The article presents a theoretical analysis of existing concepts to evaluate the non-failure of RC structures in operation. To perform the analysis, the authors considered a number of scientific works of both Ukrainian and foreign researchers. The main focus was on works in which the model of the stochastic nature of the RC structure operation included random parameters of acting loads, as well as the reserve of its bearing capacity and serviceability (geometric dimensions of cross sections of constructive members, strength and deformation characteristics of materials, etc.). Among others, according to the authors, important problems in terms of analysis of a single work were the volume of statistical selection of random parameters, their number and impact on the study result, as well as rationality of the adopted method of calculating the probability of failure (or non-failure work) of RC structure in operation. Based on the processing of a number of scientific works, the authors highlight the relevance, advantages and disadvantages of the concepts of non-failure assessment proposed there, as well as the formulate the conclusions and recommendations for further experimental and theoretical research in this area.
System for ensuring the reliability and safety of building objects. General principles of reliability assurance and constructive safety of buildings and structures. DBN V.1.2-14:2018. State Building Codes of Ukraine. (2018). Kyiv: Ministry of Regional Development, Construction and Housing and Communal Service of Ukraine (in Ukrainian). URL:https://uscc.ua/uploads/page/images/normativnye%20dokumenty/dbn/DBN-V121...
Eurocode 0. Basis of structural design. EN 1990:2002. European Standart. (2002). Brussels: European Committee for Standardization. URL:https://www.phd.eng.br/wp-content/uploads/2015/12/en.1990.2002.pdf
ISO 2394:2015. General principles on reliability for structures (4th ed.). (2015). ISO. URL:https://www.sis.se/api/document/preview/918604/
Constructions of buildings and structures. Concrete and reinforced concrete structures. Basic principles. DBN V.2.6-98:2009. State Building Codes of Ukraine. (2011). Kyiv: Ministry of Regional Development and Construction of Ukraine (in Ukrainian). URL:http://interiorfor.com/wp-content/uploads/2017/01/26_98_2009.pdf
Constructions of buildings and structures. Concrete and reinforced concrete structures made of heavy concrete. Design rules. DSTU B V.2.6-156:2010. National Standard of Ukraine. (2011). Kyiv: Ministry of Regional Development and Construction of Ukraine (in Ukrainian). URL: https://dwg.ru/dnl/9603
Voskobiinyk, O. P. (2010). Typological comparison of defects and damages of reinforced concrete, metallic and steel-reinforced concrete beam structures. Bulletin of the Lviv Polytechnic National University. Theory and Building Practice, 662, 97-103 (in Ukrainian). URL:http://ena.lp.edu.ua/bitstream/ntb/6747/1/20.pdf
Klymenko, Ye. V., Antoniuk, N. R., & Polianskyi, K. V. (2019). Modeling the work of damaged reinforced concrete beams in the SC LIRA-SAPR. Bulletin of the Odessa State Academy of Civil Engineering and Architecture, 77, 58-65 (in Ukrainian). doi:10.31650/2415-377X-2019-77-58-65
https://doi.org/10.31650/2415-377X-2019-77-58-65
Faye, P. N. (2017). Experimental Study on the Degradation Mechanism of RC Structures under Chloride Environment (PhD thesis). URL:https://www.researchgate.net/publication/335433554_Experimental_Study_on...
