地震动强度及近断层速度脉冲峰值对简支板桥地震响应影响

The main reasons for earthquake damage of bridge structures are earthquake intensity and peak of near-fault velocity pulse. Compared with other bridge types, simply supported slab bridges are more likely to be damaged in the earthquakes. Gaoyuan bridge was a kind of simply supported hollow slab bridge of prestressed concrete, which was seriously destroyed in the Wenchuan earthquake in 2008. The effects of artificial boundary on the site on the accuracy of calculation results and calculation efficiency were studied carefully while the boundary was free boundary, fixed boundary, viscoelastic boundary and the artificial boundary of viscoelastic damping layer, respectively. The finite element model of Gaoyuan bridge included structure and site was established by ABAQUS, and boundary condition was the artificial boundary of viscoelastic damping layer. The effects of earthquake intensity and peak of near-fault velocity pulse on this bridge were researched. Peak acceleration of seismic wave represented earthquake intensity, and seismic wave with near-fault velocity pulse characteristic was synthesized. The results showed that when the artificial boundary of the model is the artificial boundary of viscoelastic damping layer, the reflection effect at the boundary could be effectively reduced and the accuracy of calculation results meets the basic requirements. Peak of near-fault velocity pulse is more sensitive to the seismic response of bridge than earthquake intensity. Peak accelerations of all points are improved on the site surface while earthquake intensity is raised. The earthquake damage of local structure is aggravated easily for closing to river bank and existing bedrock interface. The increase of earthquake intensity, peak of near-fault velocity pulse or peak of seismic wave displacement lead to enhance peak of span variation, relative slipping and slipping peak. Wave seismic with near-fault velocity pulse feature caused earthquake destruction in the bridge to be magnified.