Investigation of Interface Behavior Between Offshore Pipe Pile and Sand Using a Newly Modified Shearing Apparatus

Investigation of Interface Behavior Between Offshore Pipe Pile and Sand Using a Newly Modified Shearing Apparatus

With the rapid development of marine engineering, large−diameter steel pipe piles are increasingly used in infrastructure construction, such as bridges, docks, and offshore wind power projects. Therefore, studying the shear behavior of the sand–steel interface is of great importance. In this study,...

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Bibliographic Details
Main Authors: Wenbo Du, Xuguang Chen, Shanshan Zhang, Bin Huang
Format: Article
Language:English
Published: MDPI AG 2025-04-01
Series:Buildings
Subjects:
modified shearing apparatus
sand–steel interface
shear rate
relative density
steel surface roughness
Online Access:https://www.mdpi.com/2075-5309/15/8/1308
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Summary:With the rapid development of marine engineering, large−diameter steel pipe piles are increasingly used in infrastructure construction, such as bridges, docks, and offshore wind power projects. Therefore, studying the shear behavior of the sand–steel interface is of great importance. In this study, the traditional vane shear apparatus was improved by utilizing its torsional shear actuator, adding an overlying pressure fixing device, and applying lateral pressure through a compressive spring. The original cross plate was replaced with a cylindrical steel rod to simulate the shear behavior of the large−diameter pile–sand interface under different stress states. Experimental results show that this apparatus effectively solves the problem of soil loss due to the shear gap in both the ring shear and direct shear tests under smooth interface conditions. As the shear rate (2°/min, 4°/min, 6°/min) increased, the peak and residual shear stresses decreased, while the shear stress increased with vertical confinement pressure, accompanied by significant residual stress. As the relative density of sand increased from 27.4% to 72.2%, the shear behavior transitioned from contraction to dilation. Regarding surface roughness, the experiment identified a critical threshold: when roughness is below this threshold, it significantly affects the peak shear strength; when above this threshold, the effect is smaller, and failure shifts to the internal sand body. This study provides valuable insights into the mechanics of the sand–steel interface and contributes to optimizing the foundation design for marine infrastructure.
ISSN:2075-5309

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