A refined nonlinear analytical method for buried pipelines crossing strike‐slip faults

Talebi, Farzad; Kiyono, Junji

doi:10.1002/eqe.3479

Cited by 18 publications

(3 citation statements)

References 42 publications

(119 reference statements)

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“…As mentioned in Section 1, Talebi and Kiyono [36,37] have extended the linear and nonlinear analytical methods for the stability analysis of buried pipelines at strike-slip faults with high accuracy results. Since, in this paper, the analytical method was just used for the parametric interpretation of the FE analyses results instead of the complex analytical approaches in the papers by [36,37], a simple linear analytical method mentioned by Talebi and Kiyono [42] was employed. A simplified differential equilibrium equation for the pipeline crossing the strikeslip is expressed in Equation (1).…”

Section: Analytical Evaluation Of Buried Pipeline Behaviormentioning

confidence: 99%

“…In 2012, an analytical model based on the stability model of Trifonov and Cherniy [33], including the operational loads (internal pressure and temperature gradient), was developed for the stress-strain analysis of buried pipelines at a fault crossing by Trifonov and Cherniy [35]; however, their study had the same shortcomings as their previous governing differential equation [33]. In 2020 and 2021, Talebi and Kiyono [36,37] introduced a novel nonlinear governing equation that includes the longitudinal sliding behavior of a pipe within soil during large PGDs, lateral elastoplastic soil-pipe interaction springs, and longitudinal forces made by geometrical nonlinearity effects. They removed the unrealistic assumptions and remarkably increased the accuracy and application area of the analytical methods for the problem of buried pipelines at active strike-slip fault crossings.…”

Section: Introductionmentioning

confidence: 99%

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Comparison of 3D Solid and Beam–Spring FE Modeling Approaches in the Evaluation of Buried Pipeline Behavior at a Strike-Slip Fault Crossing

Talebi

Kiyono

2021

Energies

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Validated 3D solid finite element (FE) models offer an accurate performance of buried pipelines at earthquake faults. However, it is common to use a beam–spring model for the design of buried pipelines, and all the design guidelines are fitted to this modeling approach. Therefore, this study has focused on (1) the improvement of modeling techniques in the beam–spring FE modeling approach for the reproduction of the realistic performance of buried pipelines, and (2) the determination of an appropriate damage criterion for buried pipelines in beam–spring FE models. For this paper, after the verification of FE models by pull-out and lateral sliding tests, buried pipeline performance was evaluated at a strike-slip fault crossing using nonlinear beam–spring FE models and nonlinear 3D solid FE models. Material nonlinearity, contact nonlinearity, and geometrical nonlinearity effects were considered in all analyses. Based on the results, pressure and shear forces caused by fault movement and pipeline deformation around the high curvature zone cause local confinement of the soil, and soil stiffness around the high curvature zone locally increases. This increases the soil–pipe interaction forces on pipelines in high curvature zones. The beam–spring models and design guidelines, because of the uniform assumption of the soil spring stiffness along the pipe, do not consider this phenomenon. Therefore, to prevent the underestimation of forces on the pipeline, it is recommended to consider local increases in soil spring stiffness around the high curvature zone in beam–spring models. Moreover, drastic increases in the strain responses of the pipeline in the beam–spring model is a good criterion for a damage evaluation of the pipeline.

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Section: Analytical Evaluation Of Buried Pipeline Behaviormentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Comparison of 3D Solid and Beam–Spring FE Modeling Approaches in the Evaluation of Buried Pipeline Behavior at a Strike-Slip Fault Crossing

Talebi

Kiyono

2021

Energies

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“…Suzuki [9] developed a method for calculating the deformation and crosssectional force of a buried pipe subjected to fault displacement by solving the elastic equation of the beam with the range of yielding of the ground as the unknown in a model which treats the buried pipe as an elastic beam and the ground around it as elastoplastic springs. Talebi and Kiyono [10] developed a new governing equation that includes the exact nonlinear axial and transverse soil-pile interaction terms for a strike-slip fault crossing. At present, finite element analysis, in which the pipe and the ground are modeled as a beam element and nonlinear spring, respectively, is commonly used in design practice to evaluate the cross-sectional force generated in buried pipes subjected to fault displacement.…”

Section: Introductionmentioning

confidence: 99%

Discrete Element Analysis of Soil-Pipe Interaction Subjected to Normal and Reverse Faulting

Ono¹

2022

GEOMATE

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Buried pipelines are an essential component of lifelines. However, they are repeatedly damaged by earthquakes. Fault displacement is a significant cause of damage to buried pipelines. In this study, the response of buried pipelines to reverse fault, normal fault, and vertical dislocation was evaluated using the discrete element method (DEM), which can model the details of the nonlinear behavior of the ground. The characteristics of the deformation, bending moment and axial force of the buried pipe for each fault type are clarified about the burial depth. For comparison, a finite element analysis using soil springs was also performed. The results showed that the response of the buried pipe was significantly different from that of the DEM because the deformation of the ground surface could not be considered in the FEM analysis. For finite element analysis with soil springs for the practical design of buried pipes subjected to fault displacement, it is necessary to improve the model of soil springs.

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A simplified analytical method for the tunnels’ mechanical behaviour under the action of active fault zones

Yu,

Zhang,

Wang

et al. 2023

Computers and Geotechnics

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A refined nonlinear analytical method for buried pipelines crossing strike‐slip faults

Cited by 18 publications

References 42 publications

Comparison of 3D Solid and Beam–Spring FE Modeling Approaches in the Evaluation of Buried Pipeline Behavior at a Strike-Slip Fault Crossing

Comparison of 3D Solid and Beam–Spring FE Modeling Approaches in the Evaluation of Buried Pipeline Behavior at a Strike-Slip Fault Crossing

Discrete Element Analysis of Soil-Pipe Interaction Subjected to Normal and Reverse Faulting

A simplified analytical method for the tunnels’ mechanical behaviour under the action of active fault zones

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