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Three-dimensional numerical analyses of pile responses to tunneling-induced ground movements in bilayer soil

Mohamed Nabil Houhou (MN2I2S Lab, Department of Civil Engineering and Hydraulic, Mohamed Khider University of Biskra, Biskra, Algeria)
Tamir Amari (MN2I2S Lab, Department of Civil Engineering and Hydraulic, Mohamed Khider University of Biskra, Biskra, Algeria)
Abderahim Belounar (Department of Civil Engineering, Tipaza University Center, Tipaza, Algeria)

World Journal of Engineering

ISSN: 1708-5284

Article publication date: 13 September 2022

Issue publication date: 12 January 2024

157

Abstract

Purpose

This paper aims to investigate the responses of single piles and pile groups due to tunneling-induced ground movements in a two-layered soil system. The analyses mainly focus on the additional single pile responses in terms of bending moment, lateral deflection, axial force, shaft resistance and pile settlement. Subsequently, a series of parametric studies were carried out to better understand the responses of single piles induced by tunneling. To give further understanding regarding the pile groups, a 2 × 2 pile group with two different pile head conditions, namely, free and capped, was considered.

Design/methodology/approach

Using the PLAXIS three-dimensional (3D) software, a full 3D numerical modeling is performed to investigate the effects of ground movements caused by tunneling on adjacent pile foundations. The numerical model was validated using centrifuge test data found in the literature. The relevance of the 3D model is also judged by comparison with the 2D plane strain model using the PLAXIS 2D code.

Findings

The numerical test results reveal that tunneling induces significant displacements and internal forces in nearby piles. The magnitude and distribution of internal forces depend mainly on the position of the pile toe relative to the tunnel depth and the distance between the pile and the vertical axis of the tunnel. As the volume loss increases from 1% to 3%, the apparent loss of pile capacity increases from 11% to 20%. By increasing the pile length from 0.5 to 1.5 times, the tunnel depth, the maximum pile settlement and lateral deflection decrease by about 63% and 18%, respectively. On the other hand, the maximum bending moment and axial load increase by about 7 and 13 times, respectively. When the pile is located at a distance of 2.5 times the tunnel diameter (Dt), the additional pile responses become insignificant. It was found that an increase in tunnel depth from 1.5Dt to 2.5Dt (with a pile length of 3Dt) increases the maximum lateral deflection by about 420%. Regarding the interaction between tunneling and group of piles, a positive group effect was observed with a significant reduction of the internal forces in rear piles. The maximum bending moment of the front piles was found to be higher than that of the rear piles by about 47%.

Originality/value

Soil is a complex material that shows differently in primary loading, unloading and reloading with stress-dependent stiffness. This general behavior was not possibly being accounted for in simple elastic perfectly plastic Mohr–Coulomb model which is often used to predict the behavior of soils. Thus, in the present study, the more advanced hardening soil model with small-strain stiffness (HSsmall) is used to model the non-linear stress–strain soil behavior. Moreover, unlike previous studies THAT are usually based on the assumption that the soil is homogeneous and using numerical methods by decoupled loadings under plane strain conditions; in this study, the pile responses have been exhaustively investigated in a two-layered soil system using a fully coupled 3D numerical analysis that takes into account the real interactions between tunneling and pile foundations. The paper presents a distinctive set of findings and insights that provide valuable guidance for the design and construction of shield tunnels passing through pile foundations.

Keywords

Acknowledgements

The authors express their gratitude to the Directorate General for Scientific Research and Technological Development of Algeria.

Citation

Houhou, M.N., Amari, T. and Belounar, A. (2024), "Three-dimensional numerical analyses of pile responses to tunneling-induced ground movements in bilayer soil", World Journal of Engineering, Vol. 21 No. 1, pp. 71-90. https://doi.org/10.1108/WJE-04-2022-0159

Publisher

:

Emerald Publishing Limited

Copyright © 2022, Emerald Publishing Limited

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