Linear Control Method for Arch Ring of Oblique‐Stayed Buckle Cantilever Pouring Reinforced Concrete Arch Bridge

Liu, Zengwu; Zhou, Jianting; Wu, Yuexing; You, Xing; Qu, Yinghao

doi:10.1155/2021/6633717

Advances in Civil Engineering

2021

DOI: 10.1155/2021/6633717

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Linear Control Method for Arch Ring of Oblique‐Stayed Buckle Cantilever Pouring Reinforced Concrete Arch Bridge

Zengwu Liu

Jianting Zhou

Yuexing Wu

et al.

Abstract: Yelang Lake Bridge is the largest cantilevered single-chamber reinforced concrete arch bridge in China, with a net span of 210 m. In this article, an equation for positioning the height of the formwork before pouring of the arch ring segment was derived, which was suitable for the construction control of the long-span reinforced concrete arch bridge such as the Yelang Lake Bridge. The arch ring segment elevation calculation equation was derived under the two typical working conditions that the concrete pouring… Show more

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Cited by 2 publications

References 24 publications

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Coupling Dual Nonlinearity of Arch Bridge Bearing Capacity Analysis Method

Zhou,

Wang,

Liu

et al. 2023

Int. J. Str. Stab. Dyn.

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In order to realistically restore the mechanical properties of the arch bridge under load and damage processes, a coupled dual nonlinear analysis method is established for the arch-bridge load–carrying capacity by considering the effects of bidirectional force transfer and adaptive section stiffness. First, based on the geometric nonlinear theoretical method of bidirectional force transfer, the macroscopic structural deformation of arch ribs under different loading conditions and load levels is preliminarily calculated, including the bending and axial deformation of each section of the arch, which is used to characterize the development of plasticity. According to deformation or strain, the fiber model analysis method is used to determine the true moment–curvature and axial force–curvature development paths of key sections, and then the elastic–plastic flexural and compressive stiffnesses of each section under different deformation states are derived. The elastic–plastic stiffness is substituted back to the geometric nonlinear equations to obtain the deformation and internal force along the arch ribs considering the cross-sectional plasticity. Finally, the above process is cycled until the equivalence condition is satisfied between the structural internal force/deformation and cross-sectional ones. In order to verify the rationality and accuracy of such a coupling method, a model test is carried out on a stiff skeletal concrete suspension chain line arch with a span of 12[Formula: see text]m, whose results match satisfactorily with that of calculated by the coupling dual nonlinearity method. Compared with the method suggested in the code JTG3362-2018, the proposed method can better predict the development of deflection of different arch rib sections, as well as the actual internal force state. The bending moment calculated as per the code is 7–16% larger than the test result at the ultimate capacity state, while the method of this paper is within 5%.

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Coupling Dual Nonlinearity of Arch Bridge Bearing Capacity Analysis Method

Zhou,

Wang,

Liu

et al. 2023

Int. J. Str. Stab. Dyn.

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Proposed New Analytical Method of Tower Load in Large-Span Arch Bridge Cable Lifting Construction

Huang

Zhang

et al. 2022

Applied Sciences

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The cable lifting construction method is the most widely used construction method for large-span arch bridges. The correct calculation and analysis of cable lifting construction is essential to ensure the safety and linearity in the construction of arch bridges. The existing research mainly focuses on the construction scheme and finite element analysis of cable lifting for large-span arch bridges. There is relatively little research on calculation theory, and there is no analytical method for cable lifting construction of arch bridges. To calculate and analyze cable lifting construction more quickly and accurately, based on the deformation coordination principle and suspension cable theory, a practical calculation method is proposed to calculate the load of the tower acting by a cable system in the cable lifting construction of arch bridges. A large-span arch bridge under construction was used as a case study, and the correctness of the calculation method was verified by measuring the displacements of the tower top. A brief description of the structure, verification method, and verification process is presented. The displacement results are calculated by the numerical calculation software SAP2000, the actual measured displacement data are discussed and comparatively analyzed, and the correctness and calculation accuracy of the proposed calculation method are also evaluated. The results show that the calculation method has sufficient accuracy. The tower load calculation is mainly undertaken to prepare for the analysis of the tower mechanical properties; therefore, the calculation method is applied to towers of the case engineering, and the stability, load carrying capacity, and deformation of the tower are analyzed to verify whether its mechanical properties meet the engineering requirements. The results show that steel pipe columns of the buckle tower are prone to twisting instability. The normal stress of the tower’s part of the pressurized rod or pressurized bending rod is larger. Wind cable load calculation models and tower design-related recommendations are presented in this tower analysis. The tower load calculation method and tower mechanics analysis method in this study can provide guidance for the calculation and analysis of the cable lifting construction of large-span arch bridges.

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Linear Control Method for Arch Ring of Oblique‐Stayed Buckle Cantilever Pouring Reinforced Concrete Arch Bridge

Cited by 2 publications

References 24 publications

Coupling Dual Nonlinearity of Arch Bridge Bearing Capacity Analysis Method

Coupling Dual Nonlinearity of Arch Bridge Bearing Capacity Analysis Method

Proposed New Analytical Method of Tower Load in Large-Span Arch Bridge Cable Lifting Construction

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