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

Maxim A. Poloz; Nikolay V. Frolov; A.V. Klyuev; Jan Jimei

doi:10.4028/www.scientific.net/MSF.974.601

Paper Titles

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

Implementation of Incremental Yield Condition for Continual Problems with Singularity
p.620

The Influence of the Height of Fiber Reinforcement Zone on the Crack Resistance of Rubcon Beams with Mixed Reinforcement
p.627

HomeMaterials Science ForumMaterials Science Forum Vol. 974Analysis of Prestressed Bent Precast-Cast-In-Situ...

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

Abstract:

Precast reinforced concrete structures with and without reinforcement pre-stressing are used both as newly designed independent ones and are the result of work to strengthen the existing structures by increasing the section. In both cases, the cross section of such elements is considered as a two-layer section, and the resulting composite element works under load under conditions distributed between the layers of internal forces, the mechanism and actual distribution of which depends on the physical and mechanical characteristics, the design scheme and the layers contact interaction parameters. When calculating and designing prestressed reinforced concrete precast-monolithic elements, the shear seam ductility is usually not paid much attention to, which complicates the structure actual stress-strain state analysis and contains a certain undiscovered potential of its rational design. One of the possible directions in solving the problem, which takes into account the contact seam shift, is the structural mechanics variation principles use in the calculation of structures such as rods of composite section. The questions of a composite reinforced concrete precast-monolithic rod of the variation principles of structural mechanics based on the method of V.Z. Vlasov - I.E. Mileykovsky in the displacements form in combination with the step-iterative method of calculation practical applicability in the structural analysis is considered in this work,. The numerical calculations results according to the proposed method are given. This allows to take into account the precast and monolithic layers shear connections specifics, to take practical account of weld compliance, and also to take into account the material characteristics’ physical non-linearity, which contributes to the precast monolithic structures rational design.

You might also be interested in these eBooks

Materials and Technologies in Construction and Architecture II

View Preview

Info:

Periodical:

Materials Science Forum (Volume 974)

Pages:

601-607

DOI:

https://doi.org/10.4028/www.scientific.net/MSF.974.601

Citation:

Cite this paper

Online since:

December 2019

Authors:

Maxim A. Poloz*, Nikolay V. Frolov, A.V. Klyuev, Jan Jimei

Keywords:

Composite Rod, Physical Non-Linearity of Materials, Precast Reinforced Concrete, Prestressing of Reinforcement, Stress-Strain State, Vlasov-Mileykovsky Variation Method

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

Citation:

* - Corresponding Author

References

[1] I.E. Milejkovskij, S.I. Trushin, The calculation of thin-walled structures, Strojizdat, Moscow, 1989. (In Russian).

Google Scholar

[2] V.I. Kolchunov, L.I. Panchenko, Calculation of composite thin-walled structures, ASV, Moscow, 1999. (In Russian).

Google Scholar

[3] O.V. Bajdin, A.V. Shevchenko, S.M. Shapovalov, Experimental study of the fracture toughness of the core precast-monolithic structures, Bulletin of BSTU named after V.G. Shukhov. 2 (2009) 78-83. (In Russian).

Google Scholar

[4] O.V. Bajdin, A.V. Shevchenko, S.M. Shapovalov, Calculation of precast-monolithic structures using variational method and the integral of the modulus of deformation, Structural Mechanics and Analysis of Constructions. 4 (2009) 9-13. (In Russian).

Google Scholar

[5] O.V. Bajdin, A.V. Shevchenko, S.M. Shapovalov, Considering temperature deformations in the calculation of closed cylindrical shells by variational method, Structural Mechanics and Analysis of Constructions. 5 (2009) 6-9. (In Russian).

Google Scholar

[6] A.G. Yurev, L.A. Panchenko, I.R. Seryh, V.G. Rubanov, Thin-walled construction of shallow tunnels, Industrial and civil engineering. 8 (2014) 27-29. (In Russian).

Google Scholar

[7] A.I. Nikulin, The specification of limit values of relative deformations of concrete in compression zone of the bending of reinforced concrete elements, Industrial and civil engineering. 8 (2014) 12-15. (In Russian).

Google Scholar

[8] V.I. Kolchunov, E.A. Skobeleva, A.I. Korzhavyh, To calculate the deformation of reinforced concrete frames with elements of the composite section, Academia, Architecture and construction. 4 (2009) 74-78. (In Russ.).

Google Scholar

[9] D.S. Merkulov, The strength of composite concrete elements with complex stress state. Herald of the Orlov State Technical University, Issue Construction and transport. 4-16 (2007) 48-51. (In Russian).

Google Scholar

[10] V.I. Kolchunov, E.A. Skobeleva, S.I. Gornostaev, Experimental studies of the deformation and fracture of composite structures, Herald of the Orlov State Technical University. Issue Construction and transport. 1-2 (2006) 12-16. (In Russian).

Google Scholar