The Key Technologies Research in Demolition Construction of Liuxi River Bridge

Hai Qiang Wen; Zhi Lin Zhang; Wen Jin Luo; Bu Yu Jia; Zhen Zu He; De Yi Chen

doi:10.4028/www.scientific.net/AMR.919-921.607

Paper Titles

Research on the Wave Load Effect Based on Time History Analysis of Donghai Island Bridge
p.587

Risk Prevention Measures for Three-Tower and Four-Span Suspension Bridge under Vehicle Fire
p.590

Structure Calculation of Die Carrier and Determination of Pre-Camber of Main Girder of Cable Stayed Bridge
p.598

Study on Nonlinear Structural Behaviors of Steel and Concrete Composite Slab
p.602

The Key Technologies Research in Demolition Construction of Liuxi River Bridge
p.607

The Local Stress Analysis of Slide Beam Taking into Account the Roughness of Girder Undersurface
p.615

Bridge Pavla Wonky in Pardubice. Diagnostics of Corrosion Condition of External Cables and Use of Special Materials for Proposal of Treatment
p.619

A Constitutive Model with Effect of Temperature for Frozen Soil
p.627

A Statistical Damage Constitutive Model for Brittle Rocks Based on the Lade-Duncan Failure Criterion
p.632

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The Key Technologies Research in Demolition Construction of Liuxi River Bridge

Abstract:

Because the flow of river bridge was not suitable for bearing existing vehicle load, it is needed to be dismantled, and a new bridge will build on the original site. The overall construction plan is using double bridge girder erection machines to remove box girder and the suspended beam of the main bridge. In order to guarantee the security of assembling the bridge girder erection machines and lifting the beam, we did some research in assembling technology, using the finite element software MIDAS to establish model of sling equipment, and analyses whether the sling equipment can bear the design load . With the purpose of ensuring the stability and safety of the suspended beam in the process of hoisting, the suitable order of hoisting suspended beam and risk control of slipping the suspended beam were analyzed. For purpose of guaranteeing the stability of the hoisting box girder, the construction team designed the stabilization system. Due to the complexity of the stress of the girder in the demolition process, we use the finite element software ANSYS to establish the model of e box girder in the process of hoisting, and analyze its stress and deformation. According to the practical engineering, we draw a conclusion: the box girder, suspended beam remained stable in the process of hoisting, and their internal forces conform to the requirements of the specification. The overall construction plan can provide a reference for other similar projects.