Damage Detection for Simply Supported Bridge with Bending Fuzzy Stiffness Consideration 被引量：9

Damage Detection for Simply Supported Bridge with Bending Fuzzy Stiffness Consideration

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摘要 The benchmark of a simply supported beam with damage and bending fuzzy stiffness consideration is established to be utilized for damage detection. The explicit expression describing the Rotational Angle Influence Lines(RAIL) of the arbitrary section in the benchmark is presented as the nonlinear relation between the moving load and the RAIL appeared, when the moving load is located on the damage area. The damage detection method is derived based on the Difference of the RAIL Curvature(DRAIL-C) prior to and following arbitrarily section damage in a simply supported beam with bending fuzzy stiffness consideration. The results demonstrate that the damage position can be located by the DRAIL-C graph and the damage extent can be calculated by the DRAIL-C curve peak. The simply supported box girder as a one-dimensional model and the simply supported truss bridge as a three-dimensional model with the bending fuzzy stiffness are simulated for the validity of the proposed method to be verified. The measuring point position and noise intensity effects are discussed in the simply supported box girder example. This paper provides a new consideration and technique for the damage detection of a simply supported bridge with bending fuzzy stiffness consideration. The benchmark of a simply supported beam with damage and bending fuzzy stiffness consideration is established to be utilized for damage detection. The explicit expression describing the Rotational Angle Influence Lines（RAIL） of the arbitrary section in the benchmark is presented as the nonlinear relation between the moving load and the RAIL appeared, when the moving load is located on the damage area. The damage detection method is derived based on the Difference of the RAIL Curvature（DRAIL-C） prior to and following arbitrarily section damage in a simply supported beam with bending fuzzy stiffness consideration. The results demonstrate that the damage position can be located by the DRAIL-C graph and the damage extent can be calculated by the DRAIL-C curve peak. The simply supported box girder as a one-dimensional model and the simply supported truss bridge as a three-dimensional model with the bending fuzzy stiffness are simulated for the validity of the proposed method to be verified. The measuring point position and noise intensity effects are discussed in the simply supported box girder example. This paper provides a new consideration and technique for the damage detection of a simply supported bridge with bending fuzzy stiffness consideration.

作者周宇狄生奎项长生王立宪 ZHOU Yu a;b;DI Shengkui a;XIANG Changsheng a(a. School of Civil Engineerin;b. Northwest Center for Disaster Mitigation in Civil Engineering, Ministry of Education Lanzhou University of Technology, Lanzhou 730050, Chin)

机构地区 School of Civil Engineering Northwest Center for Disaster Mitigation in Civil Engineering

出处《Journal of Shanghai Jiaotong university(Science)》 EI 2018年第2期308-319,共12页 上海交通大学学报（英文版）

基金 the National Natural Science Foundation of China(Nos.51608245 and 51568041) the Natural Science Foundation of Gansu Province(No.148RJZA026)

关键词 rotational angle influence lines method simply supported bridge bending fuzzy stiffness damage detection rotational angle, influence lines method, simply supported bridge, bending fuzzy stiffness, damage detection

分类号 U446 [建筑科学—桥梁与隧道工程]

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Journal of Shanghai Jiaotong university(Science)

2018年第2期

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