| 1,431 | 26 | 112 |
| 下载次数 | 被引频次 | 阅读次数 |
混凝土的微生物腐蚀(MICC)是当今全球面临的一个问题。下水管道中的H2S和一些硫化合物被硫氧化细菌首先氧化成生物硫酸,随后生物硫酸与混凝土中富钙相发生一系列反应生成石膏和膨胀性的钙矾石,而且还会造成水化硅酸钙分解,形成不溶且无胶结作用的胶体,进而导致混凝土的劣化。为了进一步加深对这个研究领域的理解,主要从混凝土的微生物腐蚀机理、影响因素、试验方法、评价指标、防护措施等方面详细介绍了国内外MICC的研究现状,以期希望得到更多学者的关注。
Abstract:Microbial corrosion of concrete(MICC) is still a problem in concrete engineering. The H2 S and some sulfur compounds in the sewer pipe are oxidized by sulfur oxidizing bacteria to produce biological sulfuric acid, which reacts with the calcium-rich phase in concrete to form gypsum and expansive ettringite and decomposes hydrated calcium silicate formation of insoluble and non-cemented colloids, thus leading to the deterioration of concrete. This review mainly represented recent research work on MICC aspects, including microbial corrosion mechanism, influencing factors, test methods, evaluation indexes and protection measures of concrete as well.
[1] JIANG G, ZHOU M, CHIU T H, et al. Wastewater-enhanced microbial corrosion of concrete sewers[J]. Environ Technol, 2016, 50(15):8084–8092.
[2] PARKER, IMMUNOLOGY C J, BIOLOGY C. The corrosion of concrete[J]. Immunol Cell Biol, 1945, 23(2):91–98.
[3] VOLLERTSEN J, NIELSEN A H, JENSEN H S, et al. Corrosion of concrete sewers-The kinetics of hydrogen sulfide oxidation[J]. Sci Total Environ, 2008, 394(1):162–170.
[4] WAHSHAT T M. Sulfur mortar and polymer modified sulfur mortar lining for concrete sewer pipe[D]. Ames:Lowa State University, 2001.
[5]林魁.生物硫酸对SAC海砂混凝土劣化及氯离子固化影响[D].福州:福州大学, 2016.LIN Kui. Effect of biological sulfuric acid on deterioration and chloride ion curing of sac sea sand concrete(in Chinese, dissertation).Fuzhou:Fuzhou University, 2016.
[6] MONTENY J, BELIE N D, VINCKE E, et al. Chemical and microbiological tests to simulate sulfuric acid corrosion of polymer-modified concrete[J]. Cem Concr Res, 2001, 31(9):1359–1365.
[7] MONTENY J, VINCKE E, BEELDENS A, et al. Chemical,microbiological, and in situ test methods for biogenic sulfuric acid corrosion of concrete[J]. Cem Concr Res, 2000, 30(4):623–634.
[8] ALEXANDER M G, FOURIE C J M, STRUCTURES. Performance of sewer pipe concrete mixtures with portland and calcium aluminate cements subject to mineral and biogenic acid attack[J]. Mater Struct,2011, 44(1):313–330.
[9] DIERCKS M, SAND W, BOCK E J C, et al. Microbial corrosion of concrete[J]. CMLS, 1991, 47(6):514–516.
[10] GRENGG C, MITTERMAYR F, BALDERMANN A, et al.Microbiologically induced concrete corrosion:A case study from a combined sewer network[J]. Cem Concr Res, 2015, 77:16–25.
[11] ISLANDER R L, DEVINNY J S, MANSFELD F, et al.Microbialecology of crown corrosion in sewers[J]. J Environ Eng,1991, 117(6):751–770.
[12] LI X, KAPPLER U, JIANG G M, et al. The ecology of acidophilic micro organisms in the corroding concrete sewer environment[J]. Front Microbiol, 2017(8):683.
[13] LING A L, ROBERTSON C E, HARRIS J K, et al. High-resolution microbial community succession of microbially induced concrete corrosion in working sanitary manholes[J]. Plos One, 2015, 10(3):0116400.
