Your search keyword '"Beskopylny, Alexey N."' showing total 7 results

1. Modeling and Calculation of Improved Centrifuged Reinforced Concrete Columns with Variotropic Structure.

Author

Stel'makh, Sergey A., Shcherban', Evgenii M., Beskopylny, Alexey N., Mailyan, Levon R., Veremeenko, Andrey, Shilov, Aleksandr V., Ananova, Oxana, Karalar, Memduh, Aksoylu, Ceyhun, and Onuralp Özkılıç, Yasin

Subjects

ECCENTRIC loads, COMPOSITE columns, CONCRETE columns, REINFORCED concrete, REINFORCING bars, COLUMNS

Abstract

The use of vibro-centrifugation technology allows the manufacture of variotropic structures that are inhomogeneous in the annular section and have different characteristics along the section thickness. Hardening of the outer layers allows the structure to better resist bending conditions, however, the behavior of the variotropic column under central and eccentric compression remains unexplored. This article considers the problem of compression of hollow columns made of homogeneous concrete that is non-uniform in the annular section (variotropic), and is reinforced with steel reinforcing bars at different values of the load application eccentricity. Variotropic concrete obtained by vibro-centrifugation technology has a stronger outer part and a less durable inner part. The strength of a homogeneous column corresponds to the strength of the middle part of variotropic concrete. The problem was solved numerically in the ANSYS environment for a vertical column rigidly clamped at the bottom edge and loaded with eccentricity at the top edge. Three types of eccentricity are considered; e/r = 0, 0.16 and 0.32 (respectively 0 mm, 0.24 mm and 48 mm). The results of the solution in the form of stress fields, deformations and a pattern of crack development in a spatial setting are obtained. The results showed that for central compression, a homogeneous column has a better bearing capacity of 3.6% than a variotropic one. With the values of eccentricity e/r = 0.16 and 0.32, the variotropic column has a higher bearing capacity (by 5.5% and 6.2%) than the homogeneous one and better resists the development of cracks. The significance of the study lies in the practical application of the proposed approach, developed on a research basis, for non-trivial and complicated operating conditions of columns. This study influences the development of reinforced concrete structures and applies scientific findings to engineering practice. [ABSTRACT FROM AUTHOR]

Published

2023

2. Physical and Mechanical Characteristics of Variotropic Concrete during Cyclic and Continuous Sulfate Attack.

Author

Shcherban', Evgenii M., Stel'makh, Sergey A., Beskopylny, Alexey N., Mailyan, Levon R., Meskhi, Besarion, Elshaeva, Diana, and Chernil'nik, Andrei

Subjects

CONCRETE, REINFORCING bars, SULFATES, DETERIORATION of concrete, LYOTROPIC liquid crystals

Abstract

The concrete of numerous buildings and structures is at increased risk due to various kinds of aggressive pollutants. In this regard, it is necessary to implement and take additional actions, among which the so-called technological methods for concrete structure property modification are promising. These methods comprise improvement and modernization of existing technologies to produce the most effective concrete building structures before the introduction of steel reinforcement. One of the effective and proven technological and design solutions is the use of centrifuged and vibrocentrifuged concrete of an annular section with a variotropic concrete structure. The aim of the work was to study the physical and mechanical properties of variotropic concretes of annular structures when exposed to sulfate attack. As a result of the cyclic impact of sulfate attack, the mass loss of vibrocentrifuged concrete was the smallest in comparison with centrifuged (17% less) and vibrated concrete (37% less). The loss of cube and prism strength of vibrocentrifuged concrete was the smallest in comparison with centrifuged (20% and 18% less, respectively) and vibrated concrete (42% and 38% less, respectively). The sulfate attack rate, as a depth of penetration and concrete destruction, was 46% less for vibrocentrifuged concrete than for centrifuged concrete and 65% less than for vibrated concrete. [ABSTRACT FROM AUTHOR]

Published

2023

3. Numerical Simulation of the Bearing Capacity of Variotropic Short Concrete Beams Reinforced with Polymer Composite Reinforcing Bars.

