Local buckling failure analysis of high-strength pipelines

Local buckling failure analysis of high-strength pipelines

Abstract Pipelines in geological disaster regions typically suffer the risk of local buckling failure because of slender structure and complex load. This paper is meant to reveal the local buckling behavior of buried pipelines with a large diameter and high strength, which are under different condit...

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Detalles Bibliográficos
Autores principales: Yan Li, Jian Shuai, Zhong-Li Jin, Ya-Tong Zhao, Kui Xu
Formato: article
Lenguaje:EN
Publicado: KeAi Communications Co., Ltd. 2017
Materias:
Local buckling
High-strength pipeline
Finite element analysis
Critical bending moment
Critical compressive stress
Critical compressive strain
Science
Q
Petrology
QE420-499
Acceso en línea:https://doaj.org/article/3fc82dfabf6741d7a368205425bfffd8
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Sumario:Abstract Pipelines in geological disaster regions typically suffer the risk of local buckling failure because of slender structure and complex load. This paper is meant to reveal the local buckling behavior of buried pipelines with a large diameter and high strength, which are under different conditions, including pure bending and bending combined with internal pressure. Finite element analysis was built according to previous data to study local buckling behavior of pressurized and unpressurized pipes under bending conditions and their differences in local buckling failure modes. In parametric analysis, a series of parameters, including pipe geometrical dimension, pipe material properties and internal pressure, were selected to study their influences on the critical bending moment, critical compressive stress and critical compressive strain of pipes. Especially the hardening exponent of pipe material was introduced to the parameter analysis by using the Ramberg–Osgood constitutive model. Results showed that geometrical dimensions, material and internal pressure can exert similar effects on the critical bending moment and critical compressive stress, which have different, even reverse effects on the critical compressive strain. Based on these analyses, more accurate design models of critical bending moment and critical compressive stress have been proposed for high-strength pipelines under bending conditions, which provide theoretical methods for high-strength pipeline engineering.

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