[14] MORI T, KOGA M, HIKOSAKA Y, et al. Microbial corrosion of concrete sewer pipes, H2S production from sediments and determination of corrosion rate[J]. Water Sci Technol, 1991, 23(7/9):1275–1282.
[15] MORI T, NONAKA T, TAZAKI K, et al. Interactions of nutrients,moisture and pH on microbial corrosion of concrete sewer pipes[J].Water Res, 1992, 26(1):29–37.
[16] OKABE S, ODAGIRI M, ITO T, et al. Succession of sulfur-oxidizing bacteria in the microbial community on corroding concrete in sewer systems[J]. Appl Environ Microbiol, 2007, 73(3):971–980.
[17] PADIVAL N A, WEISS J S, ARNOLD R G. Control of thiobacillus by means of microbial competition-implications for corrosion of concrete sewers[J]. Water Environ Res, 1995, 67(2):201–205.
[18] PARKER C D. Mechanics of corrosion of concrete sewers by hydrogen sulfide[J]. Sewage Industr Wastes, 1951, 23(12):1477–1485.
[19] SAND W, BOCK E J E T L. Concrete corrosion in the Hamburg sewer system[J]. Eviron Technol Lett, 1984, 5(12):517–528.
[20] SARICIMEN H, SHAMEEM M, BARRY M S, et al. Durability of proprietary cementitious materials for use in wastewater transport systems[J]. Cem Concr Compos, 2003, 25(4/5):421–427.
[21] DAN W, DAN P, DANFORD M, et al. The effect of microstructure on microbiologically influenced corrosion[J]. JOM, 1993, 45(9):22–30.
[22] KULMAN F E J C H T. Microbiological corrosion of buried steel pipe[J]. Corros Houston Tx, 1953, 9(1):11–18.
[23] KONG L, FANG J, ZHOU X, et al. Assessment of coatings for protection of cement paste against microbial induced deterioration through image analysis[J]. Constr Build Mater, 2018, 191:342–353.
[24] KONG L, LIU C, CAO M, et al. Mechanism study of the role of biofilm played in sewage corrosion of mortar[J]. Constr Build Mater,2018, 164:44–56.
[25] LIJUAN, KONG, BEI, et al. Study on the applicability of bactericides to prevent concrete microbial corrosion[J]. Constr Build Mater, 2017149:1–8.
[26]韩静云,戴超,郜志海,等.混凝土的微生物腐蚀[J].材料导报,2002(10):45–47.HAN Jingyun, DAI Chao, GAO Zhihai, et al. Mater Rev(in Chinese),2002(10):45–47.
[27]乐建新,高培伟.混凝土中微生物的侵蚀机理及其控制的研究[J].山东建材, 2007, 28(5):61–63.LE Jianxin, GAO Peiwei. Shandong Build Mater(in Chinese), 2007,28(5):61–63.
[28]乐建新,闫亚楠,李小燕,等.微生物对混凝土的侵蚀机理及其控制的研究[J]江苏建材, 2006(3):14–16, 26.LE Jianxin, YAN Yanan, LI Xiaoyan, et al. Jiangsu Build Mater(in Chinese), 2006(3):14–16, 26.
[29]闻宝联.城市污水环境下混凝土腐蚀及耐久性研究[D].天津:天津大学, 2005.WEN Baolian. Research on Concrete Corrosion and Durability in Urban Sewage Environment(in Chinese, dissertation). Tianjin:Tianjin University, 2005.
[30]闻宝联,刘一然,王新刚,等.城市污水环境下混凝土腐蚀研究[C]//中国商品混凝土可持续发展论坛暨第五届全国商品混凝土技术交流大会论文集,昆明,中国, 2008:235–242.WEN Baolian, LIU Yiran, WAND Xingang, et al. Research on concrete corrosion in urban sewage environment[C]//China Commercial Concrete Sustainable Development Forum and the 5th National Commercial Concrete Technology Exchange Conference Proceedings, Kunming, China, 2008:235–242.
