FINITE ELEMENT SIMULATION ANALYSIS OF CURVILINEAR CONTINUOUS BEAM BRIDGE JACKING AND TRANSLATION CONSTRUCTION

Authors

  • Xilong Zheng Harbin University
  • Jinshuo Yan
  • Peng Li
  • Wei Li
  • Qiong Wang

DOI:

https://doi.org/10.14311/CEJ.2024.02.0018

Keywords:

Continuous beam bridge, Jacking simulation, Translation simulation, Misalignment, Simulation analysis

Abstract

This paper investigates the issue of beam misalignment in curved continuous beam bridges. Taking the D0 to D6 spans of the Gongbin Road viaduct as the basis, the main influencing factors causing misalignment in curved beam bridges are analyzed and the causes of transverse and longitudinal misalignment in curved beam bridges are calculated and analyzed using Midas/Civil finite element simulation software. The results indicate that the main influencing factor causing misalignment in the operation of curved continuous beam bridges is the system temperature, with the displacement caused by it being larger than the cumulative displacement caused by self-weight, construction phase, gradient load, vehicle load, and bearing settlement. During operation, the failure of expansion joints changes the boundary conditions of the beam, preventing the bridge from freely expanding and contracting longitudinally under temperature load. As a result, the transverse displacement increases to 2-3 times the normal working state of the expansion joint, leading to beam misalignment.

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References

Zhai, Zhihao, Chengbiao Cai, and Shengyang Zhu. Implementation of Timoshenko curved beam into train-track-bridge dynamics modelling[J]. International Journal of Mechanical Sciences, 2023, 247: 108158.

Linzell, D. G., and J. F. Shura. Erection behavior and grillage model accuracy for a large radius curved bridge[J]. Journal of Constructional Steel Research, 2010, 66(3): 342-350.

Li, Ming, and Jingqiao Hu. Analysis of heterogeneous structures of non-separated scales using curved bridge nodes[J]. Computer Methods in Applied Mechanics and Engineering, 2022, 392: 114582.

Tondini, Nicola, and Bozidar Stojadinovic. Probabilistic seismic demand model for curved reinforced concrete bridges[J]. Bulletin of earthquake engineering, 2012, 10: 1455-1479.

Dimitrakopoulos, Elias G., and Qing Zeng. three-dimensional dynamic analysis scheme for the interaction between trains and curved railway bridges[J]. Computers & Structures, 2015, 149: 43-60.

Wang, Jianwei, et al. Application of High-Viscosity Modified Asphalt Mixture in Curved Bridge Pavement[J]. Sustainability, 2023, 15(4): 3411.

Seo, Junwon, and Daniel G. Linzell. Use of response surface metamodels to generate system level fragilities for existing curved steel bridges[J]. Engineering Structures, 2013, 52: 642-653.

Kim, Woo Seok, Jeffrey A. Laman, and Daniel G. Linzell. Live load radial moment distribution for horizontally curved bridges[J]. Journal of Bridge Engineering, 2007, 12(6): 727-736.

Zeng, Qing, Y. B. Yang, and Elias G. Dimitrakopoulos. Dynamic response of high speed vehicles and sustaining curved bridges under conditions of resonance[J]. Engineering Structures, 2016, 114: 61-74.

Monzon, Eric V., Ian G. Buckle, and Ahmad M. Itani. Seismic performance and response of seismically isolated curved steel I-girder bridge[J]. Journal of Structural Engineering, 2016, 142 (12): 04016121.

DeSantiago, Eduardo, Jamshid Mohammadi, and Hamadallah MO Albaijat. Analysis of horizontally curved bridges using simple finite-element models[J]. Practice Periodical on Structural Design and Construction, 2005, 10(1): 18-21.

Ni, Yongjun, et al. Influence of earthquake input angle on seismic response of curved girder bridge[J]. Journal of traffic and transportation engineering (English edition), 2015, 2(4): 233-241.

Wen, Q., et al. Control of human-induced vibrations of a curved cable-stayed bridge: Design, implementation, and field validation[J]. Journal of Bridge Engineering, 2016, 21(7): 04016028.

Nevling, D., Daniel Linzell, and J. Laman. Examination of level of analysis accuracy for curved I-girder bridges through comparisons to field data[J]. Journal of Bridge Engineering, 2016, 11(2): 160-168.

Zhang, Lixin, and Yin Gu. Seismic analysis of a curved bridge considering soil-structure interactions based on a separated foundation model[J]. Applied Sciences, 2020,10(12) :4260.

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Published

2024-07-30

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Section

Articles

How to Cite

FINITE ELEMENT SIMULATION ANALYSIS OF CURVILINEAR CONTINUOUS BEAM BRIDGE JACKING AND TRANSLATION CONSTRUCTION. (2024). Stavební Obzor - Civil Engineering Journal, 33(2), 261-274. https://doi.org/10.14311/CEJ.2024.02.0018