Istrazivanja i projektovanja za privreduJournal of Applied Engineering Science

MODELing OF INFLUENCE OF MICROBIOLOGICAL AGGRESSIVE MEDIA ON CORROSION OF CEMENT STONE


DOI: 10.5937/jaes18-27802 
This is an open access article distributed under the CC BY 4.0
Creative Commons License

Volume 18 article 713 pages: 458 - 462

Alexey Bulgakov*
Southwest State University, Faculty of construction and architecture, Department of industrial and civil
engineering, Kursk, Russian Federation

Dmitry Gubanov
Mordovia State University, Faculty of Construction, Department of Construction Materials and
Technologies, Saransk , Russian Federation

Evgenii Morozov
Mordovia State University, Faculty of Construction, Department of Construction Materials and
Technologies, Saransk , Russian Federation

Anna Piksaykina
Mordovia State University, Faculty of Construction, Department of Construction Materials and
Technologies, Saransk , Russian Federation

Due to the complex and constantly changing global environmental situation, the study of the resistance of mineral binder-based building composites to the effect of the metabolism products of microscopic organisms seems particularly relevant. Taking into account the nature of the effect of bacteria and mycelial fungi on cement stone, a method of evaluating the resistance on the basis of modeling by replacing the real development of colonies of microorganisms with chemically aggressive aqueous solutions of their life products is proposed. It is allowed to study the current processes of phase transformations, as well as changes of operational parameters in the form of regression dependencies.

View article

1. Sand, W. (2001). Microbial corrosion and its inhibition. Biotechnology, vol. 10, 2nd ed., Wiley-VCH Verlag, Weinheim, p. 267-316.

2.Cwalina, B., Dzierzewicz, Z. (2006). Korozja biologiczna konstrukcji zelbetowych (Biological corrosion of reinforced concrete constructions). XXI Polish Conference „Warsztat Pracy Projektanta Konstrukcji”, Szczyrk, T.1, Wyd. PZITB, O/Gliwice, p. 79-108 (in Polish)

3. Mori, T., Koga, M., Hikosaka, Y., Nonaka, T., Mishina, F., Sakai, Y., Koizumi J. (1991). Microbial corrosion of concrete sewer pipes, H2S production from sediments and determination of corrosion rate. Water Science and Technology, 23, p. 1275-1282.

4. Perego, P., Fabiano, B. (1999). Corrosion, microbial. In: Flickinger M.C., Drew S.W. (Eds) Encyclopedia of Bioprocess Technology: Fermentation, Biocatalysis and Bio-separation. John Wiley & Sons, Inc., New York, p. 717-729.

5. Cwalina,B., Zyska,B. (2005). Mineralnemateriałybudowlane – kamien, beton, cegla, zaprawybudowlane, szklo. W: Mikrobiologia Materialw. (Mineral building materials – stone, concrete, mortars, glass. In: Microbiology of Materials.) Zyska B., Zakowska Z. (Red.), Wyd. Politechniki Ldzkiej, Ldz, p. 377-412. (in Polish).

6. Vincke, E., Boon, N., Verstraete, W. (2001). Analysis of the microbial communities on corroded concrete sewer pipes – a case study. Applied Microbiology and Biotechnology, 57, p. 776-785.

7. Cwalina, B. (2004). Korozja kamienia i betonu wzbudzona przez drobnoustroje (The stone and concrete corrosion infl uenced by microorganisms). Ochrona przed Korozja, 1, p. 17-23 (in Polish).

8. Roberts, D.J., Nica, D., Zuo, G., Davis,J.L. (2002). Quantifying microbially induced deterioration of concrete: Initial studies. International Biodeterioration and Biodegradation, 49, p. 227-234.

9. Eriksen, K. (2003). Thaumasite attack on concrete at Marbjerg Waterworks. Cement and Concrete Composites, 25,p. 1147-1150.

10. Jana, D., Lewis, R.A. (2005). Acid attack in a concrete sewer pipe – a petrographic and chemical investigation. Proc. 27th Int. Conf. Cement Microscopy, ICMA, Victoria, Canada.

11. Wazny, J. (1980). The influence of wood-destroying fungi on concrete. In: Oxley T.A., Becker G., Allsopp D. (Eds) Biodeterioration. Pitman Publ. Ltd., London, p. 59-62.

12. Erofeev, V. (2016). Frame Construction Composites for Buildings and Structures in Aggressive Environments. Procedia Engineering, 165. p. 1444-1447. DOI: 10.1016/j.proeng.2016.11.877.

13. Erofeev, V., Rodin, A., Rodina, N., Kalashnikov, V., Irina, E. (2016). Biocidal Binders for the Concretes of Unerground Constructions. Procedia Engineering, 165. p. 1448-1454. DOI:10.1016/j.proeng. 2016.11.878.

14. Erofeev, V., Dergunova, A., Piksaikina, A., Bogatov, A., Kablov, E., Startsev, O., Matvievskiy, A. (2016). The Effectiveness of Materials Different with Regard to Increasing the Durability. MATEC Webof- Conferences, DOI: 73,04021.10.1051/matecconf/ 20167304021.

15. Stanaszek-Tomal, E., Fiertak, M. (2016). Biological Corrosion in the Sewage System and the Sewage Treatment Plant, Procedia Engineering, Vol. 161.

16. Maraveas, C. (2020). Durability Issues and Corrosion of Structural Materials and Systems in Farm Environment. Appl. Sci., 10, p. 990.