Mechanical performance analysis of steel-concrete joint section of a long-span hybrid girder cablestayed bridge based on field test(PDF)
长安大学学报(自然科学版)[ISSN:1006-6977/CN:61-1281/TN]
- Issue:
- 2021年5期
- Page:
- 54-65
- Research Field:
- 桥梁与隧道工程
- Publishing date:
Info
- Title:
- Mechanical performance analysis of steel-concrete joint section of a long-span hybrid girder cablestayed bridge based on field test
- Author(s):
- WEI Feng1; LUO Huiwen1; LIANG Linong2; XIAO Yongbo1; SU Cheng1
- (1. School of Civil Engineering and Transportation, South China University of Technology,Guangzhou 510641, Guangdong, China; 2. Guangdong Communication Planning &Design Institute Co., Ltd, Guangzhou 510507, Guangdong, China)
- Keywords:
- bridge engineering; mechanical performance; strain test of real bridge; steelconcrete joint section; stress distribution
- PACS:
- -
- DOI:
- -
- Abstract:
- In order to study the mechanical performance of the back bearing plate (without steel grids) steelconcrete joint section of the longspan cablestayed bridge and to verify the reliability of its longitudinal stress transmission, stress distributions of the steelconcrete joint section of the girder and adjacent girder sections during construction and operation stages were studied, with field strain test and numerical analysis on a longspan hybridgirder cablestayed bridge (Jiangshun Bridge). First, the strains of steel plate and concrete of test sections were monitored over time. Based on the monitored strain values, the stresses and distribution laws of the steelconcrete joint section, the adjacent strengthened steel box girder section and the adjacent prestressed concrete (PC) box girder section were obtained. Then the local 3dimension finite element model of the test segment was established in ANSYS software and the related numerical analysis was conducted. Finally, the finite element analysis results were compared with the field test data. The results show that the compressive stress levels of the steelconcrete joint section and its adjacent girder sections are relatively low during the entire test period. The maximum stress of steel plate is -159.4 MPa and the maximum concrete stress is -15.8 MPa. The structure of test sections is stressed with good performance. The stresses not only be effectively controlled in the construction stage but also satisfy the original design requirements during the operation stage. The largest compressive stress is observed on the upper Trib of the upper part of the reinforced steel box girder section, and there are higher compressive stresses on the lower Urib in the lower part than those on the bottom plate and the lower Trib. The longitudinal stress can be effectively transmitted on the Trib and Urib of the reinforced steel box girder section. So that the stiffness transition is smooth, and the coordinated load bearing capacity is favorable in the steelconcrete joint section and adjacent sections of the girder. The finite element calculation results of steel plate stress and concrete stress, and the stress distribution laws are basically consistent with the actual field test results, which indicates that the finite element modeling and boundary conditions of the steelconcrete joint section are reasonable, and the numerical simulation on the stress state of the steelconcrete joint section and the adjacent sections are relatively accurate. 5 tabs, 13 figs, 29 refs.
Last Update: 2021-09-30