微生物腐蚀与采出水的微生物防腐蚀——回顾与应用实例
|
摘要
针对油田采出水处理系统微生物腐蚀的特点,提出了以本源微生物群落中的假单胞菌、短芽孢杆菌和脱氮硫杆菌为主的微生物防腐蚀技术方案,讨论了微生物防腐蚀剂的室内评价结果与矿场应用情况,认为成本低、环境友好、持续时间长的微生物防腐蚀技术具有良好的应用前景。
According to the characteristics of oilfield produced water treatment system of microbial corrosion, it had been suggested that the pseudomonas, bacillus and thiobacillus denitrificans from indigenous microbial community could be microbiological Influenced corrosion inhibition(MICI). It had been discussed the MICI from laboratory evaluation to field application case. The characteristic of low cost, environment friendly and long duration of MICI technology has good application prospect.
According to the characteristics of oilfield produced water treatment system of microbial corrosion, it had been suggested that the pseudomonas, bacillus and thiobacillus denitrificans from indigenous microbial community could be microbiological Influenced corrosion inhibition(MICI). It had been discussed the MICI from laboratory evaluation to field application case. The characteristic of low cost, environment friendly and long duration of MICI technology has good application prospect.
引文
[1] Hou B R. The Cost of Corrosion in China[M]. Beijing:Science Press, 2017(侯保荣.中国腐蚀成本[M].北京:科学出版社, 2017)
[2] NACE IMPACT Study[EB/OL].(2016-12-01). http://impact.nace.org
[3] Zhang Y H, Xu C M, Cheng G X, et al. Pitting initiation of 316L stainless steel in the media of sulfate-reducing and iron-oxidizing bacteria[J]. Inorg. Mater., 2007, 43:614
[4] Baboian R. Corrosion Tests and Standards:Application and Interpre‐tation[M]. 2nd Ed. West Conshohocken PA:ASTM International,2005:367
[5] Little B J, Lee J S. Microbiologically Influenced Corrosion[M].New Jersey:Wiley, 2007
[6] Skovhus T L, Eckert R B, Rodrigues E. Management and control of microbiologically influenced corrosion(MIC)in the oil and gas in‐dustry--overview and a North Sea case study[J]. J. Biotechnol.,2017, 256:31
[7] Huang Y, Liu S J, Jiang C Y. Microbiologically influenced corrosion and mechanisms[J]. Microbiol. China, 2017, 44:1699(黄烨,刘双江,姜成英.微生物腐蚀及腐蚀机理研究进展[J].微生物学通报, 2017, 44:1699)
[8] Kermani M B, Harrop D. The impact of corrosion on oil and gas in‐dustry[J]. SPE Prod. Facilit., 1996, 11:186
[9] Maruthamuthu S, Kumar B D, Ramachandran S, et al. Microbial corrosion in petroleum product transporting pipelines[J]. Ind. Eng.Chem. Res., 2011, 50:8006
[10] Larsen J, Skovhus T L, Saunders A M, et al. Molecular identifica‐tion of MIC bacteria from scale and produced water:Similarities and differences[A]. Corrosion 2008[C]. New Orleans, Louisiana,2008
[11] Bradley A S, Leavitt W D, Johnston D T. Revisiting the dissimila‐tory sulfate reduction pathway[J]. Geobiology, 2011, 9:446
[12] Muyzer G, Stams A J M. The ecology and biotechnology of sul‐phate-reducing bacteria[J]. Nat. Rev. Microbiol., 2008, 6:441
[13] Ramesh S, Rajeswari S, Maruthamuthu S. Effect of inhibitors and biocide on corrosion control of mild steel in natural aqueous envi‐ronment[J]. Mater. Lett., 2003, 57:4547
