Numerical investigation of the effect of support conditions on beam shear behaviour in full scale reinforced concrete beams

Langevin, Hélène M.; Sherman, Karen J.

doi:10.14256/jce.3823.2023

JCE

2024

DOI: 10.14256/jce.3823.2023

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Numerical investigation of the effect of support conditions on beam shear behaviour in full scale reinforced concrete beams

Abstract: In studies on beams in the literature, the beam elements are designed and tested as simply supported. Therefore, in this study, the behaviour of reinforced concrete (RC) beams under fixed support conditions was numerically investigated using ANSYS finite element software. The variables used in the study are the shear span/effective depth ratio (a/d) and stirrup spacing of the analysed specimens. In this study, 16 RC beams on a 1/1 scale were analysed in 4-point bending protocol. The a/d ratios were assumed to … Show more

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Numerical Investigation of Torsional Behaviour of Reinforced Concrete Elements With Different Section Shapes

Solak,

Cengiz,

Ünal

et al. 2024

Konya Journal of Engineering Sciences

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When torsional cracks occur in the RC element as a result of torsion effects occurring in the structure, the cross-section stiffness decreases by 1/10-1/30 of the stiffness before cracking. When the design codes are examined, it is seen that the reinforced concrete design under the effect of torsion is not sufficiently emphasized. In the study, it is aimed to determine the cross-sectional properties of reinforced concrete elements that will be exposed to torsion effects in accordance with the behavior of the RC element. In this study, reinforced concrete elements with circular, square and rectangular cross-section shapes were modeled in accordance with the cross-section and reinforcement conditions specified in TEC-2007 and analyzed by ANSYS program. The torsional capacities of the elements increase as the cross-sectional area increases. Circular sections exhibit a highly ductile behavior in terms of rotation. Rectangular sections have more stiffness than circular and square sections to torsion.

show abstract

Numerical Investigation of Torsional Behaviour of Reinforced Concrete Elements With Different Section Shapes

Solak,

Cengiz,

Ünal

et al. 2024

Konya Journal of Engineering Sciences

View full text Add to dashboard Cite

show abstract

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Numerical investigation of the effect of support conditions on beam shear behaviour in full scale reinforced concrete beams

Cited by 1 publication

References 24 publications

Numerical Investigation of Torsional Behaviour of Reinforced Concrete Elements With Different Section Shapes

Numerical Investigation of Torsional Behaviour of Reinforced Concrete Elements With Different Section Shapes

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