Shaking table test and numerical simulation on seismic performance of prefabricated corrugated steel utility tunnels on liquefiable ground

The seismic failure mechanism of a shallow-buried prefabricated corrugated steel utility tunnel on the liquefiable ground was investigated by the shaking table test and numerical simulation. Firstly, A scaled model of prefabricated corrugated steel utility tunnel, inside pipelines, and three kinds o...

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Bibliographic Details
Published in:Soil dynamics and earthquake engineering (1984) 2021-02, Vol.141, p.106527, Article 106527
Main Authors: Yue, Feng, Liu, Bowen, Zhu, Bin, Jiang, Xiaoli, Chen, Le, Liao, Kai
Format: Article
Language:English
Subjects:
Brackets
Buried structures
Damping
Failure mechanisms
Ground motion
Liquefiable ground
Mathematical models
Numerical simulation
Numerical simulations
Pipelines and brackets
Prefabricated corrugated steel utility tunnel
Prefabrication
Seismic activity
Seismic response
Shake table tests
Shaking table test
Simulation
Soil testing
Soils
Steel
Tunnels
Underground structures
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Summary:The seismic failure mechanism of a shallow-buried prefabricated corrugated steel utility tunnel on the liquefiable ground was investigated by the shaking table test and numerical simulation. Firstly, A scaled model of prefabricated corrugated steel utility tunnel, inside pipelines, and three kinds of brackets were designed and fabricated. The model system was then excited by two seismic ground motions on a shaking table. Various dynamic responses of the model system were measured and the interface slip of tunnel and surrounding soil was also tested by a self-designed transducer. The experimental results demonstrated that the near-tunnel soil was more likely to liquefy than the far-field soil, and the liquefied soil had a remarkable damping effect. The bottom bracket was more vulnerable to be affected by excitations with high-frequency than the suspending and standing bracket. Both the utility tunnel and the suspending bracket yielded under the mainshock, but only slight deformations were observed with the model. Finally, the tunnel-ground system was simulated numerically using the FLAC 3D program. The comparison of experimental records with simulated results was carried out for validation of research outputs. The results provide valuable insight into the seismic performance of shallow-buried underground structures and the safe design of prefabricated corrugated steel utility tunnels. •Shaking table test on a prefabricated corrugated steel tunnel on liquefiable ground.•Seismic performance of the tunnel, inside pipelines and brackets is investigated.•Slip between the tunnel and surrounding ground is tested by a self-designed sensor.•Numerical simulations are performed by FLAC 3D for validation.
ISSN:0267-7261
1879-341X
DOI:10.1016/j.soildyn.2020.106527