Analysis of Concrete Corrosion of Manhole Located Near Source of Odorous Emission

[1] Błaszczyk, W. (1983). Sewers. Networks and pumping stations. (in Polish) Warszawa: Arkady. Błaszczyk W. 1983 Sewers. Networks and pumping stations. (in Polish) Warszawa Arkady Search in Google Scholar

[2] Haile, T., Nakhla, G., Allouche E. (2008). Evaluation of the resistance of mortars coated with silver bering zeolite to bacterial-induced corrosion. Corrosion Science 50, 713–720. Haile T. Nakhla G. Allouche E. 2008 Evaluation of the resistance of mortars coated with silver bering zeolite to bacterial-induced corrosion Corrosion Science 50 713 720 10.1016/j.corsci.2007.08.012 Search in Google Scholar

[3] Haile, T., Nakhla, G., Allouche, E., Vaidya, S. (2010). Evaluation of the bactericidal characteristics of nanocopper oxide or functionalized zeolite coating for biocorrosion control in concrete sewer pipes. Corrosion Science 52, 45–53. Haile T. Nakhla G. Allouche E. Vaidya S. 2010 Evaluation of the bactericidal characteristics of nanocopper oxide or functionalized zeolite coating for biocorrosion control in concrete sewer pipes Corrosion Science 52 45 53 10.1016/j.corsci.2009.08.046 Search in Google Scholar

[4] Jasiński, K., Gil, B. (2014). Corrosion of concrete in sanitary sewage – a forgotten problem. The Silesian University of Technology. New technologies in water supply and sewage networks and installations (in Polish), 169–188. Jasiński K. Gil B. 2014 Corrosion of concrete in sanitary sewage – a forgotten problem. The Silesian University of Technology New technologies in water supply and sewage networks and installations (in Polish) 169 188 Search in Google Scholar

[5] Pląskowski, Z. Roman M. (1975). Building constructions in a sewage treatment plant. Warszawa: Arkady. Pląskowski Z. Roman M. 1975 Building constructions in a sewage treatment plant. Warszawa Arkady Search in Google Scholar

[6] PN-88/B-01807: Anticorrosive protection in construction. Concrete and reinforced concrete constructions. Principles of construction diagnostics. PN-88/B-01807 Anticorrosive protection in construction. Concrete and reinforced concrete constructions. Principles of construction diagnostics Search in Google Scholar

[7] PN-EN 206-1. Concrete. Part 1: Requirements, properties, production and compliance. PN-EN 206-1 Concrete. Part 1: Requirements, properties, production and compliance Search in Google Scholar

[8] Cwalina, B. (2008). Biodeterioration of concrete. Architecture Civil Engineering Environment, 4, 133–140. Cwalina B. 2008 Biodeterioration of concrete Architecture Civil Engineering Environment 4 133 140 Search in Google Scholar

[9] O’Connell, M., McNally, C., Richardson, M.G. (2010). Biochemical attack on concrete in wastewater applications: A state of the art review. Cement and Concrete Composites, 32, 479–485. O’Connell M. McNally C. Richardson M.G. 2010 Biochemical attack on concrete in wastewater applications: A state of the art review Cement and Concrete Composites 32 479 485 10.1016/j.cemconcomp.2010.05.001 Search in Google Scholar

[10] Saricimen, H. Shameem, M. Barry, M.S. Ibrahim, M. Abbasi, T.A. (2003). Durability of proprietary cementitious materials for use in wastewater transport systems. Cement and Concrete Composites, 25(4–5), 421–427. Saricimen H. Shameem M Barry M.S. Ibrahim M. Abbasi T.A. 2003 Durability of proprietary cementitious materials for use in wastewater transport systems Cement and Concrete Composites 25 4–5 421 427 10.1016/S0958-9465(02)00082-3 Search in Google Scholar

[11] Grengg, C. Mittermayr, F. Baldermanna, A. Böttcher, M.E. Leis, A. Koraimanne, G. Grunert, P. Dietzel, M. (2015). Microbiologically induced concrete corrosion: A case study from a combined sewer Network. Cement and Concrete Research, 77, 16–25. Grengg C. Mittermayr F. Baldermanna A. Böttcher M.E. Leis A. Koraimanne G. Grunert P. Dietzel M. 2015 Microbiologically induced concrete corrosion: A case study from a combined sewer Network Cement and Concrete Research 77 16 25 10.1016/j.cemconres.2015.06.011 Search in Google Scholar