[31]孔丽娟,包昕,曹梦凡.生物膜对污水环境下混凝土腐蚀的影响[J].硅酸盐学报, 2016, 44(2):279–285.KONG Lijuan, BAO Xin, CAO Mengfan. J Chin Ceram Soc, 2016,44(2):279–285.
[32]张小伟,张雄.混凝土微生物腐蚀的作用机制和研究方法[J].建筑材料学报, 2006, 9(1):52–58.ZHANG Xiaowei, ZHANG Xiong. J Build Mater(in Chinese), 2006,9(1):52–58.
[33] MONTEN Y, AN D, VINCK E, et al. Chemical, microbiological, and in situ test methods for biogenic sulfuric acid corrosion of concrete[J].Cem Concr Res, 2000, 30(4):623–634.
[34] O’CONNELL M, MCNALLY C, RICHARDSON M G J C, et al.Biochemical attack on concrete in wastewater applications:A state of the art review[J]. Cem Concr Compos, 2010, 32(7):479–485.
[35] AYOUB G, AZAR N, FADEL M E, et al. Assessment of hydrogen sulphide corrosion of cementitious sewer pipes:a case study[J]. Urban Water J, 2004, 1(1):39–53.
[36] BANERJEE, MAHAPATRA M, BANERJEE D J M I. Fungal exopolysaccharide:production, composition and applications[J].Microbiol Insights, 2013(6):1–16.
[37] HEWAYDE E, NEHDI M, ALLOUCHE E, et al. Effect of geopolymer cement on microstructure, compressive strength and sulphuric acid resistance of concrete[J]. Mag Concr Res, 2006, 58(5):321–331.
[38] HOUSE M, WEISS W J. Review of microbially induced corrosion and comments on needs related to testing procedures[C]//International Conference on the Durability of Concrete Structures, West Lafayette,America, 2014:94–103.
[39] HOUSE M W J D, GRADWORKS T. Using biological and physico-chemical test methods to assess the role of concrete mixture design in resistance to microbially induced corrosion[J]. Dissert Theses Gradworks, 2013, 52(4):194.
[40] ZHANG L, SCHRYVER P D, GUSSEME B D, et al. Chemical and biological technologies for hydrogen sulfide emission control in sewer systems:A review[J]. Water Res, 2008, 42(1/2):1–12.
[41] WELLS P A, MELCHERS R E, BOND P. Factors involved in the long term corrosion of concrete sewers[C]//Australasian Corrosion Association Inc, Coffs Harbour, Australia, 2009:1–12.
[42]杨振杰,王玎,吴志强,等.硫化氢与硫酸腐蚀油井水泥石的对比[J].钻井液与完井液, 2012, 29(6):54–58,89–90.YANG Zhenjie, WANG Ding, WU Zhiqiang, et al. D C Fluid(in Chinese), 2012, 29(6):54–58,89–90.
[43]严思明,王杰,卿大咏,等.硫化氢对固井水泥石腐蚀研究[J].油田化学, 2010, 27(04):366–370, 394.YAN Siming, WANG Jie, QING Dayong, et al. Oilfield Chem(in Chinese), 2010, 27(4):366-370, 394.
[44] O’CONNELL M, MCNALLY C, RICHARDSON M G. Biochemical attack on concrete in wastewater applications:a state of the art review[J]. Cem Concr Compos, 2010, 32(7):479–485.
[45] YUAN H. Degradation modeling of concrete submitted to biogenic acid attack[J]. Cem Concr Res, 2015, 70:29–38.
[46] JIANG G, WIGHTMAN E, DONOSE B C, et al. The role of iron in sulfide induced corrosion of sewer concrete[J]. Water Res, 2014, 49:166–174.
[47] MEHTA P K, MONTEIRO P J M. Concrete:microstructure,properties, and materials[M]. Upper Saddle River:Prentice-Hall, 2013:1–239.
[48] JOSEPH A P, KELLER J, BUSTAMANTE H, et al. Surface neutralization and H2S oxidation at early stages of sewer corrosion:Influence of temperature, relative humidity and H2S concentration[J].Water Res, 2012, 46(13):4235–4245.
