Model Test Study on Dynamic Response of Expressway Plastic-Reinforced Earth Embankment under Earthquake

A three-dimensional finite element analysis was carried out for the influence of soil-structure interaction (SSI) on the seismic response of an isolated continuous bridge with a friction pendulum system (FPS). SSI was modelled using the soil resistance vs deflection nonlinear springs (following p-y curves). The influence of SSI on the dynamic behaviour and the seismic response of isolated bridges with different friction coefficients of FPS were investigated using six measured ground motions. Results show that the effect of SSI is limited on the isolation period of the bridge, but significant on the response amplitude of the bridge structures, and particularly on the response amplitude at the pier top and bottom. The displacement and acceleration at the pier top are underestimated, while the shear force and bending moment at the pier bottom are overestimated if the SSI effects are ignored, which suggests that SSI should be considered in the seismic analyses of continuous bridges.

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Enhancing the seismic performance of highway embankments on soft soils: a comparative study of conventional and T-shaped deep cement mixing columns

Aissaoui,

Boufarh,

Djellali

et al. 2024

SEES

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Weak soils globally pose significant challenges in highway construction under seismic conditions, causing instability issues such as settlements and slope failures. This poses challenges for geotechnical engineers to design safe, effective, and economical construction methods for stable slopes. Despite the critical nature of embankment stability under dynamic conditions, there is a lack of research investigating the effects of foundation soil reinforcement in such scenarios. This paper aims to study the seismic behavior of two soil improvement techniques: conventional Deep Cement Mixing (DCM) columns and T-shaped Deep Cement Mixing (TDM) columns. A three-dimensional numerical model was used to investigate the dynamic behavior of DCM and TDM column-supported embankments using PLAXIS 3D software. After validating the numerical model, a parametric study was conducted to understand the seismic performance of embankments with DCM and TDM columns over soft soil. The obtained results demonstrate that, under seismic loading conditions, both DCM and TDM columns substantially enhance embankment stability. However, TDM columns exhibit superior performance, consistently achieving greater efficacy in mitigating settlement and controlling displacement compared to their DCM counterparts.

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Model Test Study on Dynamic Response of Expressway Plastic-Reinforced Earth Embankment under Earthquake

Cited by 3 publications

References 15 publications

Seismic behaviour of granular slope under railway embankment in large-scale shaking table test

Seismic behaviour of granular slope under railway embankment in large-scale shaking table test

Influence of Soil-Structure Interaction on the Seismic Response of a Continuous Bridge with Friction Pendulum System

Enhancing the seismic performance of highway embankments on soft soils: a comparative study of conventional and T-shaped deep cement mixing columns

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