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Each structure is exposed to different influences during operation. As a result, there are various defects and damages of these elements that affect their safe operation. The article presents the results of experimental studies of reinforced concrete beams with damages to stretched reinforcement made with and without initial load application. As the damages were accepted one or five Ø5.6 mm holes. In one case, the damage was made until the beam destruction (up to the 8.4 mm opening) Control samples of both series were destroyed due to crushing of the compressed zone of concrete. Samples that were damaged without initial loading collapsed due to rupture of the stretched reinforcement. The same type of failure was identified for damages at the operational load level.
Czasopismo
Rocznik
Tom
Strony
242--247
Opis fizyczny
Bibliogr. 24 poz., rys., tab.
Twórcy
autor
- Lviv Polytechnic National University, 12 st. S. Bandera, Lviv, 79013, Ukraine
autor
- Lviv Polytechnic National University, 12 st. S. Bandera, Lviv, 79013, Ukraine
autor
- Lviv Polytechnic National University, 12 st. S. Bandera, Lviv, 79013, Ukraine
autor
- Czestochowa University of Technology, 69 st. Dabrowskiego, 42-201 Czestochowa, Poland
Bibliografia
- 1. Azizov, T.N., Kochkarev, D.V., Galinska, T.A., 2019. New design concepts for strengthening of continuous reinforced-concrete beams. IOP Conference Series: Materials Science and Engineering, 708(1).
- 2. Blikharskyy, Y., Kopiika, N. and Selejdak, J., 2020. Non-uniform corrosion of steel rebar and its influence on reinforced concrete elements` reliability. Production Engineering Archives, 26(2), 67–72.
- 3. Blikharskyy, Y., Vashkevych, R., Kopiika, N., Bobalo, T., Blikharskyy, Z., 2021. Calculation residual strength of reinforced concrete beams with damages, which occurred during loading. IOP Conference Series: Materials Science and Engineering,1021(1).
- 4. Bobalo, T., Blikharskyy, Y., Kopiika, N., Volynets, M., 2021. Influence of the Percentage of Reinforcement on the Compressive Forces Loss in Pre-stressed RC Beams Strengthened with a Package of Steel Bars. Lecture Notes in Civil Engineering, 100, 53–62.
- 5. Czajkowska, A., Ingaldi, M., 2019. Analysis of the impact of individual phases in the building process cycle on the environment with respect to the principles of sustainable development. IOP Conference Series: Earth and Environmental Science, 214(1), 012012. DOI: 10.1088/1755-1315/214/1/012012
- 6. Fomin, O., Vatulia, G., Horbunov, M., Lovska, A., Píštěk, V., Kučera, P., 2021. Determination of residual resource of flat wagons load-bearing structures with a 25-year service life. IOP Conference Series: Materials Science and Engineering, 1021(10).
- 7. Karpiuk, V., Somina, Y., Maistrenko, O., 2019. Engineering Method of Calculation of Beam Structures Inclined Sections Based on the Fatigue Fracture Model. Lecture Notes in Civil Engineering, 47, 135–144.
- 8.Khmil, R.Y., Tytarenko, R.Y., Blikharskyy, Y.Z., Vegera, P.I., 2021a. 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(1).
- 9. Khmil, R., Tytarenko, R., Blikharskyy, Y., Vegera, P., 2021b. The Probabilistic Calculation Model of RC Beams, Strengthened by RC Jacket. Lecture Notes in Civil Engineering, 100, 182–191.
- 10. Klymenko, Y., Grynyova, I., Kos, Z., 2019. The method of calculating the bearing capacity of compressed stone pillars. Lecture Notes in Civil Engineering, 47, 161–167.
- 11. Klymenko, Y., Kos, Z., Grynyova, I., Maksiuta, O., 2020. Operation of Damaged H-Shaped Columns. Lecture Notes in Civil Engineering, 100, 192–201.
- 12. Kochkarev, D., Azizov, T., Galinska, T., 2020. Design of Effective Statically Indeterminate Reinforced Concrete Beams. Lecture Notes in Civil Engineering, 73, 83–93, DOI: 10.1007/978-3-030-42939-3_10
- 13. Kotes, P., Strieska, M., Brodnan, M., 2018. Sensitive analysis of calculation of corrosion rate according to standard approach. IOP Conference Series: Materials Science and Engineering, 385(1), 012031, DOI: 10.1088/1757-899X/385/1/012031
- 14. Koteš, P., Vavruš, M., Jošt, J., Prokop, J., 2020. Strengthening of concrete column by using the wrapper layer of fibre reinforced concrete. Materials, 12(23), 1–21, DOI: 10.3390/ma13235432
- 15. Kramarchuk, A., Ilnytskyy, B., Bobalo, T., Lytvyniak, O., (2021). A study of bearing capacity of reinforced masonry beams with GFRP reinforcement. IOP Conference Series: Materials Science and Engineering, 1021(1).
- 16. Lipiński, T., 2017. Roughness of 1.0721 steel after corrosion tests in 20% NaCl. Production Engineering Archives, 15(15), 27–30.
- 17. Lobodanov, M., Vegera, P., Khmil, R., Blikharskyy, Z., 2021. Influence of Damages in the Compressed Zone on Bearing Capacity of Reinforced Concrete Beams. Lecture Notes in Civil Engineering, 100, 260–267.
- 18. Pavlikov, A., Kochkarev, D., Harkava, O., 2019. Calculation of reinforced concrete members strength by new concept. Proceedings of the fib Symposium 2019, Concrete - Innovations in Materials, Design and Structures, 820–827.
- 19. Turba, Y., Solodkyy, S., 2021. Crack Resistance of Concretes Reinforced with Polypropylene Fiber. Lecture Notes in Civil Engineering, 100, 474–481, DOI: 10.1007/978-3-030-57340-9_58
- 20. Ulewicz, R., Ulewicz, M., 2020. Problems in the Implementation of the Lean Concept in the Construction Industries. Lecture Notes in Civil Engineering, 47, 495–500, DOI: 10.1007/978-3-030-27011-7_63
- 21. Vatulia, G., Lobiak, A., Orel, Y., 2017. Simulation of performance of circular CFST columns under short-time and long-time load. Matec Web of Conferences, 116, 02036, DOI: 10.1051/matecconf/201711602036
- 22. Vatulia, G., Rezunenko, M., Petrenko, D., Rezunenko, S., 2018. Evaluation of the carrying capacity of rectangular steel-concrete columns. Civil and Environmental Engineering, 14(1), 76–83. DOI: 10.2478/cee-2018-0010
- 23. Vavruš, M., Koteš, P., 2019. Numerical comparison of concrete columns strengthened with layer of fiber concrete and reinforced concrete. Transportation Research Procedia, 40, 920–926.
- 24. Yogalakshmi, N.J., Rao, K.B., Anoop, M.B., 2020. Durability-Based Service Life Design of RC Structures—Chloride-Induced Corrosion. Reliability, Safety and Hazard Assessment for Risk-Based Technologies, Springer, Singapore, 579–590, DOI: 10.1007/978-981-13-9008-1_48.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-01229e80-8c5c-4ff5-a0c5-c1fdc08a902b