[49] ROBERTS D J, NICA D, ZUO G, et al. Quantifying microbially induced deterioration of concrete:initial studies[J]. Int Biodeterior Biodegrad, 2002, 49(4):227–234.
[50] VINCKE E, VERSTICHEL S, MONTENY J, et al. A new test procedure for biogenic sulfuric acid corrosion of concrete[J].Biodegradation, 1999, 10(6):421–428.
[51] BIELEFELDT A, GUTIERREZ-PADILLA M G D,OVTCHINNIKOV S, et al. Bacterial kinetics of sulfur oxidizing bacteria and their biodeterioration rates of concrete sewer pipe samples[J]. J Environ Eng, 2010, 136(7):731–738.
[52] GRANDCLERC A, DANGLA P, GUEGUEN-MINERBE M, et al.Modelling of the sulfuric acid attack on different types of cementitious materials[J]. Cem Concr Res, 2018, 105:126–133.
[53] PARKER C D. The corrosion of concrete[J]. Immunol Cell Biol, 1945,23(2):81–90.
[54] DOMINGO J W S, REVETTA R P, IKER B, et al. Molecular survey of concrete sewer biofilm microbial communities[J]. Biofouling, 2011,27(9/10):993–1001.
[55] KLEINJAN W E, KEIZER A D, JANSSEN A J H J C. Biologically produced sulfur[J]. Topics Curr Chem, 2004, 35(15):44–57.
[56] ISLANDER R L, DEVINNY J S, MANSFELD F, et al. Microbial ecology of crown corrosion in sewers[J]. J Environ Eng, 1991, 117(6):751–770.
[57] YONGSIRI C, VOLLERTSEN J, HVITVED-JACOBSEN T J J O E E.Effect of temperature on air-water transfer of hydrogen sulfide[J]. J Environ Eng, 2004, 130(1):104–109.
[58] HERISSON J J P E. Biodétérioration des matériaux cimentaires dans les ouvrages d'assainissement:étude comparative du ciment d'aluminate de calcium et du ciment Portland[D].?le-de-France:Paris East University, 2012.
[59] GU J D, FORD T E, BERKE N S, et al. Biodeterioration of concrete by the fungus Fusarium[J]. Int Biodeterior Biodegrad, 1998, 41(2):101–109.
[60] XIE Y, LIN X, JI T, et al. Comparison of corrosion resistance mechanism between ordinary portland concrete and alkali-activated concrete subjected to biogenic sulfuric acid attack[J]. Constr Build Mater, 2019, 228:117071.
[61] SCRIVENER K L, CAPMAS A. Calcium aluminate cements[J]. Leas Chem Cem Concr, 1998, 13:713–782.
[62] KILISWA M W, SCRIVENE K L, ALEXANDER M G. The corrosion rate and microstructure of Portland cement and calcium aluminate cement-based concrete mixtures in outfall sewers:A comparative study[J]. Cem Concr Res, 2019, 124:105818.
[63] EHRICH S, HELARD L, LETOURNEUX R, et al. Biogenic and chemical sulfuric acid corrosion of mortars[J]. J Mater Civ Eng, 1999,11(4):340–344.
[64] YANG W, VOLLERTSEN J, HVITVED-JACOBSEN T J W S, et al.Anoxic sulfide oxidation in wastewater of sewer networks[J]. Water Sci Technol, 2005, 52(3):191–199.
[65] WU L, HU C, LIU W J S. The sustainability of concrete in sewer tunnel—a narrative review of acid corrosion in the city of edmonton,canada[J]. Sustainability, 2018, 10(2):517.
[66] YUAN H, DANGLA P, CHATELLIER P, et al. Degradation modeling of concrete submitted to biogenic acid attack[J]. Cem Concr Res, 2015,70:29–38.
[67] SUN X, JIANG G, BOND P L, et al. A rapid, non-destructive methodology to monitor activity of sulfide-induced corrosion of concrete based on H2S uptake rate[J]. Water Res, 2014, 59:229-238.
