Experimental studies of the quantitative composition of corrosion products on the surface of reinforced concrete structures

Reinforced concrete structures play a key role in modern infrastructure, however, corrosion of reinforcement poses a serious threat to their durability and safety. In this study, the sensitivity of a portable X-ray fluorescence analyzer (XRF) to corrosion products on the concrete surface is considered. The experiment was conducted using concrete samples containing varying amounts of iron hydroxide. The results showed that the FRA demonstrates high accuracy and reliability in detecting corrosion, which contributes to the improvement of diagnostic methods and maintenance of reinforced concrete structures.

1. Kondrashov G. M. Sovremennyye metody zashchity zhelezobetonnykh konstruktsiy ot korrozii s ispol’zovaniyem elektrofizicheskogo effekta [Modern Methods of Protecting Reinforced Concrete Structures from Corrosion Using ElectroPhysical Effects] // Fundamental'nye Issledovaniya. Fundamental Research. 2008. No. 9. P. 65–66. EDN: JUCNBJ. (In Russ.).

2. Ovchinnikova T. S., Marinin A. N., Ovchinnikov I. G. Korroziya i antikorrozionnaya zashchita zhelezobetonnykh mostovykh konstruktsiy [Corrosion and corrosion protection of reinforced concrete bridge structures] // Vestnik Evraziyskoy Nauki. Bulletin of Eurasian Science. 2014. No. 5 (24). P. 11–36. EDN: TKELFZ. (In Russ.).

3. Pshenichkina V. A., Gritsenko B. S., Glukhov A. V. [et al.]. Otsenka ostatochnogo resursa zhelezobetonnykh balok ob”yekta promyshlennogo naznacheniya s uchetom korrozionnogo iznosa [Estimation of the residual service life of reinforced concrete beams of an industrial facility taking into account corrosion wear] // Vestnik MGSU. Vestnik MGSU. 2023. No. 4. P. 533–544. EDN: RTSDVV. (In Russ.).

4. Zhokhov E. I., Fursov L. F. Otsenka ostatochnogo resursa v zone korrozii betona [Residual resource of concrete inside the limit of corrosion zone] // Vestnik MGSU. Vestnik MGSU. 2010. No. 4-4. P. 118–123. EDN: RTSDVV. (In Russ.).

5. Podzharova K. D., Bykova A. S., Ryba N. S. [et al.]. Otsenka nadezhnosti zhelezobetonnykh konstruktsiy [Assessment of the reliability of reinforced concrete structures] // Moskovskiy Ekonomicheskiy Zhurnal. Moscow Economic Journal. 2019. No. 5. P. 337–344. EDN: PZABXK. (In Russ.).

6. Zaki A., Chai H. K., Aggelis D. G. [et al.]. Non-Destructive Evaluation for Corrosion Monitoring in Concrete: A Review and Capability of Acoustic Emission Technique // Sensors. 2015. Vol. 15 (8). P. 19069–19101. DOI: 10.3390/s150819069. (In Engl.).

7. Altoubat S., Maalej M., Shaikh F. U. A. Laboratory Simulation of Corrosion Damage in Reinforced Concrete // International Journal of Concrete Structures and Materials. 2016. Vol. 10 (3). P. 383–391. DOI: 10.1007/s40069-016-0138-7. (In Engl.).

8. Ožbolt J., Balabanić G., Oršanić F. Modelling corrosion of steel reinforcement in concrete // IOP Conference Series: Materials Science and Engineering. IOP Publishing. 2019. Vol. 615 (1). DOI: 10.1088/1757-899X/615/1/012011. (In Engl.).

9. Andrade C. Propagation of reinforcement corrosion: principles, testing and modeling // Materials and Structures. 2018. Vol. 52 (2). P. 1–26. DOI: 10.1617/s11527-018-1301-1. (In Engl.).

10. Leonovich S. N., Stepanova A. V. Deformirovaniye i razrusheniye zhelezobetonnykh konstruktsiy: modelirovaniye v usloviyakh khloridnoy korrozii [Deformation and destruction of reinforcement structures: modeling in condition of chlorine corrosion] // Vestnik Belorusskogo Gosudarstvennogo Universiteta Transporta: Nauka i Transport. Bulletin of Belarusian State University of Transport: Science and Transport. 2012. No. 1 (24). P. 81–83. EDN: UWTPCX. (In Russ.).

11. Benin A. V., Semenov A. S., Semenov S. G. [et al.]. Konechno-elementnoye modelirovaniye protsessov razrusheniya i otsenka resursa elementov avtodorozhnogo mosta s uchetom korrozionnykh povrezhdeniy [Finite element modeling of fracture processes and estimation of the road with account of corrosion damage] // Inzhenerno-stroitelnyy zhurnal. Magazine of Civil Engineering. 2012. No. 7. P. 32–42. (In Russ.).

12. Volchanin G. V., Kuznetsov A. A., Ponomarev A. V. Obnaruzheniye i kolichestvennaya otsenka korrozii na poverkhnosti zhelezobetona s pomoshch’yu analiza izobrazheniy [Detection and quantification of corrosion on reinforced concrete surfaces using image analysis] // Pribory. Instruments. 2023. No. 6 (276). P. 35–42. EDN: JFZKIT. (In Russ.).

13. Kuznetsov A. A., Ponomarev A. V., Fomichenko K. I., Zaprudskiy A. A. Issledovaniye protsessa korrozii zhelezobetonnykh opor kontaktnoy seti s otsenkoy parametrov prochnosti [Analysis of corrosion process in reinforced concrete structures with strength parameters estimation] // Izvestiya Transsiba. The Journal of Transsib Railway Studies. 2020. No. 2 (42). P. 26–34. EDN: CDUVOI. (In Russ.).

14. Ukazaniya po tekhnicheskomu obsluzhivaniyu i remontu opornykh konstruktsiy kontaktnoy seti. Utv. Rasporyazheniyem OAO «RZhD» ot 18.04.2022 № 1047/r (red. ot 19.01.2023 № 91/r) [Guidelines for Maintenance and Repair of Support Structures of the Contact Network. Approved by the Order of OJSC «RZD» dated 18.04.2022 No. 1047/r (ed. dated 19.01.2023 No. 91/r). Moscow, 2023. 80 p. (In Russ.).