Strength and Deformation of Bendable Plastic-Concrete-Tubal Structures

Alexander V. Dolzhenko; Andrey E. Naumov; A.V. Klyuev; N.A. Simonov

doi:10.4028/www.scientific.net/MSF.974.589

Paper Titles

Determination of Coefficients for Defining the Deformations when Calculating Reinforced Concrete Structures on Deformation and Cracking Disclosure
p.564

Improving the Methodology for Calculating the Bearing Capacity of Eccentrically Compressed Reinforced Concrete Elements Based on the Use of the Refined Curvilinear Deformation Diagrams of Concrete and Reinforcement
p.570

Investigation of the Effect of Reinforcing Diaphragms Ribbed Panels on their Carrying Capacity
p.577

Cascade Strengthening of Bent Elements by Polymers with Adhesive Joints
p.583

Strength and Deformation of Bendable Plastic-Concrete-Tubal Structures
p.589

Light Steel Thin -Walled Structures Composite Beam of Cellular Concrete
p.596

Analysis of Prestressed Bent Precast-Cast-In-Situ Structures in Vlasov-Mileykovsky Method with Physical Non-Linearity of Material
p.601

Comparative Analysis of Plasticity Theory Algorithms in Finite-Element Calculations of the Rotation Shell
p.608

Probable Calculation of Reinforced Concrete Elements by Deformation
p.614

HomeMaterials Science ForumMaterials Science Forum Vol. 974Strength and Deformation of Bendable...

Strength and Deformation of Bendable Plastic-Concrete-Tubal Structures

Abstract:

In modern construction production, structures with the use of tube concrete elements are increasingly used [1]. The use of such structures can significantly reduce the weight of the building, as well as reduce the cost of construction and installation works by 2-3 times compared with similar structures made of classical reinforced concrete. At the same time, labor costs are reduced by 4–5 times. In comparison with metal structures, the cost is significantly reduced and the steel consumption is reduced by a factor of 2–3 with a slight increase in weight. Currently in our country the use of tube concrete structures is not widespread due to insufficient study of their work under various influences. The tube in tube concrete structures simultaneously plays the role of a shell, as well as longitudinal and transverse reinforcement. For a classic tube concrete, the tube is able to perceive the resulting forces from different angles and in all directions. Concrete in the plastic tube, being in conditions of triaxial compression and withstands stresses considerably exceeding the cube and prism strength of concrete. In such structures, the tube prevents the formation of microcracks in the concrete core.

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Periodical:

Materials Science Forum (Volume 974)

Pages:

589-595

DOI:

https://doi.org/10.4028/www.scientific.net/MSF.974.589

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Online since:

December 2019

Authors:

Alexander V. Dolzhenko*, Andrey E. Naumov, A.V. Klyuev, N.A. Simonov

Keywords:

Bending, Plastic Tube Concrete, Strength Calculations of Building Structures, Tube Concrete

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References

[1] K. Sakino, H. Nakahara, S. Morino, I. Nishiyama, Behavior of centrally loaded concrete-filled steel-tube short columns, J. Struct. Eng. ASCE. 130 (2) (2004)180-188.

DOI: 10.1061/(asce)0733-9445(2004)130:2(180)

Google Scholar

[2] S.P. Schneider, Axially loaded concrete-filled steel tubes, J. Struct. Eng. ASCE. 124 (1998) 1125-1138.

DOI: 10.1061/(asce)0733-9445(1998)124:10(1125)

Google Scholar

[3] C.S. Huang, Y.K. Yeh, G.Y. Liu, H.T. Hu, K.C. Tsai, Y.T. Weng, S.H. Wang, M.H. Wu, Axial load behavior of stiffened concrete- filled steel columns, J. Struct. Eng. ASCE. 128 (9) (2002) 1222-1230.

DOI: 10.1061/(asce)0733-9445(2002)128:9(1222)

Google Scholar

[4] B. Uy, High-strength steel-concrete composite columns for buildings, Struct. Build. 156 (2003) 3-14.

Google Scholar

[5] A. Dolzhenko, A. Naumov, A. Shevchenko, Bearing capacity and rigidity of short plastic-concrete-tubal vertical columns under transverse load, IOP Conf. Series, Materials Science and Engineering. 327 (2018).

DOI: 10.1088/1757-899x/327/4/042024

Google Scholar

[6] A.V. Dolzhenko, A.E. Naumov, A.V. Shevchenko, N. Stoykovich, Numerical researches of the stressedstrained state of plastic tubed concrete pier under central compression load, Bulletin of BSTU named after V.G. Shukhov. 10 (2018) 23–32.

DOI: 10.12737/article_5bd95a716cf0c5.55926144

Google Scholar

[7] A.V. Dolzhenko, A.E. Naumov, A.V. Shevchenko, N. Stoykovich, Influence of the tangential forces of friction on stressed-deformed state of polimer concrete pipe of centrally compressed short rod. Bulletin of BSTU named after V.G. Shukhov. 12 (2018) 42–51.

DOI: 10.12737/article_5c1c99553a7828.01508345

Google Scholar

[8] I.R. Seryh, E.V. Chernyshova, Science-intensive technologies and innovations: Jubilee International scientific-practical conference dedicated to the 60th anniversary of BSTU named after V.G. Shukhov, XXI scientific readings. Belgorod State Technological University named after V.G. Shukhov. (2014) 112-115.

DOI: 10.15863/tas.2015.01.21.24

Google Scholar

[9] L.K. Luksha, Strength of tube-concrete, High, Minsk, (1977).

Google Scholar

[10] P.S. Sanzharovsky, Theory and calculation of the strength and stability of structural elements from steel tubes filled with concrete, (2000).

Google Scholar

[11] A.P. Filin, Elements of the theory of cases, Ed. 2nd., Stroiizdat, Moscow, (1975).

Google Scholar

[12] V.A. Snigireva, G.L. Gorynin, The nonlinear stress-strain state of the concrete-filled steel tube structures. Magazine of Civil Engineering. 83 (7) (2018) 73–82.

Google Scholar

[13] A.R. Rzhanitsyn, The theory of calculation of building structures for reliability, Stroiizdat, Moscow, (1978).

Google Scholar

[14] N.I. Karpenko, General models of reinforced concrete mechanics. Stroiizdat, Moscow, (1996).

Google Scholar