ANÁLISE DE SENSIBILIDADE DE VIGAS MISTAS DE AÇO E CONCRETO SUBMETIDAS A MOMENTO FLETOR NEGATIVO PARA MODELOS CONSTITUTIVOS DO AÇO

Juliano Branjão Zonta; Felipe Piana Vendramell Ferreira; Alexandre  Rossi

doi:10.4025/revtecnol.v33i1.72966

Juliano Branjão Zonta Universidade Federal de Uberlândia
Felipe Piana Vendramell Ferreira Universidade Federal de Uberlândia
Alexandre Rossi Universidade Federal de Uberlândia

DOI: https://doi.org/10.4025/revtecnol.v33i1.72966

Abstract

Composite steel and concrete beams stand out as an efficient structural solution for multi-story buildings, contributing to the reduction of overall height and self-weight of the structure. Current research in this field predominantly relies on numerical modeling to enhance understanding. However, there exists a gap in sensitivity analysis for different constitutive models of the steel profile. This study aims to explore the predictive capability of four constitutive models for the steel profile of composite beams. The models will be evaluated through numerical simulations using the ABAQUS® program, considering experimental tests. The findings indicate that the assessed constitutive models demonstrate a strong predictive capacity for the real structural behavior.

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References

ABAQUS. Dassault Systèmes Simulia. Abaqus, 6.12.2012. , [s.d.].

CEB-FIB. Model Code 2010. , 2010.

EARLS, C. J. Effects of material property stratification and residual stresses on single angle flexural ductility. Journal of Constructional Steel Research, v. 51, n. 2, p. 147–175, ago. 1999.

GALAMBOS, T. V.; KETTER, R. L. Columns Under Combined Bending and Thrust. Journal of the Engineering Mechanics Division, v. 85, n. 2, p. 1–30, abr. 1959.

HORDIJK, D. A. Local approach to fatigue of concrete. Delft: University of Technology, 1991. Disponível em: http://resolver.tudelft.nl/uuid:fa87147b-8201-47ed-83d7-b812b09c5fbb

HOSSEINPOUR, M. et al. New predictive equations for LDB strength assessment of steel–concrete composite beams. Engineering Structures, v. 258, p. 114121, maio 2022.
VIEIRA, H. C; FAKURY, R. H. Análise numérica da flambagem do montante de alma devida ao cisalhamento em vigas de aço celulares. Belo Horizonte, MG, Brasil: Universidade Federal de Minas Gerais (UFMG), 2014.

L. TONG et al. Experimental investigation on mechanical behavior of steel-concrete composite beams under negative bending. Journal of Building Structures, v. 35, n. 10, p. 1–10, 2014.

QUEIROZ, F. D.; VELLASCO, P. C. G. S.; NETHERCOT, D. A. Finite element modelling of composite beams with full and partial shear connection. Journal of Constructional Steel Research, v. 63, n. 4, p. 505–521, abr. 2007.

ROSSI, A. et al. Lateral distortional buckling in steel-concrete composite beams: A review. Structures, v. 27, p. 1299–1312, out. 2020.

ROSSI, A. et al. The influence of structural and geometric imperfections on the LDB strength of steel–concrete composite beams. Thin-Walled Structures, v. 162, p. 107542, maio 2021a.

ROSSI, A. et al. A Parametric Study on the LDB Strength of Steel-Concrete Composite Beams. Eng, v. 4, n. 3, p. 2226–2253, 27 ago. 2023.

WANG, X.-Q. et al. Tensile stress-strain models for high strength steels. Journal of Constructional Steel Research, v. 186, p. 106879, nov. 2021.
WIJESIRI PATHIRANA, S. et al. Flexural behaviour of composite steel–concrete beams utilising blind bolt shear connectors. Engineering Structures, v. 114, p. 181–194, 1 maio 2016.

YUN, X.; GARDNER, L. Stress-strain curves for hot-rolled steels. Journal of Constructional Steel Research, v. 133, p. 36–46, jun. 2017.