Abstract
U-shaped girder has been extensively used for its excellent adaptability in the urban railway transit system. As an open thin-walled structure, significant difference of working mechanism exists between U-shaped girder and conventional section girder (e.g., T section or box section). The thin-walled web plays significant role in the flexural performance of U type girder particularly. Moreover, severe collision may occur between the moving train and the girder, and subsequently results in the decrease of the structural bearing capacity. In this paper, a full-scale test was carried out to examine the ultimate bearing capacity and the failure mechanism of the U-shaped girder, and a refined numerical model was developed to simulate the damage evolution and the failure process. It was shown that the flexural failure occurred on the U-shaped girder under vertical loads. In addition, the ultimate bearing capacity of the structure under different web damage conditions (e.g., web damaged region or damaged range) was studied by applying the displacement based lateral load on the flange of the U-shaped girder to simulate the damage caused by accidental train collision. The numerical results have shown that the damaged web greatly affects the ultimate bearing capacity of U-shaped girder, more severe bearing capacity descending occurs around the middle span rather than the beam ends. The damaged range (length) of the web has less influence on the falling amplitude of bearing capacity. It can be concluded that the major reason accounting for the bearing capacity decrease is that the original section is weakened by the web damage, and consequently results in the buckling of the damaged web and lead to the total failure of the structure. It is recommended that the lateral resistant design for the web should be taken into consideration to ensure the operation safety of the urban railway transportation.
Highlights
U-shaped girder is a common type of -supported bridge structure, which is widely used in the modern urban railway transit
A great number of study achievements have been obtained on the working mechanism and design theory of reinforced concrete (RC) or prestressed concrete (PC) girder under static and cyclic loading with conventional cross sections, such as box shape or T shape [3,4,5]
The examined U-shaped girder was in the state of linear elastic deformation and no visible crack as follows: appeared until the vertical loadsgirder exceeded the design load
Summary
U-shaped girder is a common type of -supported bridge structure, which is widely used in the modern urban railway transit. Compared with traditional bridge types in urban viaduct rail transit, U-shaped girder exhibits several significant advantages, i.e., more elegant appearance, higher utilization ratio of cross-section, lower structural height and elevation of rail running surface. U-shaped girder can isolate the wheel-rail induced noise and prevent the derailed. Sensors 2019, 19, 3735 train vehicles from falling down by its web. These merits make U-shaped girder more competitive in the urban railway transit [1,2]. Further research and engineering application of the U-shaped girder are still intensively needed. Cusens and Rounds [6]
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