Service limit state of cast-in-place flexural member

Cast-in-place structure design distinguish them from reinforced concrete structures. Cast-in-place structures are involved in deformation and receive external load, so they possess different strength, deformation and other physical properties. In this regard, calculation methods of cast-in-place structures given in regulatory documents require clarification.
Having studied the cast-in-place structure design and considering their stress-strain state, a method is proposed for the analysis of such structures according to their service limit state. This method allows taking into account different times of involvement in the external load and deformation of the cast-in-place structure as well as the difference in concrete strength and deformation properties. It is shown that the experimental data are in satisfactory agreement with theoretical calculations.

1. Kainov E.A. Analysis and evaluation of consumer properties of objects with cast-in-situ frame using expert evaluations. Vestnik sovremennykh issledovanii. 2019; 1.8 (28): 83–88. (In Russian)

2. Kozhambek B.R., Zhusupov T.V., Beisekeyeva S.Z. Cast-in-situ slabs based on a system of permanent formwork. Vestnik sovremennykh issledovanii. 2019; 2.3 (29): 18–21. (In Russian)

3. Zoteeva E.E., Fomin N.I. New technological and structural solutions for the of monolithic and cast-in-situ slab construction. Sovremennye tekhnologii v stroitel'stve. Teoriya i praktika. 2018; (2): 336–341. (In Russian)

4. Olmati P., Sagaseta J., Cormie D., Jones A.E.K. Simplified reliability analysis of punching in reinforced concrete flat slab constructions under accidental actions. Engineering Structures. 2017; (130): 83–98.

5. Qian K., Li B. Resilience of flat slab structures in different phases of progressive collapse. ACI Structural Journal. 2016; (113): 537–548.

6. Drakatos I.S., Muttoni A., Beyer K. Internal slab-column connections under monotonic and cyclic imposed rotations. Engineering Structures. 2016; (123): 501–516.

7. Nedviga E., Beresneva N., Gravit M., Blagodatskaya A. Fire resistance of prefabricated monolithic reinforced concrete slabs of "Marko" technology. Advances in Intelligent Systems and Computing. 2018; (692): 739–749.

8. Yan J.B., Wang J.Y., Liew J.Y.R., Qian X.D., Zhang W. Reinforced ultra-lightweight cement composite flat slabs: Experiments and analysis. Materials and Design. 2016; (95): 148–158.

9. Zeziukov D.M., Makhinko N.N., Butskaya E.L., Kotov N.A. Actual stress state of elements of flat cast-in-situ slabs. Vіsnik Pridnіprovs'koї derzhavnoї akademії budіvnitstva ta arkhіtekturi. 2019; 2 (251–252): 63–70. (In Russian)

10. Poloz M.A., Yasser G.S., Shevchenko A.V. Application of step-iteration method in calculation of bendable prestressed prefabricated monolithic elements taking into account physical nonlinearity. Stroitel'nye materialy i izdeliya. 2019; 2 ( 3): 12–27. (In Russian)

11. Koyankin A.A., Mitasov V.M. Stress-strain state of cast-in-situ flexural element. Magazine of Civil Engineering. 2020; 97 (5). (In Russian)

12. Semeniuk S.D., Moskalkova Yu.G. Strength and deformability of bending elements reinforced by compressive zone build-up under static and low-cycle loading. Mogilev, 2017. 274 p. (In Russian)

13. Lazovsky D.N. Strengthening of reinforced concrete structures of operating buildings. Novopolotsk: PSU, 1998. 240 p. (In Russian)

14. Koyankin A.A., Mitasov V.M. Stress-strain state of cast-in-place and precast structure with loaded cast-in-place element. Vestnik Tomskogo gosudarstvennogo arkhitekturno-stroitel'nogo universiteta – Journal of Construction and Architecture. 2021; 23 ( 3): 129–142. (In Russian)

15. Koyankin A.A., Mitasov V.M., Klindukh N.Yu. Stress-strain state of precast-monolithic bending element. Academia. Arkhitektura i stroitel'stvo. 2021; (3): 101–107. (In Russian)