[14] Zou C J, Tang Q W, Zhao P W, et al. Further study on the inclusion complex of 2-phosphonobutane-1, 2, 4-tricarboxylic acid withβ-cyclodextrin:A new insight of high inhibition efficiency for pro‐tecting steel corrosion[J]. J. Petrol. Sci. Eng., 2013, 103:29
[15] Santillan E F U, Choi W, Bennett P C, et al. The effects of biocide use on the microbiology and geochemistry of produced water in the Eagle Ford formation, Texas, U. S. A.[J]. J. Petrol. Sci. Eng.,2015, 135:1
[16] Ma R. Effect on chlorine dioxide disinfection technology applied in the oilfield water injection back[J]. Oil Gas Field Surf. Eng.,2016, 35(6):88(马荣.二氧化氯杀菌技术在油田回注水处理中的应用效果[J].油气田地面工程, 2016, 35(6):88)
[17] Gou S H, Yin T, Wu Y, et al. A review of the research into sulfate reducing bacteria Inhibitor for oilfield wastewater of water-flood‐ing[J]. Fine Chem., 2015, 32:481(苟绍华,尹婷,吴雁等.注水开发污水中硫酸盐还原菌抑制剂研究进展[J].精细化工, 2015, 32:481)
[18] Eckert R B, Skovhus T L. Advances in the application of molecu‐lar microbiological methods in the oil and gas industry and links to microbiologically influenced corrosion[J]. Int. Biodeterior. Bio‐degrad., 2018, 126:169
[19] Jayaraman A, Ornek D, Duarte D A, et al. Axenic aerobic biofilms inhibit corrosion of copper and aluminum[J]. Appl. Microbiol.Biotechnol., 1999, 52:787
[20] Wang M F, Liu H F, Xu L M. Applied research on the competitive growth of bacteria in biological control of MIC[J]. J. Chin. Soc.Corros. Prot., 2004, 24:159(汪梅芳,刘宏芳,许立铭.细菌竞争生长在微生物腐蚀防治中的应用研究[J].中国腐蚀与防护学报, 2004, 24:159)
[21] Xu P, Zhai Y J, Wang J, et al. To understand biomembranes from another perspective—The research progress of microbial corrosion and prevention[J]. Corros. Sci. Prot. Technol., 2016, 28:356(许萍,翟羽佳,王婧等.从新的视角理解生物膜—微生物防腐蚀研究进展[J].腐蚀科学与防护技术, 2016, 28:356)
[22] Wang X T, Xiang L B, Zhang Y X. Microorganism preparation and application evaluation on microbial enhanced high-pour point oil recovery in Liaohe Oilfield[J]. Lithol. Reserv., 2017, 29(5):162(王小通,向龙斌,张艺馨.辽河高凝油微生物采油菌剂研究及应用评价[J].岩性油气藏, 2017, 29(5):162)
[2] NACE IMPACT Study[EB/OL].(2016-12-01). http://impact.nace.org
[3] Zhang Y H, Xu C M, Cheng G X, et al. Pitting initiation of 316L stainless steel in the media of sulfate-reducing and iron-oxidizing bacteria[J]. Inorg. Mater., 2007, 43:614
[4] Baboian R. Corrosion Tests and Standards:Application and Interpre‐tation[M]. 2nd Ed. West Conshohocken PA:ASTM International,2005:367
[5] Little B J, Lee J S. Microbiologically Influenced Corrosion[M].New Jersey:Wiley, 2007
[6] Skovhus T L, Eckert R B, Rodrigues E. Management and control of microbiologically influenced corrosion(MIC)in the oil and gas in‐dustry--overview and a North Sea case study[J]. J. Biotechnol.,2017, 256:31
[7] Huang Y, Liu S J, Jiang C Y. Microbiologically influenced corrosion and mechanisms[J]. Microbiol. China, 2017, 44:1699(黄烨,刘双江,姜成英.微生物腐蚀及腐蚀机理研究进展[J].微生物学通报, 2017, 44:1699)