Khaghanpour, R., Dousti, A., & Shekarchi, M. (2017). Prediction of Cover Thickness Based on Long-Term Chloride Penetration in a Marine Environment. Journal of Performance of Constructed Facilities, 31(1). doi:10.1061/(ASCE)CF.1943-5509.0000931
https://doi.org/10.1061/(ASCE)CF.1943-5509.0000931
Chen, D., Sun, G., Hu, D., & Shi, J. (2021). Study on the bearing capacity and chloride ion resistance of RC structures under multi-factor corrosive environment and continuous load. Journal of Building Engineering, 44(6), 102990. doi:10.1016/j.jobe.2021.102990
https://doi.org/10.1016/j.jobe.2021.102990
Sakhno, S. I., Lyulchenko, E. V., Yanova, L. A., & Pyshchykova, O. V. (2020). Analysis of nonlinear deformations of reinforced concrete beams by the finite element method. Mining Bulletin, 108, 27-34 (in Ukrainian). doi:10.31721/2306-5435-2020-1-108-27-34
https://doi.org/10.31721/2306-5435-2020-1-108-27-34
Bashynska, O. Yu. (2019). Creation of calculation models of building structures taking into account the rheological properties of reinforced concrete (PhD thesis) (in Ukrainian). URL:https://dspace.nau.edu.ua/handle/NAU/40283
Heraskin, O. O., Rotko, S. V., & Uzhehova, O. A. (2020). Calculation of a monolithic plate taking into account the rheological properties of reinforced concrete. Modern technologies and methods of calculations in construction, 14, 63-72 (in Ukrainian). doi:10.36910/6775-2410-6208-2020-4(14)-07
https://doi.org/10.36910/6775-2410-6208-2020-4(14)-07
Pashinsky, V. V. (2015). Regulation and zoning of the design parameters of air temperature on the territory of Ukraine. Municipal services of cities, 120, 49-53 (in Ukrainian). URL:http://www.irbis-nbuv.gov.ua/cgi-bin/irbis_nbuv/cgiirbis_64.exe?I21DBN=L...
Kiesse, T. S., Bonnet, S., Amiri, O., & Ventura, A. (2020). Analysis of corrosion risk due to chloride diffusion for concrete structures in marine environment. Marine Structures, 73, 102804.doi:10.1016/j.marstruc.2020.102804
https://doi.org/10.1016/j.marstruc.2020.102804
Pellizzer, G. P., Leonel, E. D., & Nogueira, C. G. (2015). Influence of reinforcement's corrosion into hyperstatic reinforced concrete beams: a probabilistic failure scenarios analysis. IBRACON Structures and Materials Journal, 8(4), 479-490. doi:10.1590/S1983-41952015000400004
https://doi.org/10.1590/S1983-41952015000400004
Bastidas-Arteaga, E., Bressolette, P., Chateauneuf, A., & Sanchez-Silva, M. (2009). Probabilistic lifetime assessment of RC structures under coupled corrosion-fatigue deterioration processes. Structural Safety, 31(1), 84-96. doi:10.1016/j.strusafe.2008.04.001
https://doi.org/10.1016/j.strusafe.2008.04.001
Conciatori, D., Bruhwiler, E., & Morgenthaler, S. (2009). Calculation of reinforced concrete corrosion initiation probabilities using the Rosenblueth method. International Journal of Reliability and Safety, 3(4). doi:10.1504/IJRS.2009.028581
https://doi.org/10.1504/IJRS.2009.028581
Krasnoshchekov, Y. V., & Zapoleva, M. Yu. (2015). Probabilistic design of structures by the given level of reliability. Bulletin of the Siberian State Automobile and Highway Academy, 1(41), 68-73 (in Russian). URL:https://cyberleninka.ru/article/n/veroyatnostnoe-proektirovanie-konstruk...
Khmil, R. Ye., Tytarenko, R. Yu., Blikharskyy, Ya. Z., & Vegera, P. I. (2021). Improvement of the method of probability evaluation of the failure-free operation of reinforced concrete beams strengthened under load. IOP Conference Series: Materials Science and Engineering, 1021, 012014. doi:10.1088/1757-899X/1021/1/012014
https://doi.org/10.1088/1757-899X/1021/1/012014
Khmil, R., Tytarenko, R., Blikharskyy, Y., & Vegera, P. (2021). The Probabilistic Calculation Model of RC Beams, Strengthened by RC Jacket. Lecture Notes in Civil Engineering, 100, 182-191. doi:10.1007/978-3-030-57340-9_23
https://doi.org/10.1007/978-3-030-57340-9_23
Ventsel, O. S. (2018). Probability theory (12th ed.). Moscow: Justitia (in Russian). URL:https://cdn1.ozone.ru/multimedia/1020633476.pdf