Author

Beskopylny, Alexey N., Meskhi, Besarion, Stel'makh, Sergey A., Shcherban', Evgenii M., Mailyan, Levon R., Veremeenko, Andrey, Akopyan, Vladimir, Shilov, Aleksandr V., Chernil'nik, Andrei, and Beskopylny, Nikita

Subjects

*FIBROUS composites, *REINFORCING bars, *CONCRETE beams, *LYOTROPIC liquid crystals, *REINFORCED concrete, *GLASS composites, *COMPUTER simulation

Abstract

One of the disadvantages of reinforced concrete is the large weight of structures due to the steel reinforcement. A way to overcome this issue and develop new types of reinforcing elements is by using polymer composite reinforcement, which can successfully compensate for the shortcomings of steel reinforcement. Additionally, a promising direction is the creation of variotropic (transversely isotropic) building elements. The purpose of this work was to numerically analyze improved short bending concrete elements with a variotropic structure reinforced with polymer composite rods and to determine the prospects for the further extension of the results obtained for long-span structures. Numerical models of beams of a transversally isotropic structure with various types of reinforcement have been developed in a spatially and physically nonlinear formulation in ANSYS software considering cracking and crashing. It is shown that, in combination with a stronger layer of the compressed zone of the beam, carbon composite reinforcement has advantages and provides a greater bearing capacity than glass or basalt composite. It has been proven that the use of the integral characteristics of concrete and the deflections of the elements are greater than those when using the differential characteristics of concrete along the height of the section (up to 5%). The zones of the initiation and propagation of cracks for different polymer composite reinforcements are determined. An assessment of the bearing capacity of the beam is given. A significant (up to 146%) increase in the forces in the reinforcing bars and a decrease in tensile stresses (up to 210–230%) were established during the physically non-linear operation of the concrete material. The effect of a clear redistribution of stresses is in favor of elements with a variotropic cross section in height. [ABSTRACT FROM AUTHOR]

Published

2022

4. Reinforced Concrete Columns with Local Prestressing Rebars: A Calculation Theory and an Experimental Study.

Author

Chepurnenko, Anton, Lipovich, Andrei, Beskopylny, Alexey N., and Meskhi, Besarion

Subjects

CONCRETE columns, REINFORCED concrete, PRESTRESSED concrete, REINFORCING bars, PRESTRESSED construction, TENDONS (Prestressed concrete)

Abstract

Local prestressing of reinforcement can be effective for slender reinforced concrete columns with large longitudinal force eccentricities. This article deals with columns with prestressed reinforcement on the side opposite to the eccentricity of the longitudinal force. Prestressing is created with the help of turnbuckles. The aim of the work is to develop a model for determining the stress–strain state of columns with local prestress and its experimental verification. The article presents the derivation of a resolving equation for the increment of deflection, which considers the non-linearity of the concrete and reinforcement work, the presence of creep and shrinkage of concrete. The solution of the resulting equation was performed numerically by the finite difference method in a MATLAB environment. Experimental studies were carried out according to the hinged support scheme for eight eccentrically compressed samples, four of which had been prestressed. Experiments and numerical modeling of columns with local prestressing showed a significant increase in crack resistance (by 1.3–2.5 times) and bearing capacity (by 12.5–30%) compared to similar structures without prestressing. [ABSTRACT FROM AUTHOR]

Published

2022

5. Theoretical and Experimental Substantiation of the Efficiency of Combined-Reinforced Glass Fiber Polymer Composite Concrete Elements in Bending.

Author

Meskhi, Besarion, Beskopylny, Alexey N., Stel'makh, Sergey A., Shcherban', Evgenii M., Mailyan, Levon R., Beskopylny, Nikita, and Dotsenko, Natal'ya

Subjects

*FIBROUS composites, *FIBER-reinforced concrete, *GLASS fibers, *REINFORCING bars, *POLYMER-impregnated concrete, *BENT functions, *CHARACTERISTIC functions

