Seismic response of pile-supported embankment in unequal thickness liquefiable soil with V shape underlying stratum

Seismic response of pile-supported embankment in unequal thickness liquefiable soil with V shape underlying stratum

In this study, a series of shake table tests were conducted on saturated sand soil foundations to investigate the seismic response of pile-supported railway embankments under equal and unequal thickness heterogeneous liquefiable soil conditions. The model's failure process, the variations of ex...

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Bibliographic Details
Published in:Soil dynamics and earthquake engineering (1984) Vol. 182; p. 108757
Main Authors: Deng, Weiting, Wang, Chunyan, Ou, Qiang, Ding, Xuanming, Luan, Lubao, Xu, Yan, Feng, Huaiping
Format: Journal Article
Language:English
Published: Elsevier Ltd 01-07-2024
Subjects:
Composite foundation
Railway embankment
Shaking table test
Unequal thickness liquefiable soil
Shaking table test
Composite foundation
Unequal thickness liquefiable soil
Railway embankment
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Summary:In this study, a series of shake table tests were conducted on saturated sand soil foundations to investigate the seismic response of pile-supported railway embankments under equal and unequal thickness heterogeneous liquefiable soil conditions. The model's failure process, the variations of excess pore water pressure, the bending moments of the pile, and the acceleration response under different seismic intensities were analyzed in detail. Test results showed that the pore pressure increased with the increase of seismic intensity, and the liquefaction phenomenon occurred in the loose sand layer under 0.2 g dynamic excitation. The growth rate and peak value of excess pore water pressure in unequal thickness liquefiable soil terrain were greater than that in equal thickness soil conditions. The maximum bending moment of the pile body exhibits an inverted S-shaped distribution. In unequal thickness soil conditions, the edge piles experience higher bending moments compared to those in terrains with the same thickness. Additionally, the position of the maximum negative bending moment distribution for the central pile underwent a noticeable downward shift. During the loading process, the amplification effect of acceleration was greater in the loose sand layer than in the gravel soil layer, and more significant at the center of the foundation or the subgrade in unequal thickness liquefiable soil conditions. Therefore, the influence of terrain factors on the rise of pore pressure and the distribution of pile bending moments was nonnegligible in the seismic design of pile-supported embankment. •The seismic characteristics of pile-supported embankments in unequal thickness liquefiable soil were studied by model tests.•The failure process of the above system was revealed.•The characteristics of excess water generation, pile bending moment and acceleration response were obtained.•The seismic response of embankment under equal and unequal thickness liquefiable terrain conditions was compared.
ISSN:0267-7261
DOI:10.1016/j.soildyn.2024.108757