2000,6(3):123-127
[6]Li S,Kim Y,Jeon K,Kho Y,Kang T.Microbiologically influencedcorrosion of carbon steel exposed to anaerobic soil[J].Corrosion,2001,57(9):23-28
[7]Gao D C,Wei X F,Xing D K.Analysis on corrosion reason ofShenyang-Fushun oil pipeline[J].Oil&Gas Storage and Trans-portation,1995,14(1):48-51(高德春,魏晓峰,行登恺.沈抚输油管道腐蚀原因分析[J].油气储运,1995,14(1):48-51)
[8]Pikas J.Case histories of external microbiologically influenced corro-sion underneath disbonded coatings[A].Corrosion/96[C].NACE,Houston,Texas,1996,198
[9]Liu H F,Liu L W,Xu L M.Effects of bio-film on corrosion of car-bon steel[J].J.Chin.Soc.Corros.Prot.,1999,19(5):291-294(刘宏芳,刘烈炜,许立铭.生物膜对碳钢腐蚀的影响[J].中国腐蚀与防护学报,1999,19(5):291-294)
[10]Jack T R,Wilmoot M J.Indicator minerals formed during externalcorrosion of line pipe[J].Material Performance,1995,11:19-22
[11]Tang H Q.Function of dissociation oxygen in microbiologically in-fluenced corrosion[J].Mater.Prot.,1992,25(4):23-26(唐和清.微生物腐蚀中游离氧的作用[J].材料保护,1992,25(4):23-26)
[12]Jack T R,Wilmoot M J.Corrosion consequences of secondary oxi-dation of microbial corrosion[J].Corrosion,1998,54(3):246-252

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