Determination of the bearing capacity of encentrally compressed concrete filled steel tubular columns on the basis of the deformation theory of concrete plasticity

Objective. The article proposes a method for finite element analysis of pipe-concrete columns in a physically nonlinear setting by reducing a three-dimensional problem to a twodimensional one based on the hypothesis of plane sections.

Method.The equations of the theory of plasticity of concrete by G.A. Geniev are used. The technique was tested by comparing the solution with a calculation in a three-dimensional setting in the LIRA-SAPR software package, as well as with the experimental data of A.I. Sagadatov and calculation according to the current Russian design codes for steel-pipe concrete structures.

Result. It has been established that the effective area of operation of columns with a circular cross section is small eccentricities of the longitudinal force.

Conclusion. The proposed approach can be applied to the analysis of the stress-strain state and the bearing capacity of pipe-concrete columns of arbitrary section. There are no restrictions on the composition of concrete, and the shell material can be not only steel, but also fiberglass. 

1. Rezvan A. V., Kolotienko M. A. Rationalization of technological, constructive and architectural solutions of pipe-concrete structures on the example of columns of high-rise buildings. Inzhenernyy vestnik Dona. 2020;(65). URL: ivdon.ru/ru/magazine/archive/N5y2020/6475

2. Aadsan A., Tenemaza D. O., Kubasov A. Yu. Technical and economic calculation of metal, reinforced concrete and pipe con- crete columns using computer systems. Inzhenernyy vestnik Dona. 2018;2(49). URL: ivdon.ru/ru/magazine/archive/N2y2018/5015

3. Duvanova I. A., Salmanov I. D. Pipe concrete columns in the construction of high-rise buildings and structures. Construction of unique buildings and structures. 2014; 6: 89-103.

4. Krishan A.L. Pipe-concrete columns for multi-storey buildings. Construction mechanics of engineering structures and structures. 2009; 4: 75-80.

5. Krishan A.L., Melnichuk A.S. Pipe-concrete columns of square section Housing construction. 2012; 5:19-20.

6. Krishan A.L., Melnichuk A.S. Strength of square pipe-concrete columns under axial compression. Bulletin of the Magnitogorsk State Technical University. 2012; 3: 51-54.

7. Krishan A. L., Rimshin V. I., Astafyeva M. A. Strength of improved square-section pipe-concrete elements. Building materials. 2018; 6.: 24-28.

8. Krishan A. L., Melnichuk A. S. Bearing capacity of pipe-concrete columns of square cross-section. Innovations in the branches of the national economy as a factor in solving social and economic problems of our time. 2011; 57-59.

9. Ma D. Y. et al. Behaviour of hexagonal concrete-encased CFST columns subjected to cyclic bending. Journal of Constructional Steel Research. 2018; 144: 283-294.

10. Xu W., Han L. H., Li W. Performance of hexagonal CFST members under axial compression and bending. Journal of constructional steel research. 2016; 123: 162-175.

11. Hassanein M. F., Patel V. I., Bock M. Behaviour and design of hexagonal concrete-filled steel tubular short columns under axial compression. Engineering Structures. 2017; 153: 732-748.

12. Fang H., Chan T. M., Young B. Structural performance of concrete-filled cold-formed high-strength steel octagonal tubular stub columns. Engineering Structures. 2021; 239: 112360.

13. Khashkhozhev K. N., Avakov A. A. Calculation of centrally compressed pipe-concrete columns of an annular section taking nto account physical nonlinearity. Construction and architecture. 2021;9.(3). URL: https://riorpub.com/ru/nauka/article/45575/view

14. Krishan A., Astafeva M. Strength and Deformability of the Concrete Core of Precompressed Concrete Filled Steel Tube Columns of Annular Cross-Section. MATEC Web of Conferences. EDP Sciences. 2019; 278: 03002.

15. Krishan A. L., Narkevich M.Y., Sagadatov A.I., Rimshin, V.I. The strength of short compressed concrete elements in a fiberglass shell. Journal of civil engineering. 2020; 2 (94): 3-10.

16. Ouyang Y., Kwan A. K. H. Finite element analysis of square concrete-filled steel tube (CFST) columns under axial compressive load. Engineering Structures. 2018; 156: 443-459.

17. Geniev G.A., Kissyuk G.A., Tyupin V.N. Teoriya plastichnosti betona i zhelezobetona [The theory of plasticity of concrete and reinforced concrete]. Moscow: Stroyizdat, 1974: 316.

18. Andreev V., Potekhin I. Calculation of Equal Strength Thick-Walled Concrete Cylinder with Free Ends. IOP Conference Series: Materials Science and Engineering. IOP Publishing, 2019; 661(1): 012023.

19. Narkevich M. Y., Sagadatov A. I. Strength and deformation property enhancement of compressed steel tube-concrete elements using super concrete and thin-shell structure. IOP Conference Series: Materials Science and Engineering. IOP Publishing, 2019; 687(3): 033031.

20. Sagadatov A. I. Stress-strain state of compressed concrete filled steel tubular elements with an internal steel core: PhD thesis; Magnitogorsk, 2006.