[12] Rao, T. S., Sairam, T. N., Viswanathan, B., Nair, K.V.K. (2000). Carbon steel corrosion by iron oxidising and sulphate reducing bacteria in a freshwater cooling system. Corrosion Science, 42(8), 1417–1431. Rao T. S. Sairam T. N. Viswanathan B. Nair K.V.K. 2000 Carbon steel corrosion by iron oxidising and sulphate reducing bacteria in a freshwater cooling system Corrosion Science 42 8 1417 1431 10.1016/S0010-938X(99)00141-9 Search in Google Scholar

[13] Kośmider, J., Mazur-Chrzanowska, B., Wyszyński, B. (2002). Odors. (in Polish) Warszawa: Wydawnictwa Naukowe PWN. Kośmider J. Mazur-Chrzanowska B. Wyszyński B. 2002 Odors. (in Polish) Warszawa Wydawnictwa Naukowe PWN Search in Google Scholar

[14] Dieter, W. (2001). Municipal sewage pumping stations. (in Polish.) Warszawa: Wydawnictwo SeidelPrzywecki Sp. z o.o. Dieter W. 2001 Municipal sewage pumping stations. (in Polish.) Warszawa Wydawnictwo SeidelPrzywecki Sp. z o.o Search in Google Scholar

[15] Dąbrowski, W. (2004). The impact of sewerage systems on the environment. (in pol.) Kraków: Wydawnictwo Politechnika Krakowska im. Tadeusza Kościuszki. Dąbrowski W. 2004 The impact of sewerage systems on the environment. (in pol.) Kraków Wydawnictwo Politechnika Krakowska im. Tadeusza Kościuszki Search in Google Scholar

[16] Gil, B., Kawczyński, A. (2017). The analysis of sewer network damage. (in pol.) BK: Optimization of devices and methods in water supply and sewage disposal of urban agglomerations. Silesian University of Technology. Gil B. Kawczyński A. 2017 The analysis of sewer network damage. (in pol.) BK: Optimization of devices and methods in water supply and sewage disposal of urban agglomerations Silesian University of Technology Search in Google Scholar

[17] Witherspoon, J. (2008). Minimization of Odors and Corrosion in Collection Systems. WERF Research Report Series. IWA Publishing. Witherspoon J. 2008 Minimization of Odors and Corrosion in Collection Systems WERF Research Report Series IWA Publishing Search in Google Scholar

[18] Łowińska-Kluge, A. (2008). Copper slag as an ingredient of cement composites with increased durability. (in pol.) Rozprawy, nr 419, Poznań: Publisher of Poznan University of Technology. Łowińska-Kluge A. 2008 Copper slag as an ingredient of cement composites with increased durability. (in pol.) Rozprawy, nr 419 Poznań Publisher of Poznan University of Technology Search in Google Scholar

[19] Cywiński, B., Gdula, St., Kempa E., Kurbiel J., Płoszański H. (1983). Wastewater treatment. Part 1. Mechanical and chemical treatment. (in Polish) Warszawa: Arkady. Cywiński B. Gdula St. Kempa E. Kurbiel J. Płoszański H. 1983 Wastewater treatment Part 1. Mechanical and chemical treatment. (in Polish) Warszawa Arkady Search in Google Scholar

[20] PN-80/B-01800. Anticorrosive protection in construction (in Polish). PN-80/B-01800 Anticorrosive protection in construction (in Polish) Search in Google Scholar

[21] Tayfun Uygunoğlu, Ibrahim Gunes. (2015). Biogenic corrosion on ribbed reinforcing steel bars with different bending angles in sewage systems. Construction and Building Materials, 96(15), 530–540. Uygunoğlu Tayfun Gunes Ibrahim 2015 Biogenic corrosion on ribbed reinforcing steel bars with different bending angles in sewage systems Construction and Building Materials 96 15 530 540 10.1016/j.conbuildmat.2015.08.082 Search in Google Scholar

