High-Mobility Concrete Mixes for Concrete-Filled Steel Tube Structures of Complex Cross-Section

  • Authors

    • Viktor Sopov
    • Viktor Dolgiy
    • Kateryna Latorets
    • Yurii Zhuravlov
    https://doi.org/10.14419/ijet.v7i4.8.27259

    Received date: February 11, 2019

    Accepted date: February 11, 2019

    Published date: October 13, 2018

  • concrete-filled steel tubes, concrete mixes, mobility, viscosity, chemical additives, mineral additives, injection.

  • Abstract

    Currently, in the technology of concrete and reinforced concrete, a period of revolutionary leap is observed, caused mainly by the use of high-strength and composite materials, complex high-performance chemical and mineral admixtures, disperse reinforcement, etc. In conditions of increased requirements for economy, lower consumption of metal, cement and forest materials, Interest in the builders causes concrete-filled steel tubes.

    The main requirements for concrete-filled steel tubes and concrete mixtures for its manufacture are considered. The specific features of the selection of the composition of concrete-filled steel tubes are shown. The technique of selection of compositions and results of researches of properties of concrete mixes and concrete-filled steel tubes is presented.

  • References

    1. Shams M., Saadeghvaziri M.A., "State of the art of concrete-filled steel tubular columns", ACI Structural Journal 94 (5), (1997), рр. 558-571.
    2. Storozhenko L.I. Trubobeton, Poltava: TOB ASMG, (2010), 306 s.
    3. Baron J. “Essai sur une vue d'ensemble de la fissuration spontanee accidentelle du beton hydraulique non arme et arme”, Bull. Liais. Lab. Ponts et chausses, №87, (1977), pp. 69-78.
    4. Yuhnevskiy, P.I. Vliyanie himicheskoy prirodyi dobavok na svoystva betonov, Minsk: BNTU, (2013), 310 s.
    5. Volkov, V.A. Kolloidnaya himiya (poverhnostnyie yavleniya i dis-persnyie sistemyi), M.: MGTU im. A.N. Kosyigina, (2001), 640 s.
    6. Bazhenov, Yu. M., Demyanova B. C., Kalashnikov V. I. “Modi-fitsirovannyie vyisokokachestvennyie betonyi”, Nauchnoe izdanie, M.: Izdatelstvo Assotsiatsii stroitelnyih vuzov, (2006), pp. 328-337.
    7. Tattrsall, G. Banfill, P. The Rheology of Fresh Concrete, London, Pitman, (1983), 356 p.
    8. Banfill, P. “Rheology of fresh cement and concrete”, Rheology Re-views, (2006), pp. 61 - 130.
    9. Jodeh, S.A., Nassar, G.E. “Pumpability assessment of C90 SCC”, Proc 2nd Int Conf Adv Concr Technol Middle East: Self-Consolid Concr, Abu Dhabi, (2009), pp 155–176.
    10. Feys, D., Verhoeven, R., De Schutter, G., “Parameters influencing pressure during pumping of self-compacting concrete”, Materials and Structures, January, (2013), p.p. 533-555.
    11. Benaicha, M., Jalbaud, O., Hafidi Alaoui, A., Burtschell, Y., “Cor-relation between the pumping and the rheological properties of self-compacting concrete: a practical study” International Journal of En-gineering and Technical Research (IJETR), Volume-1, Issue-8, (2013), p.p. 62-67.
    12. Sopov V., Dolgiy V. “The properties of concrete mixes, pumped over long distances”. Matec WEB of Conferences, 6th International Scientific Conference “Reliability and Durability of Railway Transport Engineering Structures and Buildings” (Transbud-2017), Volume 116, (2017). – 01017. – pp. 1-7. DOI: 10.1051/matecconf/201711601017.
    13. Batrakov, V.G. Modifitsirovannyie betonyi. Teoriya i praktika, M.: Tehnoproekt, (1998), 768 s.