[68] BELIE N D, MONTENY J, BEELDENS A, et al. Experimental research and prediction of the effect of chemical and biogenic sulfuric acid on different types of commercially produced concrete sewer pipes[J]. Cem Concr Res, 2004, 34(12):2223–2236.
[69] HEWAYDE E, NEHDI M L, ALLOUCHE E, et al. Using concrete admixtures for sulphuric acid resistance[J]. Constr Mater, 2007, 160:25–35.
[70] SIAD H, LACHEMI M, SAHMARAN M, et al. Effect of glass powder on sulfuric acid resistance of cementitious materials[J]. Constr Build Mater, 2016, 113:163–173.
[71] LAVIGNE M P, BERTRON A, AUER L, et al. An innovative approach to reproduce the biodeterioration of industrial cementitious products in a sewer environment. Part I:Test design[J]. Cem Concr Res. 2015, 73:246–256.
[72] SAND W, BOCK E, PERFORMANCE D C W J M. Biotest system for rapid evaluation of concrete resistance to sulfur-oxidizing bacteria[J].Mater Performance, 1987, 26(3):14–17.
[73] SOLEIMANI S, ISGOR O B, ORMECI B J J O M I C E. Effectiveness of e. coli biofilm on mortar to inhibit biodegradation by biogenic acidification[J]. J Mater Civil Eng, 2016, 28(4):04015167.1–04015167.9.
[74]高向玲,王丽娜,刘威.混凝土排水管道内部腐蚀研究[J].结构工程师, 2020, 36(02):71-79.GAO Xiangling, WANG Lina, LIU Wei. Struct Eng(in Chinese), 2020,36(02):71–79.
[75] POMEROY R D. The problem of hydrogen sulphide in sewers[R].London:Clay Pipe Development Association. Limited, 1990.
[76] JOSEPH A P, KELLER J, Bustamante H, et al. Surface neutralization and H2S oxidation at early stages of sewer corrosion:Influence of temperature, relative humidity and H2S concentration[J]. Water Res,2012, 46(13):4235–4245.
[77] WELLS T, MELCHERS R E. Modelling concrete deterioration in sewers using theory andfield observations[J]. Cem Concr Res, 2015,77:82–96.
[78] ESTOKOVA A, HARBULAKOVA V O, LUPTAKOVA A, et al.Study of the deterioration of concrete influenced by biogenic sulphate attack[J]. Procedia Eng, 2012, 42:1731–1738.
[79] BELIE N D, MONTENY J, BEELDENS A, et al. Experimental research and prediction of the effect of chemical and biogenic sulfuric acid on different types of commercially produced concrete sewer pipes[J]. Cem Concr Res, 2004, 34(12):2223–2236.
[80] BERNDT M L. Evaluation of coatings, mortars and mix design for protection of concrete against sulphur oxidising bacteria[J]. Constr Build Mater, 2011, 25(10):3893–3902.
[81] HONG H E, SHAN L U J J O B M. Study on the resistance of fly ash concrete to corrosion by city sewage[J]. J Build Mater, 1999, 2(4):314–318.
[82] BEELDENS A, MONTENY J, VINCKE E, et al. Resistance to biogenic sulphuric acid corrosion of polymer-modified mortars[J].Cem Concr Compos, 2001, 23(1):47–56.
[83] FIERTAK M, STANASZEK-TOMAL E B J P E. Biological corrosion of polymer-modified cement bound materials exposed to activated sludge in sewage treatment plants[J]. Procedia Eng, 2013, 65:335–340.
[84] MUYNCK W D, BELIE N D, VERSTRAETE W J C, et al.Effectiveness of admixtures, surface treatments and antimicrobial compounds against biogenic sulfuric acid corrosion of concrete[J].Cem Concr Compos, 2009, 31(3):163–170.
[85] BERNDT M L J C, MATERIALS B. Evaluation of coatings, mortars and mix design for protection of concrete against sulphur oxidising bacteria[J]. Constr Build Mater, 2011, 25(10):3893–3902.