[22] Basiński, A., Bielański, A., Gumiński K. (1966). Physical chemistry. (in pol.) Warszawa: Państwowe Wydawnictwo Naukowe PWN. Basiński A. Bielański A. Gumiński K. 1966 Physical chemistry. (in pol.) Warszawa Państwowe Wydawnictwo Naukowe PWN Search in Google Scholar

[23] Kurdowski, W. (2010). The chemistry of cement and concrete. Warszawa: PWN. Kraków: Polski Cement. Kurdowski W. 2010 The chemistry of cement and concrete Warszawa PWN Kraków: Polski Cement Search in Google Scholar

[24] Słomka-Słupik, B., Zybura, A. (2017). Thaumasite non-sulphate attack at ambient temperature and pressure. Architecture Civil Engineering Environment, 10(3), 73–80. Słomka-Słupik B. Zybura A. 2017 Thaumasite non-sulphate attack at ambient temperature and pressure Architecture Civil Engineering Environment 10 3 73 80 10.21307/acee-2017-036 Search in Google Scholar

[25] Słomka-Słupik, B. (2009). The changes of phases composition of the paste from cement CEM III/A under the influence of NH4CI water solution. Cement Wapno Beton, 2, 61–66. Słomka-Słupik B. 2009 The changes of phases composition of the paste from cement CEM III/A under the influence of NH₄CI water solution Cement Wapno Beton 2 61 66 Search in Google Scholar

[26] Słomka-Słupik, B., Zybura, A. (2009). Mechanism of concrete damage in industrial wastewater treatment plant facilities. Materiały Budowlane, 448(12), 14–15. Słomka-Słupik B. Zybura A. 2009 Mechanism of concrete damage in industrial wastewater treatment plant facilities Materiały Budowlane 448 12 14 15 Search in Google Scholar

[27] Słomka-Słupik, B., Zybura, A. (2010). The changes in the microstructure of the hydrated cement paste subjected to decalcification. Cement Wapno Beton 6, 333–339. Słomka-Słupik B. Zybura A. 2010 The changes in the microstructure of the hydrated cement paste subjected to decalcification Cement Wapno Beton 6 333 339 Search in Google Scholar

[28] Piasta, W. G. (2000). Sulphate corrosion of concrete under long-term load. (in Polish) Kielce: Kielce University of Technology. Piasta W. G. 2000 Sulphate corrosion of concrete under long-term load. (in Polish) Kielce Kielce University of Technology Search in Google Scholar

[29] Kołwzan, B. (2011). The analysis of the phenomenon of biofilm – the conditions of its formation and functioning. (in pol.) Ochrona Środowiska, 4, 3–14. Kołwzan B. 2011 The analysis of the phenomenon of biofilm – the conditions of its formation and functioning. (in pol.) Ochrona Środowiska 4 3 14 Search in Google Scholar

[30] Cwalina, B., Dzierżewicz, Z. (2007). Factors favoring the biological corrosion of reinforced concrete structures. (in Polish) Przegląd budowlany, 7–8, 52–59. Cwalina B. Dzierżewicz Z. 2007 Factors favoring the biological corrosion of reinforced concrete structures. (in Polish) Przegląd budowlany 7–8 52 59 Search in Google Scholar

[31] Cwalina, B. (2003). The role of microorganisms in the deterioration of natural building stones. Journal of Polish Mineral Engineering Society, 1, 39–48. Cwalina B. 2003 The role of microorganisms in the deterioration of natural building stones Journal of Polish Mineral Engineering Society 1 39 48 Search in Google Scholar

[32] Melchers, R. E., Wells, P.A. (2007). Modelling the long term corrosion of reinforced concrete sewers. ResearchGate.net. Melchers R. E. Wells P.A. 2007 Modelling the long term corrosion of reinforced concrete sewers ResearchGate.net Search in Google Scholar

[33] EN196-2:2005 – Cement testing methods. Part 2: Chemical analysis of cement. EN196-2 2005 Cement testing methods. Part 2: Chemical analysis of cement Search in Google Scholar

[34] Jin, X., Cheng, S. & Maocheng, Y., Fuhui, W. (2012). Effects of sulfate reducing bacteria on corrosion of carbon steel Q235 in soil-extract solution. International Journal of Electrochemical Science, 7, 11281–11296. Jin X. Cheng S. Maocheng Y. Fuhui W. 2012 Effects of sulfate reducing bacteria on corrosion of carbon steel Q235 in soil-extract solution International Journal of Electrochemical Science 7 11281 11296 Search in Google Scholar

