Calculation method improvement of damaged elements of steel structures

Introduction. Defects and damages of steel structures in combination with metal corrosion, stimulating the loss of local stability, can lead to their limited serviceable condition or operational unsuitability. There is no method for calculating elements with such damages. At the same time, “normative” strength testing of undamaged elements under two or more parametric loading leads to underestimated results. Therefore, the development of a reliable method for calculating the strength of elements, including undamaged ones, under general loading is relevant.

Materials and methods. A method for investigating the strength of damaged and undamaged elements of steel structures in the general case of loading, taking into account the mutual influence of forces on the actual limit state corresponding to the criterion of limited plastic deformation is proposed. The solution of the problem is carried out in dimensionless parameters in reverse order, which reduces the calculation time by several orders of magnitude.

Results. Based on the analysis of the obtained research results, an effective practical method for calculating damaged and undamaged elements is developed, which allows obtaining more reliable information about their strength. The effect of damage on strength was established, which, depending on its location relative to the acting forces N, Mx, My, can lead serviceable, limited or inoperable states. Significant strength reserves of undamaged I-beam elements were identified.

Conclusions. An analytical solution in which the weakening of the cross section is compensated by equivalent loading by fictitious forces, allowing to reduce the strength test as for an undamaged element. The discovered strength reserves of undamaged I-beam elements indicate the need to study the rods with other types of cross sections.

1. Di Sarno L., Majidian A., Karagiannakis G. The effect of atmospheric corrosion on steel structures: a state-of-the-art and case-study. Buildings. 2021; 11(12):571. DOI: 10.3390/buildings11120571

2. Zhao Z., Zhang N., Wu J., Gao Y., Sun Q. Shear capacity of steel plates with random local corrosion. Construction and Building Materials. 2020; 239:117816. DOI: 10.1016/j.conbuildmat.2019.117816

3. Kong Z., Jin Y., Hossen G.M. S., Hong S., Wang Y., Vu Q.V. et al. Experimental and theoretical study on mechanical properties of mild steel after corrosion. Ocean Engineering. 2022; 246:110652. DOI: 10.1016/j.oceaneng.2022.110652

4. Bely G.I. Calculation of elastic-plastic thin-walled rods according to a spatially deformable scheme. Construction Mechanics of Structures. 1983; 40-48. (rus.).

5. Stegachev P.B. Study of issues of assessing the operational condition of steel roof trusses : abstract of thesis. dis. ... cand. tech. sci. Leningrad, 1982; 27. (rus.).

6. Sotnikov N.G. Strength and stability of elements of steel structures from paired corners having general and local defects and damages : abstract of thesis. dis. ... cand. tech. sci. Leningrad, 1987; 28. (rus.).

7. Rodikov N.N. Stability of compressed core elements of structures made of open profiles : dis. ... cand. tech. sci. Leningrad, 1987; 27. (rus.).

8. Lacussa K.S.E. Strength and spatial stability of rods made from single angles : abstract of thesis. dis. ... cand. tech. sci. St. Petersburg, 1993; 26. (rus.).

9. Munkueva E.M. Strength and stability of elements of cross-section steel structures having general and local defects and damages : dis. ... cand. tech. sci. St. Petersburg. 1999; 22. (rus.).

10. Kosorukov V.A. The influence of random bends of compressed rods of steel trusses on their load-bearing capacity : dis. ... cand. tech. sci. Moscow, 1975; 12. (rus.).

11. Oplanchuk A.A. Load-bearing capacity of truss rods made from angles with local defects : dis. ... cand. tech. sci. Novosibirsk, 1983; 241. (rus.).

12. Korchak M.D. On the influence of local initial curvatures of the belt on the stability of a lattice rod. Improving the development of design standards for steel building structures. 1981; 119-127. (rus.).

13. Astashkin M.V. Stress-strain and limit states in sections of rod elements of steel structures in the general case of static loading : dis. ... cand. tech. sci. St. Petersburg, 2003; 130. (rus.).

14. Belyy G.I. “Reverse” method of calculating steel structure rod elements reinforced under load by increasing cross sections. Bulletin of Civil Engineers. 2020; 6(83):46-55. DOI: 10.23968/1999-5571-2020-17-4-39-46. EDN FCYLVT. (rus.).

15. Vedernikova A.A. Numerical and analytical calculation of stability of non-centrally compressed round and square tube concrete rods. Bulletin of SevKavGTI. 2017; 3(30):112-118. EDN ZSIVVL. (rus.).

16. Smirnov M.O. Strength and stability of rod elements of structures made of cold-formed profiles with an actually reduced cross-section : dis. ... cand. tech. sci. St. Petersburg, 2021; 157. (rus.).

17. Smirnov M.O. Improvement of the inverse numerical-analytical method for calculating the light steel thin-walled structures for stability under eccentric compression. Bulletin of Civil Engineers. 2021; 1(84):46-52. DOI: 10.23968/1999-5571-2021-18-1-46-52. EDN TDGIAI. (rus.).

18. Smirnov M.O. Improving the methodology for determining reduced cross-sections of rods from cold-formed profiles at one-parameter loading. Bulletin of Civil Engineers. 2020; 2(79):60-67. DOI: 10.23968/1999-5571-2020-17-2-60-67. EDN NXYLAC. (rus.).

19. Belyy G.I., Garipov A.I. Post-limit stress-strain states of steel structure elements in cross-sections. Bulletin of Civil Engineers. 2022; 4(93):16-30. DOI: 10.23968/1999-5571-2022-19-4-16-30. EDN MPRVNX. (rus.).

20. Zhang Z., Xu S., Wang Y., Nie B., Wei T. Local and post-buckling behavior of corroded axially-compressed steel columns. Thin-Walled Structures. 2020; 157:107108. DOI: 10.1016/j.tws.2020.107108

21. Kullashi G., Siriwardane S.C., Atteya M.A. Lateral torsional buckling capacity of corroded steel beams: A parametric study. IOP Conference Series: Materials Science and Engineering. 2021; 1201(1):012038. DOI: 10.1088/1757-899X/1201/1/012038