The stressed-deformed state of slab reinforced-concrete hollow structures considering the biaxial compression of concrete

Authors

DOI:

https://doi.org/10.15587/1729-4061.2020.194145

Keywords:

reinforced concrete hollow structures, stressed-strained state, biaxial compression of concrete, estimation schemes, strength, rigidity, example of calculation

Abstract

In order to significantly reduce the weight of flat monolithic reinforced concrete floors, foundations, and other slab structures, construction operations have increasingly involved effective inserts as the separate articles made from relatively light and cheap materials that are placed in the midsection and left in the slabs after concreting.

The inserts made from relatively light and cheap materials, with respect to concrete, have the strength and rigidity that are orders of magnitude less and are essentially used to form hollows. The inserts considered in this paper are prismatic. When the inserts are arranged in two directions, which is typical for most slab structures, we obtain the I-sections, whose calculation involved the analysis of the impact exerted by the general and local strength factors. Under such conditions, slabs must be calculated taking into consideration the biaxial work of concrete. In this paper, we have examined the stressed-strained state of the slab reinforced concrete structures with a bidirectional location of inserts and have substantiated the estimation schemes and calculation dependences related to the procedure for calculating the floors and other slab reinforced concrete structures with a bidirectional location of inserts. The paper gives an example of the calculation of a monolithic flooring slab based on the proposed procedure, which demonstrated that accounting for the biaxial stressed-strained state of concrete significantly increases the strength of concrete and the rigidity of a flooring slab, by 19.3 %.

Thus, the consideration of biaxial compression of concrete is an important factor in the design of slab structures with a bidirectional arrangement of inserts

Author Biographies

Andrii Bambura, State Enterprise „State Research Institute of Building Constructions” Preobrazhenska str., 5/2, Kyiv, Ukraine, 03037

Doctor of Technical Sciences, Professor

Department of Reliability of Building Structures

Ihor Mel’nyk, Lviv Polytechnic National University S. Bandery str., 12, Lviv, Ukraine, 79013

PhD, Associate Professor

Department of Building Constructions and Bridges

Vitaliy Bilozir, Lviv National Agrarian University V. Velykoho str., 1, Dubliany, Zhovkva district, Lviv reg., Ukraine, 80381

PhD, Associate Professor

Department of Building Structures

Vasyl Sorokhtey, Lviv Polytechnic National University S. Bandery str., 12, Lviv, Ukraine, 79013

Senior Researcher

Branch Research Laboratory No. 112

Taras Prystavskyi, Lviv Polytechnic National University S. Bandery str., 12, Lviv, Ukraine, 79013

Senior Researcher

Branch Research Laboratory No. 112

Volodymyr Partuta, Lviv Polytechnic National University S. Bandery str., 12, Lviv, Ukraine, 79013

Department of Building Constructions and Bridges

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Published

2020-02-29

How to Cite

Bambura, A., Mel’nyk, I., Bilozir, V., Sorokhtey, V., Prystavskyi, T., & Partuta, V. (2020). The stressed-deformed state of slab reinforced-concrete hollow structures considering the biaxial compression of concrete. Eastern-European Journal of Enterprise Technologies, 1(7 (103), 34–42. https://doi.org/10.15587/1729-4061.2020.194145

Issue

Vol. 1 No. 7 (103) (2020): Applied mechanics

Section

Applied mechanics

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Copyright (c) 2020 Andrii Bambura, Ihor Mel’nyk, Vitaliy Bilozir, Vasyl Sorokhtey, Taras Prystavskyi, Volodymyr Partuta

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