Finite Element Modelling on the Mechanical Behaviour of Marine Bonded Composite Hose (MBCH) under Burst and Collapse

Chiemela Victor Amaechi; Cole Chesterton; Harrison Obed Butler; Zewen Gu; Agbomerie Charles Odijie; Facheng Wang; Xiaonan Hou; Jianqiao Ye

doi:10.3390/jmse10020151

Finite Element Modelling on the Mechanical Behaviour of Marine Bonded Composite Hose (MBCH) under Burst and Collapse

Chiemela Victor Amaechi^*, Cole Chesterton, Harrison Obed Butler, Zewen Gu, Agbomerie Charles Odijie, Facheng Wang, Xiaonan Hou, Jianqiao Ye^*

^*Corresponding author for this work

Department of Energy Conversion and Storage

Research output: Contribution to journal › Journal article › Research › peer-review

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Abstract

Currently, the properties of composites have been harnessed on pipelines in the marine offshore industry. In this study, marine bonded composite hose (MBCH) is presented. It is aimed at understanding the stress/strain distribution on marine bonded hoses using local design pressure under burst and collapse cases. This study also investigates composite material modelling, hose modelling, liner wrinkling, helical spring deformation, and two MBCH models—with and without ovalisation. The ovalized model is considered the simplified model in this research. A mesh study was carried out on meshing the hose layers. In this study, local design pressure was considered and not operational pressure. This finite element model was adopted to predict the deformation and mechanical response behaviour of MBCH. From this study, composites could be considered to improve conventional marine hoses. The study findings include identification of buckled sections on the hose and stressed zones on the helix reinforcement. Highly reinforced hose ends are recommended in ends of the MBCH as they had maximum stress and strain values.

Original language	English
Article number	151
Journal	Journal of Marine Science and Engineering
Volume	10
Issue number	2
Number of pages	24
ISSN	2077-1312
DOIs	https://doi.org/10.3390/jmse10020151
Publication status	Published - 2022

Keywords

Marine bonded composite hose
Finite element model
Composite riser
Layered marine structures
Helix spring
Liner wrinkling
Numerical model
Stress analysis
Bonded model

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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title = "Finite Element Modelling on the Mechanical Behaviour of Marine Bonded Composite Hose (MBCH) under Burst and Collapse",

abstract = "Currently, the properties of composites have been harnessed on pipelines in the marine offshore industry. In this study, marine bonded composite hose (MBCH) is presented. It is aimed at understanding the stress/strain distribution on marine bonded hoses using local design pressure under burst and collapse cases. This study also investigates composite material modelling, hose modelling, liner wrinkling, helical spring deformation, and two MBCH models—with and without ovalisation. The ovalized model is considered the simplified model in this research. A mesh study was carried out on meshing the hose layers. In this study, local design pressure was considered and not operational pressure. This finite element model was adopted to predict the deformation and mechanical response behaviour of MBCH. From this study, composites could be considered to improve conventional marine hoses. The study findings include identification of buckled sections on the hose and stressed zones on the helix reinforcement. Highly reinforced hose ends are recommended in ends of the MBCH as they had maximum stress and strain values.",

keywords = "Marine bonded composite hose, Finite element model, Composite riser, Layered marine structures, Helix spring, Liner wrinkling, Numerical model, Stress analysis, Bonded model",

author = "Amaechi, {Chiemela Victor} and Cole Chesterton and Butler, {Harrison Obed} and Zewen Gu and Odijie, {Agbomerie Charles} and Facheng Wang and Xiaonan Hou and Jianqiao Ye",

year = "2022",

doi = "10.3390/jmse10020151",

language = "English",

volume = "10",

journal = "Journal of Marine Science and Engineering",

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T1 - Finite Element Modelling on the Mechanical Behaviour of Marine Bonded Composite Hose (MBCH) under Burst and Collapse

AU - Amaechi, Chiemela Victor

AU - Chesterton, Cole

AU - Butler, Harrison Obed

AU - Gu, Zewen

AU - Odijie, Agbomerie Charles

AU - Wang, Facheng

AU - Hou, Xiaonan

AU - Ye, Jianqiao

PY - 2022

Y1 - 2022

N2 - Currently, the properties of composites have been harnessed on pipelines in the marine offshore industry. In this study, marine bonded composite hose (MBCH) is presented. It is aimed at understanding the stress/strain distribution on marine bonded hoses using local design pressure under burst and collapse cases. This study also investigates composite material modelling, hose modelling, liner wrinkling, helical spring deformation, and two MBCH models—with and without ovalisation. The ovalized model is considered the simplified model in this research. A mesh study was carried out on meshing the hose layers. In this study, local design pressure was considered and not operational pressure. This finite element model was adopted to predict the deformation and mechanical response behaviour of MBCH. From this study, composites could be considered to improve conventional marine hoses. The study findings include identification of buckled sections on the hose and stressed zones on the helix reinforcement. Highly reinforced hose ends are recommended in ends of the MBCH as they had maximum stress and strain values.

AB - Currently, the properties of composites have been harnessed on pipelines in the marine offshore industry. In this study, marine bonded composite hose (MBCH) is presented. It is aimed at understanding the stress/strain distribution on marine bonded hoses using local design pressure under burst and collapse cases. This study also investigates composite material modelling, hose modelling, liner wrinkling, helical spring deformation, and two MBCH models—with and without ovalisation. The ovalized model is considered the simplified model in this research. A mesh study was carried out on meshing the hose layers. In this study, local design pressure was considered and not operational pressure. This finite element model was adopted to predict the deformation and mechanical response behaviour of MBCH. From this study, composites could be considered to improve conventional marine hoses. The study findings include identification of buckled sections on the hose and stressed zones on the helix reinforcement. Highly reinforced hose ends are recommended in ends of the MBCH as they had maximum stress and strain values.

KW - Marine bonded composite hose

KW - Finite element model

KW - Composite riser

KW - Layered marine structures

KW - Helix spring

KW - Liner wrinkling

KW - Numerical model

KW - Stress analysis

KW - Bonded model

U2 - 10.3390/jmse10020151

DO - 10.3390/jmse10020151

M3 - Journal article

SN - 2077-1312

VL - 10

JO - Journal of Marine Science and Engineering

JF - Journal of Marine Science and Engineering

IS - 2

M1 - 151

ER -

Finite Element Modelling on the Mechanical Behaviour of Marine Bonded Composite Hose (MBCH) under Burst and Collapse

Abstract

Keywords

UN SDGs

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