Analysis of Equivalent Flexural Stiffness of Steel–Concrete Composite Beams in Frame Structures

Tao, Mu‐Xuan; Li, Ziang; Zhou, Qi-Liang; Xu, Lihua

doi:10.3390/app112110305

Applied Sciences

2021

DOI: 10.3390/app112110305

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Analysis of Equivalent Flexural Stiffness of Steel–Concrete Composite Beams in Frame Structures

Mu‐Xuan Tao

Ziang Li

Qi-Liang Zhou

et al.

Abstract: Vertical deflection of a frame beam is an important indicator in the limit-state analysis of frame structures, particularly for steel–concrete composite beams, which are usually designed with large spans and heavy loads. In this study, the equivalent flexural stiffness of composite frame beams is analysed to evaluate their vertical deflection. A theoretical beam model with a spring constraint boundary and varied stiffness segments is established to consider the influence of both the rotation restraint stiffnes… Show more

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Cited by 3 publications

References 32 publications

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Minimum design bending moment for systems of equivalent stiffness

de Macêdo Wahrhaftig,

Plevris,

Abdullah Mohamad

et al. 2023

Structures

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Minimum design bending moment for systems of equivalent stiffness

de Macêdo Wahrhaftig,

Plevris,

Abdullah Mohamad

et al. 2023

Structures

View full text Add to dashboard Cite

Flexural performance of T-shape light-weight concrete filled steel tubular girder

El-Kherbawy,

Morsy,

Abdel-Ghaffar

et al. 2023

J. Eng. Appl. Sci.

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This paper proposes an optimization study for both structure and materials to obtain an affordable, long-span, light-weight, and fast-constructing T-shape lightweight concrete-filled steel tubular (LWCFST) girder in order to be used in bridge construction. This research was performed on a hollow steel tube of Steel-52 (yield limit 360 MPa), which was filled with LWC. A set of parameters had been investigated to illustrate its effect on T-shape LWCFST girder stiffness, toughness, resilience, and ultimate carrying load capacity in order to obtain an equivalent stiffness to that of the typically used precast concrete girder. Based on design codes (EN 1994-1-1/Euro code 4 and ANSI/AISC 360-10) that permit the use of LWC as a filler material, the parameters considered were: the thickness of the steel tube, compressive strength of the filler concrete, and the bond condition between the steel tube and filler lightweight concrete. The yielding and ultimate bending capacity were determined based on the interpreted failure criteria of T-shape LWCFST girder, considering non-linear analysis for both material and loads using ANSYSWORKBENCH software. The results showed that T-shape LWCFST girder can be employed as a significant relative economic alternative to a typical precast girder in the bridge construction field, thanks to its high stiffness/weight ratio. The lightweight concrete inside was effectively employed to delay the local web buckling of the steel tube to increase its bending capacity. In addition, it reduced the total self-weight of the bridge’s superstructure by 20% compared with a typical precast concrete girder. The dominant failure of T-shape LWCFST girders was found in the upper concrete slab due to the compression stress, even though the tensile cracks in the filler concrete occurred after reaching tensile yield stress in the steel tube. Additionally, increasing the value of friction coefficient between steel tube and lightweight concrete up to 0.8 was found to significantly affect the girder stiffness and has a slight effect after, no matter how high it is.

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Vibration and Reliability Analysis of Non-Uniform Composite Beam under Random Load

Wang

Sun

et al. 2022

Applied Sciences

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Non-uniform structures and composite materials have advantages in engineering applications, such as light weight design, multi-functionality, and better buckling/flutter load capacity. For composite structures under dynamic loading conditions, reliability is a key problem to be analyzed during practical operations. However, there is little research work on non-uniform composite structural reliability analysis under random load. The forced vibration response of non-uniform composite beam under random load is firstly solved by the Adomian Decomposition Method (ADM) and iterative process for reliability analysis. Different variation laws of the cross-section rigidity and mass distribution along the length of the non-uniform composite beam structures are analyzed. Various angular frequency and amplitude of random base motion acceleration following Gaussian distribution are considered. Influences of different random excitations and structural design on vibration responses and reliability are studied. The larger mean and variance of excitation frequency leads to the smaller amplitude and strain of the beam, while greater mean and variance of the base motion excitation amplitude will induce the higher maximum amplitude and strain values and lower reliability. The influences of structural design on reliability are studied. The reliability increases with the increment of taper ratios of the host beam and composite layer. The iteration mathematical model and numerical solutions proposed in this paper can be used to solve and analyze vibration responses and reliability of general non-uniform composite beam structures under arbitrary excitation during a certain period of time.

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Analysis of Equivalent Flexural Stiffness of Steel–Concrete Composite Beams in Frame Structures

Cited by 3 publications

References 32 publications

Minimum design bending moment for systems of equivalent stiffness

Minimum design bending moment for systems of equivalent stiffness

Flexural performance of T-shape light-weight concrete filled steel tubular girder

Vibration and Reliability Analysis of Non-Uniform Composite Beam under Random Load

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