Progressive Collapse of Structural Systems Considering Force and Corrosion Damage

The main directions of development of the theory of structural safety of buildings and structures have been formulated. A hierarchical approach to the assessment of structural safety of objects under corrosion damage from structural materials to structural system is proposed. Peculiarities of corrosion damageability of concrete of reinforced concrete structures are determined, mechanisms of force and corrosion effects and their influence on progressive destruction of structural systems of exploited buildings are analyzed.

1. Merkulov S.I. Strength and Deformability of Reinforced Concrete Structures in Service. World Applied Sciences Journal. 2013. No. 25 (12). Pp. 1747-1750.

2. Bondarenko V.M., Kolchunov V.I. Concepts and directions of development of the theory of structural safety of buildings and structures under force and environmental influences. Industrial and civil construction. 2013. No. 2. Pp. 28-31.

3. Bondarenko V.M., Merkulov S.I. Methodological foundations of the theory of structural safety of reconstructed reinforced concrete. Structural mechanics of engineering structures and structures. 2008. No. 3. Pp. 77-80.

4. Bondarenko V.M. Corrosion damage as a cause of avalanche destruction of reinforced concrete structures. Structural mechanics and design of structures. 2009. No. 5. Pp. 13-17.

5. Podvalny A.M. Physico-chemical mechanics — the basis of scientific ideas about the corrosion of concrete and reinforced concrete. Concrete and reinforced concrete. 2000. No. 5. Pp. 23-27.

6. Nazarov Yu.P., Gorodetsky A.S., Simbirkin V.N. On the problem of ensuring the survivability of building structures under emergency impacts. Structural mechanics and design of structures. 2009. No. 4. Pp. 5-9.

7. Bondarenko V.M., Fedorov V.S. Models in theories of deformation and destruction of building materials. Academia. Architecture and construction. 2013. No. 2. Pp. 103-106.

8. Merkulov S.I. Fundamentals of the theory of reinforced concrete reconstruction. Kursk : Kursk. state those. Univ., 2009. 248 p.

9. Merkulov S.I., Tatarenkov A.I., Lesovik R.V. Assessment of progressive collapse of operated buildings and structures based upon structural damage. International Conference on Actual Issues of Mechanical Engineering (AIME). AER-Advances in Engineering Research. 2017. Vol. 133. Pp. 409-413.

10. Bulgakov S.N., Tamrazyan A.G., Rakhman I.A., Stepanov A.Yu. Reducing risks in construction during natural and man-made emergencies: Scientific publication. Under general ed. A.G. Tamrazyan. Moscow : ASV Publishing House, 2012. 304 p.

11. Merkulov S.I., Lesovik R.V., Metrohin A.A., Kalashnikov N.V. Development of Theory of Structural for Buildings and Construction. World Applied Sciences Journal. 2014. Vol. 31. No. 4. Pp. 531-533.

12. MNSN 4.19–05. Multifunctional high-rise buildings and complexes. Moscow : Department of Urban Policy, Development and Reconstruction of Moscow, OJSC TsNIIEPzhilishcha, 2005. 70 p.

13. MGSN 4.19–2005. Temporary norms and rules. Design of multifunctional high-rise buildings and building complexes in Moscow. Enter. 2005-12-28. Moscow : Government of Moscow, Moskomarkhitektura, 2005.

14. EN 1991-1-7. Part 1-7: General Actions — Accidental actions. CEN. 2003, p. 69.

15. UFC 4-023-03. Design of buildings to resist progressive collapse. Department of Defense, 2003, 176 p.