Behavior and innovative design model on soil pressure at the top of large-diameter buried steel pipes

Existing design models of soil pressure at the top of buried steel pipes are limited to small-diameter pipes. This study aims to investigate the behavior and design model on the soil pressure for large-diameter pipes considering the pipe diameter, diameter-to-thickness ratio, and cover depth. The di...

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Bibliographic Details
Published in:Soils and foundations 2022-06, Vol.62 (3), p.101153, Article 101153
Main Authors: Yu, Jin-Hong, Wu, He-Gao, Shi, Chang-Zheng, Ma, Zhu, Xu, Wen-Tao
Format: Article
Language:English
Subjects:
Buried pipes
Design model
Finite element method
Large diameter
Soil pressure
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Summary:Existing design models of soil pressure at the top of buried steel pipes are limited to small-diameter pipes. This study aims to investigate the behavior and design model on the soil pressure for large-diameter pipes considering the pipe diameter, diameter-to-thickness ratio, and cover depth. The distribution and size of soil pressure are obtained from finite element models and compared with traditional design models. Sensitivity studies of soil parameters, trench parameters, and friction coefficients are discussed. Furthermore, an innovative design model of soil pressure for large-diameter pipes is proposed. The results indicate that the basic distribution pattern of soil pressure is the “inverted basin”/parabola for large/small-diameter pipes, respectively. Peak soil pressure typically appears in the pleura of pipes with great flexibility and deep cover depth. The modulus and Poisson's ratio of backfill and soil-soil friction coefficient have an influence range of within 10% for soil pressure, while trench parameters have a more significant influence. Prism load is too large at high cover depth, and Marston load is small at low cover depth. The proposed basin model for soil pressure adopts the form of “straight line + parabola” for distribution and “Marston + pleura” load for size, with high accuracy and strong adaptability.
ISSN:0038-0806
DOI:10.1016/j.sandf.2022.101153