Your search keyword '"Noncompact section"' showing total 2 results

1. Vertical shear resistance of noncompact steel–concrete composite girders under combined positive moment and shear

Author

Pengfei Men, Bowen Liang, Wuchao He, Jin Di, Fengjiang Qin, and Zhigang Zhang

Subjects

Steel–concrete composite girder, Positive moment, Noncompact section, Ultimate shear resistance, Finite element method, Design equation, Materials of engineering and construction. Mechanics of materials, TA401-492

Abstract

For noncompact composite girders widely employed in bridge structures, the design can be more reasonable and economical if the shear contribution of concrete slabs is considered. In this study, the ultimate shear resistance of composite girders with noncompact sections under positive moments was investigated using the finite element method (FEM). The validity of the FEM was verified using existing test data. Subsequently, parametric studies were performed using the validated FEM. It was shown that the concrete slab thickness and web height-to-thickness ratio had notable effects on the shear resistance of the slab; the concrete slab width had a negligible effect on the shear resistance if its value exceeded twice the web height; the web aspect ratio mainly affected the shear resistance of the web. The numerical results indicated that the shear resistance of the composite girder was 1.02–1.63 times of that calculated using the ASSHTO code, and 1.12–1.55 times of that calculated using the EC4 code. After comprehensively considering the effects of these parameters, a design equation for predicting the shear resistance of noncompact composite girders under positive moments was suggested and verified using numerical and test data.

Published

2023

2. Noncompact and slender concrete-filled steel tubes under axial compression: Finite-element modeling and evaluation of stress-strain models for fiber-based analysis.

Author

Subedi, Naresh, Obara, Taku, and Kono, Susumu

Subjects

*CONCRETE-filled tubes, *STRAINS & stresses (Mechanics), *STEEL tubes, *FINITE element method

Abstract

This study provides guidelines for the detailed finite-element modeling and efficient fiber-based analysis of noncompact/slender CFSTs under axial compression. To this end, a finite-element model capable of explicitly simulating the interaction between the concrete and steel tube is developed in LS-DYNA. The accuracy of the proposed model is verified using a database of ninety-six noncompact and slender CFSTs compiled from the literature. In addition, seven sets of most commonly used stress-strain models for the fiber-based analysis of CFSTs are briefly reviewed. The suitability of the stress-strain models to simulate the behavior under axial compression is evaluated using the experimental data in the compiled database and the finite element analysis results. The results show that the proposed finite-element model reasonably simulates the axial compression response of noncompact and slender CFSTs. For the fiber-based approach, Sakino's model gives the best prediction of the full-range axial load-displacement response. Findings from this study will help the designers and researchers to select appropriate modeling approaches and model parameters for the design and analysis of noncompact and slender CFSTs. • Database of 96 noncompact and slender concrete-filled steel tube (CFST) column tests collected from the literature. • A finite-element model is developed to accurately simulate the behavior of noncompact/slender CFSTs under axial compression. • Accuracy of existing stress-strain models is evaluated for the fiber-based analysis. • Recommendations for detailed finite-element modeling and efficient fiber-based analysis of noncompact and slender CFSTs. [ABSTRACT FROM AUTHOR]

Published

2022