[8] Kermani M B, Harrop D. The impact of corrosion on oil and gas in‐dustry[J]. SPE Prod. Facilit., 1996, 11:186
[9] Maruthamuthu S, Kumar B D, Ramachandran S, et al. Microbial corrosion in petroleum product transporting pipelines[J]. Ind. Eng.Chem. Res., 2011, 50:8006
[10] Larsen J, Skovhus T L, Saunders A M, et al. Molecular identifica‐tion of MIC bacteria from scale and produced water:Similarities and differences[A]. Corrosion 2008[C]. New Orleans, Louisiana,2008
[11] Bradley A S, Leavitt W D, Johnston D T. Revisiting the dissimila‐tory sulfate reduction pathway[J]. Geobiology, 2011, 9:446
[12] Muyzer G, Stams A J M. The ecology and biotechnology of sul‐phate-reducing bacteria[J]. Nat. Rev. Microbiol., 2008, 6:441
[13] Ramesh S, Rajeswari S, Maruthamuthu S. Effect of inhibitors and biocide on corrosion control of mild steel in natural aqueous envi‐ronment[J]. Mater. Lett., 2003, 57:4547
[14] Zou C J, Tang Q W, Zhao P W, et al. Further study on the inclusion complex of 2-phosphonobutane-1, 2, 4-tricarboxylic acid withβ-cyclodextrin:A new insight of high inhibition efficiency for pro‐tecting steel corrosion[J]. J. Petrol. Sci. Eng., 2013, 103:29
[15] Santillan E F U, Choi W, Bennett P C, et al. The effects of biocide use on the microbiology and geochemistry of produced water in the Eagle Ford formation, Texas, U. S. A.[J]. J. Petrol. Sci. Eng.,2015, 135:1
[16] Ma R. Effect on chlorine dioxide disinfection technology applied in the oilfield water injection back[J]. Oil Gas Field Surf. Eng.,2016, 35(6):88(马荣.二氧化氯杀菌技术在油田回注水处理中的应用效果[J].油气田地面工程, 2016, 35(6):88)
[17] Gou S H, Yin T, Wu Y, et al. A review of the research into sulfate reducing bacteria Inhibitor for oilfield wastewater of water-flood‐ing[J]. Fine Chem., 2015, 32:481(苟绍华,尹婷,吴雁等.注水开发污水中硫酸盐还原菌抑制剂研究进展[J].精细化工, 2015, 32:481)
[18] Eckert R B, Skovhus T L. Advances in the application of molecu‐lar microbiological methods in the oil and gas industry and links to microbiologically influenced corrosion[J]. Int. Biodeterior. Bio‐degrad., 2018, 126:169
[19] Jayaraman A, Ornek D, Duarte D A, et al. Axenic aerobic biofilms inhibit corrosion of copper and aluminum[J]. Appl. Microbiol.Biotechnol., 1999, 52:787
[20] Wang M F, Liu H F, Xu L M. Applied research on the competitive growth of bacteria in biological control of MIC[J]. J. Chin. Soc.Corros. Prot., 2004, 24:159(汪梅芳,刘宏芳,许立铭.细菌竞争生长在微生物腐蚀防治中的应用研究[J].中国腐蚀与防护学报, 2004, 24:159)
[21] Xu P, Zhai Y J, Wang J, et al. To understand biomembranes from another perspective—The research progress of microbial corrosion and prevention[J]. Corros. Sci. Prot. Technol., 2016, 28:356(许萍,翟羽佳,王婧等.从新的视角理解生物膜—微生物防腐蚀研究进展[J].腐蚀科学与防护技术, 2016, 28:356)
[22] Wang X T, Xiang L B, Zhang Y X. Microorganism preparation and application evaluation on microbial enhanced high-pour point oil recovery in Liaohe Oilfield[J]. Lithol. Reserv., 2017, 29(5):162(王小通,向龙斌,张艺馨.辽河高凝油微生物采油菌剂研究及应用评价[J].岩性油气藏, 2017, 29(5):162)