Abstract
Large-scale model tests were established at a scale of 1/5 using a 7 m deep model tank with cross-sectional dimension of 5 m × 4 m, to study the vibration response characteristics of ballastless track, embankment, and X-section piled raft foundation under cyclic axial load, including the vibration displacement, velocity, dynamic soil, and pile stress. Cyclic dynamic loading can be achieved by controlling the loading frequency and cycles through the vibration servo control loading system. The test results are presented in the variation of dynamic displacement, velocity, and stress of X-section piled raft composite foundation. The vibration displacement, velocity, and stress of the track, embankment, and pile foundation follow a pattern of vibration characteristics of loading sine wave. The vibration characteristics of loading waves can be identified easily from the peaks and troughs in the dynamic response of displacement, velocity, and stress at many locations of track slab, embankment, cushion, and underlying soil, at which the vibration response presents almost monotonically increasing tendency with the loading frequencies. With the increase of loading frequency, the vibration responses at the track structure and embankment have higher increasing rates than those at substructure (raft, cushion, and subsoil). The piled raft bears more dynamic load than cushion and subsoils, to ensure long-term dynamic stability and safety of the foundation soils. The model testing results provide a better understanding of the dynamic response characteristics of ballastless track, embankment, and X-section piled raft foundation under cyclic axial load in soft soil.
Highlights
In recent years, with the rapid development of high-speed railway, the studies on the dynamic response of ground and environmental vibration induced by moving trains have attracted many attentions
Pile Stress Response Analysis. e time histories and frequency analysis of dynamic stress at the pile top and bottom for f 20 Hz are shown in Figure 18. e dynamic loads are induced by vibration exciter, which transfer stresses from track slab to roadbed, embankment, raft, cushion, piles, and subsoils. e dynamic response of stress caused by the load transferred to the pile top exhibits the shape and frequency characteristic of the loading sine wave
Compared with the dynamic stress at the pile top, cushion, subsoils, and pile bottom in Figures 14(a) and 18, for the loading frequency of 20 Hz, the maximum dynamic soil stresses at S1, E3, E6, and S3 are 4.3 kPa, 1.23 kPa, 0.41 kPa, and 0.63 kPa. e load sharing ratio between pile and gravel cushion is 3.5, which is similar to the load sharing and transfer mechanism under static load for X-section piled raft foundation. e pile bears more load than cushion and subsoils
Summary
With the rapid development of high-speed railway, the studies on the dynamic response of ground and environmental vibration induced by moving trains have attracted many attentions. In spite of the increasing use of piled foundations as a rapid construction technique for highway and railway lines, most studies focused on investigating the bearing capacity and behavior of foundations without improvement under dynamic loads. Foundation improvement by using X-section cast-in-place concrete (XCC) piles has been developed and applied in highway construction [32,33,34], which has been applied to improve the soft soil foundation of the Jing-Hu railway in Nanjing of China. Very limited attentions were considered to investigate the dynamic behavior of track, embankment, and X-section piled raft foundation in soft soil under dynamic loads. Is paper presents a physical model of ballastless railway track, embankment, and X-section piled raft foundation in soft soils. Is paper presents a physical model of ballastless railway track, embankment, and X-section piled raft foundation in soft soils. e short-term dynamic response of each position of the system is tested and recorded to study the vibration response characteristics and laws of the X-section piled raft composite foundation under cyclic axial load, including the vibration response, transmission and attenuation of vibration displacement, velocity, dynamic soil, and pile stress
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