[35] Davis, J.L., Nica, D., Shields, K., Roberts, D.J. (1998). Analysis of concrete from corroded sewer pipe. International Biodeterioration & Biodegradation, 42, 75–84. Davis J.L. Nica D. Shields K. Roberts D.J. 1998 Analysis of concrete from corroded sewer pipe International Biodeterioration & Biodegradation 42 75 84 10.1016/S0964-8305(98)00049-3 Search in Google Scholar

[36] Węglowski, W. (2008). Modeling of concrete damage caused by sulphate corrosion (dissertation (in pol.), Instytut Podstawowych Problemów Techniki Polskiej Akademii Nauk). Poland, Warszawa. Węglowski W. 2008 Modeling of concrete damage caused by sulphate corrosion (dissertation (in pol.) Instytut Podstawowych Problemów Techniki Polskiej Akademii Nauk). Poland, Warszawa Search in Google Scholar

[37] Rawat, A., Sharma, N., Khandelwal, A. (2014). Microbiological causes of corrosion, Digital Refining, 1–7. Rawat A. Sharma N. Khandelwal A. 2014 Microbiological causes of corrosion Digital Refining 1 7 Search in Google Scholar

[38] Zapała, J. (2010). Negative aspects of the impact of bacteria on concrete. Structure, 2, 14–17. Zapała J. 2010 Negative aspects of the impact of bacteria on concrete Structure 2 14 17 Search in Google Scholar

[39] Wołejko, E., Matejczyk, M. (2011). The problem of biological corrosion in construction. Civil and Environmental Engineering, 2, 2081–3279. Wołejko E. Matejczyk M. 2011 The problem of biological corrosion in construction Civil and Environmental Engineering 2 2081 3279 Search in Google Scholar

[40] Kielemoes, J., Boever, P., Verstraete, W. (2000). Influence of denitrification on the corrosion of iron and stainless steel powder. Environmental Science & Technology, 34, 663–671, Kielemoes J. Boever P. Verstraete W. 2000 Influence of denitrification on the corrosion of iron and stainless steel powder Environmental Science & Technology 34 663 671 10.1021/es9902930 Search in Google Scholar

[41] White, C., Tancos, M., Lytle, D. A. (2011). Microbial Community Profile of a Lead Service Line Removed from a Drinking Water Distribution System. Applied and Environmental Microbiology, 77, 5557–5561. White C. Tancos M. Lytle D. A. 2011 Microbial Community Profile of a Lead Service Line Removed from a Drinking Water Distribution System Applied and Environmental Microbiology 77 5557 5561 10.1128/AEM.02446-10 Search in Google Scholar

[42] Baszkiewicz, J., Kamiński M. (2006). Corrosion of materials. (in Polish) Warszawa: OWPN. Baszkiewicz J. Kamiński M. 2006 Corrosion of materials. (in Polish) Warszawa OWPN Search in Google Scholar

[43] Pak, K.-R., Lee, H.-J., Lee, H.-K., Kim, Y.-K., Oh, Y.-S., Choi, S.-C. (2003). Involvement of Organic Acid During Corrosion of Iron Coupon by Desulfovibrio desulfuricans. Journal of Microbiology and Biotechnology, 13(6), 937–941. Pak K.-R. Lee H.-J. Lee H.-K. Kim Y.-K. Oh Y.-S. Choi S.-C. 2003 Involvement of Organic Acid During Corrosion of Iron Coupon by Desulfovibrio desulfuricans Journal of Microbiology and Biotechnology 13 6 937 941 Search in Google Scholar

[44] Valix M., Zamri D. Mineyama H., Cheung W.H., Shi J., Bustamante H. (2012). Microbiologically Induced Corrosion of Concrete and Protective Coatings in Gravity Sewers. Chinese Journal of Chemical Engineering, 20(3), 433–438. Valix M. Zamri D. Mineyama H. Cheung W.H. Shi J. Bustamante H. 2012 Microbiologically Induced Corrosion of Concrete and Protective Coatings in Gravity Sewers Chinese Journal of Chemical Engineering 20 3 433 438 10.1016/S1004-9541(11)60150-X Search in Google Scholar