[86] MAEDA T, NEGISHI A, UCHIDA H, et al. Thiobacillus thiooxidansgrowth inhibitor, cement composition,and cement structure[P]. EP Patent, 0956770. 1998–07–14.
[87] YAMANAKA T, ASO I, TOGASHI S, et al. Corrosion by bacteria of concrete in sewerage systems and inhibitory effects of formates on their growth[J]. Water Res, 2002, 36(10):2636–2642.
[88] HAILE T, NAKHLA G, ALLOUCHE E, et al. Evaluation of the bactericidal characteristics of nano-copper oxide or functionalized zeolite coating for bio-corrosion control in concrete sewer pipes[J].Corros Sci, 2010, 52(1):45–53.
[89] ZHANG X W, ZHANG X J M P. Present and prospect of microbial corrosion prevention of concrete[J]. Mater Protect, 2005(11):52.
[90] AMIN, KASHI, ALI, et al. Effect of cement based coatings on durability enhancement of GFRP-wrapped columns in marine environments[J]. Constr Build Mater, 2017, 137:307–316.
[91] WU Y, KRISHNAN P, YU L E, et al. Using lightweight cement composite and photocatalytic coating to reduce cooling energy consumption of buildings[J]. Constr Build Mater, 2017, 145:555–564.
[92] XIAO G, ZHANG X, ZHAO Y, et al. The behavior of active bactericidal and antifungal coating under visible light irradiation[J].Appl Surf Sci, 2014, 292:756–763.
[93] WANG R, NEOH K G, KANG E T J J O C, et al. Integration of antifouling and bactericidal moieties for optimizing the efficacy of antibacterial coatings[J]. J Colloid Interface Sci, 2015, 438:138–148.
[94] HUSAIN A, AL-SHAMAH O, ABDULJALEEL A J D. Investigation of marine environmental related deterioration of coal tar epoxy paint on tubular steel pilings[J]. Desalination, 2004, 166:295–304.
[95] VALENTINI C, FIORA J, YBARRA G J P I O C. A comparison between electrochemical noise and electrochemical impedance measurements performed on a coal tar epoxy coated steel in 3%Na Cl[J]. Prog Org Coat, 2012, 73(2/3):173–177.
[96] NGUYEN M D, BANG J W, BIN A S, et al. Novel polymer-derived ceramic environmental barrier coating system for carbon steel in oxidizing environments[J]. J Eur Ceram Soc, 2017, 37(5):2001–2010.
[97] HEWAYDE E H, NAKHLA G F, ALLOUCHE E N, et al. Beneficial impact of coatings on biological generation of sulfide in concrete sewer pipes[J]. Struct Infrastr Eng, 2007, 3(3):267–77.
[98] EDGE M, ALLEN N S, TURNER D, et al. The enhanced performance of biocidal additives in paints and coatings[J]. Prog Org Coat, 2001,43(1):10–17.
[99] WHITEKETTLEW K, TAFEL G J, ZHAO Q, et al. Method for controlling microbial biofilm in aqueous systems[P]. US Patent,0052656. 2011–03–03.
[100] SOEBBING J B, SKABO R R, MICHEL H E, et al. Rehabilitating water and wastewater treatment plants[J]. J PCL, 1996, 13(5):54–64.
基本信息:
DOI:10.14062/j.issn.0454-5648.20200415
中图分类号:TU528
引用信息:
[1]荣辉,於成龙,马国伟,等.污水环境下混凝土的微生物腐蚀研究进展[J].硅酸盐学报,2021,49(05):988-999.DOI:10.14062/j.issn.0454-5648.20200415.
基金信息:
国家自然科学基金项目(51978439,51708390); 天津市交通运输科技发展计划项目(2018-38); 中国博士后科学基金项目(2019M651000); 天津市轨道交通重大专项项目(18ZXGD GX00050); 天津市重点研发计划科技支撑计划重点项目(20YFZCSN00520)
2020-06-13
2020
2021-03-31
2021-01-19
2021
1
2021-04-12
2021-04-12
2021-04-12