Abstract

An essential problem of current construction engineering is the search for ways to obtain lightweight building structures with improved characteristics. The relevant way is the use of polymer composite reinforcement and concrete with high classes and prime characteristics. The purpose of this work is the theoretical and experimental substantiation of the effectiveness of combined-reinforced glass fiber polymer composite concrete (GFPCC) bending elements, and new recipe, technological and design solutions. We theoretically and experimentally substantiated the effectiveness of GFPCC bending elements from the point of view of three aspects: prescription, technological and constructive. An improvement in the structure and characteristics of glass fiber-reinforced concrete and GFPCC bending elements of a new type has been proven: the compressive strength of glass fiber-reinforced concrete has been increased up to 20%, and the efficiency of GFPCC bending elements is comparable to the concrete bending elements with steel reinforcement of class A1000 and higher. An improvement in the performance of the design due to the synergistic effect of fiber reinforcement of bending elements in combination with polymer composite reinforcement with rods was revealed. The synergistic effect with optimal recipe and technological parameters is due to the combined effect of dispersed fiber, which strengthens concrete at the micro level, and polymer composite reinforcement, which significantly increases the bearing capacity of the element at the macro level. Analytical dependences of the type of functions of the characteristics of bent concrete structures on the arguments—the parameters of the combined reinforcement with fiber and polymer composite reinforcement—are proposed. The synergistic effect of such a development is described, a new controlled significant coefficient of synergistic efficiency of combined reinforcement is proposed. From an economic point of view, the cost of the developed elements has been reduced and is economically more profitable (up to 300%). [ABSTRACT FROM AUTHOR]

Published

2022

6. Modeling and Experimental Verification of the Performance of Polymer Composite Reinforcing Bars of Different Types in Concrete of Different Density.

Author

Beskopylny, Alexey N., Stel'makh, Sergey A., Shcherban', Evgenii M., Mailyan, Levon R., Meskhi, Besarion, Efremenko, Innessa, Varavka, Valery, Beskopylny, Nikita, and Dotsenko, Natal'ya

Subjects

*REINFORCING bars, *FIBROUS composites, *LIGHTWEIGHT concrete, *CONCRETE, *COMPRESSION loads, *BUILDING-integrated photovoltaic systems

Abstract

Currently, there is a scientific and practical deficit in new methods of integrated technological and design solutions based on improving the properties of concrete as the primary material that perceives compressive loads, and its joint work with various types of reinforcing rods. A new system using an integrated engineering approach to the design of building structures is proposed, which involves minimizing their cost and weight through numerical simulations and an experimental verification of the operation of reinforcing bars made of various materials in concrete of various densities. The control of the bearing capacity of reinforced building structures on the example of compressed elements is proposed to be carried out using the developed recipe-technological methods at the manufacturing stage. The economic and environmental efficiency of nano modification with the help of production waste and the use of lightweight dispersion-reinforced concrete to obtain such structures was revealed. The most effective concrete formulations showed strength gains ranging from 10% to 34%. Ultimately, this led to an increase in the bearing capacity of the elements up to 30%. The application of such an integrated lean approach will allow saving up to 20% of resources during construction. [ABSTRACT FROM AUTHOR]

Published

2022

7. Ultimate Compressive Strains and Reserves of Bearing Capacity of Short RC Columns with Basalt Fiber.

Author

Shilov, Aleksandr V., Beskopylny, Alexey N., Meskhi, Besarion, Mailyan, Dmitry, Shilov, Dmitry, and Polushkin, Oleg O.

Subjects

FIBER-reinforced concrete, BASALT, REINFORCING bars, STRAIN gages, FIBERS, CONCRETE columns, REINFORCED concrete

Abstract

Increasing the bearing capacity of reinforced concrete structures, reducing material consumption, and ensuring quality are critical in modern construction. The article presents an experimental study of the ultimate compressive strains of short fiber basalt reinforced concrete columns and provides recommendations for increasing the bearing capacity using steel reinforcement bars with greater strength. The columns were tested in an upright position using a hydraulic press. Strains were measured with dial indicators and a strain gauge station. It was shown that the addition of 10% coarse basalt fiber increased the ultimate compressibility of concrete on ordinary crushed stone by 19.8%, and expanded clay concrete by 26.1%, which led to the strain hardening of concrete under compression by 9.0% and 12%, respectively. Ultimate compressive strains in fiber-reinforced concrete short columns with combined reinforcement increased 1.42 times in columns on a lightweight aggregate and 1.19 times on heavy aggregate. An increase in the ultimate compressibility of concrete makes it possible to use steel reinforcement with greater strength in compressed elements as the concrete crushing during compression occurs primarily due to the reaching of critical values by tensile stresses in the transverse direction. This makes it possible to manufacture structures with a higher load-bearing capacity and less material consumption. A practical example of the application of the proposed approach is given. [ABSTRACT FROM AUTHOR]

Published

2021