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³¤°²´óѧѧ±¨£¨×ÔÈ»¿Æѧ°æ£©[ISSN:1006-6977/CN:61-1281/TN]

Issue:

2018Äê06ÆÚ

Page:

146-154

Research Field:

ÇÅÁºÓëËíµÀ¹¤³Ì

Publishing date:

Info

Title:

Analysis of failure patterns of doubleª²column bridgeª¤piers subjected to vessel collision

Author(s):

ZHANG Jingª²fengª¬1;  ZHAN Gangª²yiª¬2;  JING Yuanª¬1;  LI Xiaoª²zhenª¬3

(1. School of Highway, Chang¬ðan University, Xi¬ðan 710064, Shaanxi, China; 2. Nanchang Railway Survey andª¤Design Institute Co Ltd., Nanchang 330002, Jiangxi, China; 3. School of Civil Engineering,ª¤Southwest Jiaotong University, Chengdu 610031, Sichuan, China£©

Keywords:

bridge engineering;  vesselª²bridge collision;  doubleª²column bridge pier;  failure pattern;  reinforced concrete (RC);  numerical simulation

PACS:

-

DOI:

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Abstract:

To investigate the damage and failure mechanisms of bridge doubleª²column piers subjected to vessel collision, the material constitutive models of the reinforced concrete (RC) structure and the modeling approach of bond effects were discussed. The concrete material in RC piers was simulated with a concrete continuousª²smoothª²capª²model (CSCM), and the longitudinal reinforcement and stirrup were modeled with a kinematic hardening plastic model, including the strainª²rate effect. The explicit dynamic finite element software LSª²DYNA was employed to conduct the numerical simulation of barge doubleª²column pier collision, considering the influences of longitudinal reinforcement ratio and soilª²pile interaction. The results show that the failure process of the doubleª²column could be classified into 4 stages£¬ initial contact and collision, collided column failure, nonª²collided column failure, and joint between tie beam and column failure stage£¬under the vessel impact loading . The contacted area of the pier suffered the first local damage. Then, both the collided and nonª²collided pier columns, as well as the tie beam joints is damaged by a ruptureª²failure pattern. The barge bow endured the loadingª²unloading process twice. Around 76% of the vessel kinetic energy is transformed into the internal energy of the barge bow and structure during the collision process. The ratio of longitudinal reinforcement affects the failure patterns of the bridge pier significantly. The damage pattern of the bridge pier transferred from the flexural failure to a few transverse cracks as the reinforcement ratio increases. No flexural failure occurred as the reinforcement ratio is reach to 2%, whereas the joint between the contacted column and tie beam suffered severe rupture failure under various reinforcement ratios. The soilª²pile interaction has a significant influence on the failure pattern of bridge pier, which should be considered in the structural design. Shear failure occurs as the pier bottom is fixed rigidly. 2 tabs, 11 figs, 25 refs.

References:

Memo

Memo:

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Common functions

Last Update: 2018-12-18