|Table of Contents|

Research on Structural Performance and Design Indices of FRP Footbridges(PDF)

《建筑科学与工程学报》[ISSN:1673-2049/CN:61-1442/TU]

Issue:
2011年03期
Page:
14-22
Research Field:
Publishing date:
2011-09-20

Info

Title:
Research on Structural Performance and Design Indices of FRP Footbridges
Author(s):
FENG Peng JIN Fei-fei YE Lie-ping
Department of Civil Engineering, Tsinghua University, Beijing 100084, China
Keywords:
FRP footbridge comfort acceleration crouching excitation load maximum deflection structural performance
PACS:
U443.31
DOI:
-
Abstract:
A tentative FRP cable-stayed footbridge was investigated, in which the design method and design indices of FRP footbridges were studied. Firstly, the analysis of mechanical properties of the FRP footbridge made of large section industrialization pultruded profiles was carried out. It was found that FRP footbridge had the high loading capacity, while the deformation and the vibration comfort were the main controlling parameters for structural design. Furthermore, based on summarizing the deformation limits of the footbridge in domestic and international codes and considering the finite element analysis and the field measurement results, the deflection limit of 1/500 span length for FRP footbridge was proposed. The indices for the pedestrian vibration comfort requirements were also summarized, and the frequency limit, acceleration limit and excitation load were analyzed. Considering the finite element analysis and the field measurement results, it was concluded that the acceleration should be the controlling indicator, and simplified excitation load model and calculation method for acceleration were proposed. After reviewing the variety of damping ratio of real bridge in literature, the damping ratio of FRP footbridge was suggested to take as 0.008 for single component and 0.02 for multi-component structures. Based on the proposed design indices above, the limit span of continuous beam FRP footbridge and cable-stayed FRP footbridge were analyzed. For the cable-stayed FRP footbridge, the results of finite element analysis and field measurement showed that it could not meet the designing requirements. Hence, the improvement of overlaying a concrete layer was proposed. After it, the behaviors of the FRP footbridge met the requirements. All these works made out the design approach and the design indices for FRP footbridges, which were proved to be practical and reasonable through the actual FRP footbridge.

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Last Update: 2011-09-20