Influence of the Type of Filler from Production Waste on the Corrosion Resistance of Concrete

Sustainable modern construction implies maintaining a healthy economy and rational use of resources. In the work presented, studies have been carried out to obtain concretes of increased corrosion resistance. For this purpose, waste products of the non-metallic industry were used in the extraction of crushed stone - crushing screenings, construction waste - concrete scrap, as well as waste of mineral wool production – “beads”. The conducted experimental studies of concrete compositions indicate that: with the planned impact of sulfate media on the structures, the use of mineral wool production waste as a filler is effective; with the planned impact of sulfate-magnesia media on the structure, the use of the filler based on concrete scrap is effective. The concrete compositions developed with the use of crushing screenings of a fraction of 0–5 mm can be recommended for the widespread use of non-metallic raw material extraction waste, rational use of resources and the production of high-quality concrete. The use of additives based on polycarboxylates makes it possible to obtain concretes with a reduction in cement consumption in the mixture by 10–20% and a reduction in the heat-humidity treatment regime by 2 times. At the same time, to obtain concretes with high durability, it is important to use clean washed sands with a content of pulverized and clay particles of no more than 1%.

L.R. ZAITSEVA¹, Engineer (graduate student) (This email address is being protected from spambots. You need JavaScript enabled to view it.),
E.V. LUTSYK¹, Candidate of Sciences (Engineering) (This email address is being protected from spambots. You need JavaScript enabled to view it.),
T.V. LATYPOVA¹, Candidate of Sciences (Engineering) (This email address is being protected from spambots. You need JavaScript enabled to view it.),
V.M. LATYPOV¹, Doctor of Sciences (Engineering) (This email address is being protected from spambots. You need JavaScript enabled to view it.),
P.A. FEDOROV¹, Candidate of Sciences (Engineering) (This email address is being protected from spambots. You need JavaScript enabled to view it.);
V.P. POPOV², Doctor of Sciences (Engineering) (This email address is being protected from spambots. You need JavaScript enabled to view it.)

¹ Ufa State Petroleum Technological University (1, Kosmonavtov Street, Ufa, 450062, Russian Federation)
² Samara State Technical University (244, Molodogvardeyskaya Street, Samara, 443100, Russian Federation)

1. Kemenov D. Definitions and concepts of sustainable development in the field of low-rise construction. Arhitektura i dizayn. 2018. No. 4, pp. 1–7. (In Russian). DOI: 10.7256/2585-7789.2018.4.30093
2. Development of resource-saving technologies and complex technological lines for multi-tonnage waste of inert non-metallic raw materials with the production of economical construction products for mass use. State contract dated June 26, 2008 № 02.525.11.5007 (In Russian).
3. Falikman V., Rozental N., Rozental A. AAR in concrete: Russian experience. In RILEM, Proceedings of the Pro128-3 Durability, Monitoring and Repair of Structure, Proceedings of the International Conference on Sustainable Materials Systems and Structures (SMSS2019). Rovinj, Croatia. 20–22 March 2019. Vol. 3, pp. 192–199.
4. Butkevich G.R. Stages of development of non-metallic construction materials industry in Russia. Stroitel’nye Materialy [Construction Materials]. 2011. No. 1, pp. 3–5. (In Russian).
5. Bedov A.I., Tkach E.V., Pakhratdinov A.A. Issues of utilization of concrete scrap waste for the production of large aggregate in the production of reinforced concrete bending elements. Vestnik MGSU. 2016. No. 7, pp. 91–100. (In Russian).
6. Murtazaev S-A.Yu, Murtazaev A.T., Salamova M.Sh. Influence of recycled concrete aggregate on formation of concrete structure and properties. Science, education and production: materials of the All-Russian scientific and technical conference. Grozny. 2008. pp. 57–61. (In Russian).
7. Golovin M.V., Kutov D.V., Shchigoreva E.M., Shchigorev D.S. Influence of recycled concrete aggregate on corrosion resistance of concrete. International Scientific and Technical Conference of Young Scientists BSTU named after V.G. Shukhov. 2017. pp. 1489–1493. (In Russian).
8. Thomas M., Monkman S., Djerbi A. The carbonation of recycled concrete aggregate affected by alkali-silica reaction. In RILEM Proceedings of the PRO 133 International Workshop CO₂ Storage in Concrete (CO2STO2019). Marne-la-Vallee, France. 24–25 June 2019, pp. 138–145.
9. Ekolu S.O., Makama L.N., Shuluuka W.P. Influence of different recycled aggregate types on strength and abrasion resistance properties of concrete. In Concrete Repair, Rehabilitation and Retrofitting III, Proceedings of the 3rd International Conference on Concrete Repair Rehabilitation and Retrofitting (ICCRRR). Cape Town, South Africa. 3–5 September 2012, pp. 72–73.
10. Serna P., Ulloa V.A., Pelufo M.J., Jacquin C. Analysis of zero-slump concrete made recycled aggregate from concrete demolition waste. In RILEM Proceedings of the PRO 82 2-nd International RILEM Conference on Progress of Recycling in the Built Environment. Sao Paulo, Brazil. 2–4 December 2009, pp. 243–252.
11. Gutiérrez P.A., Sanchez de Juan M. Utilization of recycled concrete aggregate for structural concrete. In RILEM Proceedings of the PRO 40 International RILEM Conference on the Use of Recycled Materials in Building and Structures. Barcelona, Spain. 8–11 November 2004. Vol. 2, pp. 693–702.
12. Tanaka K., Yada K., Maruyama I., Sato R., Kawai K. Study on corrosion of reinforcing bar in recycled concrete. In RILEM Proceedings of the PRO 40 International RILEM Conference on the Use of Recycled Materials in Building and Structures. Barcelona, Spain. 8–11 November 2004. Vol. 2, pp. 643–650.
13. Sun J., Huaqin J. Study on properties of recycled concrete aggregate and influence of it on properties of concrete. In RILEM Proceedings of the PRO 73 2-nd International Conference on Waste Engineering and Management (ICWEM 2010). Shanghai, China. 13–15 October 2010, pp. 261–268.
14. Khitskov A.A. Influence of different clay particles on efficiency of polycarboxylate superplasticizer, properties of cement stone. Vestnik YuUrGU. Seriya «Stroitel’stvo i arkhitektura». 2019. Vol. 19. No. 1, pp. 40–51. (In Russian).
15. Tolypina N.M., Shchigoreva E.M., Golovin M.V., Shchigorev D.S. Increase of corrosion resistance of concrete by application of active aggregates of the second type. Vestnik Belgorodskogo Gosudarstvennogo Tekhnologicheskogo Universiteta Im. V.G. Shukhova. 2019. No. 2, pp. 27–32. (In Russian).
16. Khokhrin N.I. Stoykost’ legkobetonnykh stroitel’nykh konstruktsiy [Resistance of lightweight building structures]. Kuibyshev: KuISI. 1973. 206 p.
17. Rakhimbaev Sh.M., Tolypina N.M., Khakhaleva E.N. Substantiation of methods for testing corrosion resistance of hydration hardening materials. II International Online Congress Nature-Like Technologies of Building Composites for the Protection of the Human Environment. Belgorod. 2019, pp. 735–739. (In Russian)