Plastic limit loads for piping branch junctions under out-of-plane bending

Kuk Hee Lee; Yinghu Xu; Jun Young Jeon; Yun Jae Kim; Peter J. Budden

doi:10.1177/0309324711427001

Plastic limit loads for piping branch junctions under out-of-plane bending

Kuk Hee Lee, Yinghu Xu, Jun Young Jeon, Yun Jae Kim, Peter J. Budden

School of Mechanical Engineering

Research output: Contribution to journal › Article › peer-review

10 Citations (Scopus)

Abstract

This paper presents approximate closed-form plastic limit load solutions for branch junctions under out-of-plane bending and under combined pressure and out-of-plane bending, based on three-dimensional finite element limit analyses for an elastic-perfectly plastic material. When bending is applied to the branch pipe, the plastic limit loads for out-of-plane bending are shown to be lower than those for in-plane bending. However, for bending to the run pipe, the opposite trend is found. For combined pressure and out-of-plane bending, either the circular interaction or the parabolic interaction rule can be used, depending on the bending location and the branch geometry. Comparison with published experimental plastic limit load data shows that the predictions agree relatively well with the test data.

Original language	English
Pages (from-to)	32-45
Number of pages	14
Journal	Journal of Strain Analysis for Engineering Design
Volume	47
Issue number	1
DOIs	https://doi.org/10.1177/0309324711427001
Publication status	Published - 2012 Jan

Keywords

Branch junction
Combined pressure and out-of-plane bending
Finite element limit analysis
Limit load

ASJC Scopus subject areas

Modelling and Simulation
Mechanics of Materials
Mechanical Engineering
Applied Mathematics

Access to Document

10.1177/0309324711427001

Cite this

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title = "Plastic limit loads for piping branch junctions under out-of-plane bending",

abstract = "This paper presents approximate closed-form plastic limit load solutions for branch junctions under out-of-plane bending and under combined pressure and out-of-plane bending, based on three-dimensional finite element limit analyses for an elastic-perfectly plastic material. When bending is applied to the branch pipe, the plastic limit loads for out-of-plane bending are shown to be lower than those for in-plane bending. However, for bending to the run pipe, the opposite trend is found. For combined pressure and out-of-plane bending, either the circular interaction or the parabolic interaction rule can be used, depending on the bending location and the branch geometry. Comparison with published experimental plastic limit load data shows that the predictions agree relatively well with the test data.",

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AU - Lee, Kuk Hee

AU - Xu, Yinghu

AU - Jeon, Jun Young

AU - Kim, Yun Jae

AU - Budden, Peter J.

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N2 - This paper presents approximate closed-form plastic limit load solutions for branch junctions under out-of-plane bending and under combined pressure and out-of-plane bending, based on three-dimensional finite element limit analyses for an elastic-perfectly plastic material. When bending is applied to the branch pipe, the plastic limit loads for out-of-plane bending are shown to be lower than those for in-plane bending. However, for bending to the run pipe, the opposite trend is found. For combined pressure and out-of-plane bending, either the circular interaction or the parabolic interaction rule can be used, depending on the bending location and the branch geometry. Comparison with published experimental plastic limit load data shows that the predictions agree relatively well with the test data.

AB - This paper presents approximate closed-form plastic limit load solutions for branch junctions under out-of-plane bending and under combined pressure and out-of-plane bending, based on three-dimensional finite element limit analyses for an elastic-perfectly plastic material. When bending is applied to the branch pipe, the plastic limit loads for out-of-plane bending are shown to be lower than those for in-plane bending. However, for bending to the run pipe, the opposite trend is found. For combined pressure and out-of-plane bending, either the circular interaction or the parabolic interaction rule can be used, depending on the bending location and the branch geometry. Comparison with published experimental plastic limit load data shows that the predictions agree relatively well with the test data.

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KW - Combined pressure and out-of-plane bending

KW - Finite element limit analysis

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Plastic limit loads for piping branch junctions under out-of-plane bending

Abstract

Keywords

ASJC Scopus subject areas

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