    14. Izotov, V.S., Sokolova Yu.A., Himicheskie dobavki dlya modifikatsii betona, Kazanskiy Gosudarstvennyiy arhitekturno-stroitelnyiy universitet: Izdatelstvo «Paleotip», (2006), 130 s.
    15. Vovk, A.I. „Adsorbtsiya-superplastifikatorov na produktah gidratatsii mineralov portlandtsementnogo klinkera. Zakonomernosti protsessa i stroenie adsorbtsionnyih sloev”, Kolloidnyiy zhurnal. T.62, No2, (2000), pp. 11-16.
    16. Sugiyama, T., Ohta, A., Uomoto, T., “The dispersing mechanism and applications of polycarboxylate-based superplasticisers”, Proc. 11th Int. Congr. on the Chemistry of Cement, Durban, South Africa, (2003), pp. 560-568.
    17. Allan, M.L. Latex-modified groutes for in-situ stabilization of buried transuranic/mixed waste, New York., Brookhaven National Labora-tory, (1996), 32p.
    18. Aitcin, P. C., High-Performance Concrete, E & FN Spon, Routledge, London, (1998).
    19. Usherov-Marshak A.V., Sopov V.P., “Betonyi novogo pokoleniya: osnovyi polucheniya i perspektivyi razvitiya”, Naukoviy visnik budivnitstva, No55, (2009), pp. 231-239.
    20. Kalashnikov, V.I. “Kapillyarnaya usadka vyisokoprochnyih reak-tsionno- poroshkovyih betonov i vliyanie masshtabnogo faktora”, Stroitelnyie materialyi, No5, (2010), pp.52-53.
    21. Kalashnikov, V.I., “Cherez ratsionalnuyu reologiyu ‒ v buduschee betonov”, Tehnologiya betonov, No6. 4.2, (2007), pp. 8-10.
    22. Minakov S.V., Vliyanie elektropoverhnostnyih svoystv mineralnyih dobavok na effektivnost razzhizhiteley tsementnyih sistem: dis. na soiskanie uchenoy stepeni kandidata tehnicheskih nauk, Belgo-rodskiy gosudarstvennyiy tehnologicheskiy universitet im. V.G. Shuhova, Belgorod, (2011).
    23. Ivaschenko, S.I., Komar, A.G., “Issledovanie vliyaniya mineralnyih i organicheskih dobavok na svoystva tsementov i betonov”, Izvesti-ya vuzov. Stroitelstvo, No9, (1993), pp.16- 19.
    24. Zotkin, A.F. “Effektyi ot mineralnyih dobavok v betone”, Tehnologiya.betonov, No4, (2007), pp.10-12.
    25. Dauksys, M, Skripkiunas G., Ivanauskas E., “Microsilica and Plasti-cizing Admixtures Influence on Cement Slurry Dilatancy”, Materi-als science (Medžiagotyra), Vol. 14, No. 2, (2008), pp. 143-150.
    26. Piskunov, V. G., Goryk, A. V., & Cherednikov, V. N. (2000). Modeling of transverse shears of piecewise homogeneous composite bars using an iterative process with account of tangential loads. 1. construction of a model.Mechanics of Composite Materials, 36(4), 287-296. https://doi.org/10.1007/BF02262807
    27. Kochkarev, D., & Galinska, T. (2017). Calculation methodology of reinforced concrete elements based on calculated resistance of rein-forced concrete. Paper presented at the MATEC Web of Confer-ences, , 116 https://doi.org/10.1051/matecconf/201711602020
    28. Leshchenko, M. V., & Semko, V. (2015). Thermal characteristics of the external walling made of cold-formed steel studs and polysty-rene concrete. Magazine of Civil Engineering, 60(8), 44-55. https://doi.org/10.5862/MCE.60.6
    29. Semko, O., Yurin, O., Avramenko, Y., & Skliarenko, S. (2017). Thermophysical aspects of reconstruction of cold roof spaces. Paper presented at the MATEC Web of Conferences, , 116 https://doi.org/10.1051/matecconf/201711602030

  • Downloads

  • How to Cite

    Sopov, V., Dolgiy, V., Latorets, K., & Zhuravlov, Y. (2018). High-Mobility Concrete Mixes for Concrete-Filled Steel Tube Structures of Complex Cross-Section. International Journal of Engineering and Technology, 7(4.8), 295-300. https://doi.org/10.14419/ijet.v7i4.8.27259