Grigorios Tsinidis scite author profile

This paper presents an extended set of numerical fragility functions for the structural assessment of buried steel natural gas (NG) pipelines subjected to axial compression caused by transient seismic ground deformations. The study focuses on NG pipelines crossing sites with a vertical geotechnical discontinuity, where high compression straining of a buried pipeline is expected to occur under seismic transient ground deformations. A de-coupled numerical framework is developed for this purpose, which includes a 3D finite element model of the pipetrench system employed to evaluate rigorously the soil-pipe interaction effects on the pipeline axial response in a quasi-static manner. One-dimensional soil response analyses are used to determine critical ground deformation patterns at the vicinity of the geotechnical discontinuity, caused by the ground shaking. A comprehensive parametric analysis is performed by implementing the proposed analytical framework for an ensemble of 40 recorded earthquake ground motions. Crucial parameters that affect the seismic response and therefore the seismic vulnerability of buried steel NG pipelines namely, the diameter, wall thickness, burial depth and internal pressure of the pipeline, the backfill compaction level, the pipe-soil interface friction characteristics, the soil deposits characteristics, as well as initial geometric imperfections of the walls of the pipeline, are systematically considered. The analytical fragility functions are developed in terms of peak ground velocity (PGV) at the ground surface, for four performance limit states, considering all the associated uncertainties. The study contributes towards a reliable quantitative risk assessment of buried steel NG pipelines, crossing similar sites, subjected to seismically-induced transient ground deformations.

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Seismic behaviour of circular tunnels accounting for above ground structures interaction effects

Pitilakis

Tsinidis

Leanza

et al. 2014

Soil Dynamics and Earthquake Engineering

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Grigorios Tsinidis

Performance and Seismic Design of Underground Structures

Seismic behaviour of tunnels: From experiments to analysis

Seismic vulnerability of circular tunnels in soft soil deposits: The case of Shanghai metropolitan system

Effects of SSI and lining corrosion on the seismic vulnerability of shallow circular tunnels

Response characteristics of rectangular tunnels in soft soil subjected to transversal ground shaking

Seismic response of box-type tunnels in soft soil: Experimental and numerical investigation

Seismic fragility of buried steel natural gas pipelines due to axial compression at geotechnical discontinuities

Seismic behaviour of circular tunnels accounting for above ground structures interaction effects

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