Model-experiment comparison for transverse loading of metal–composite ring specimen (part 1)
Model-experiment comparison for transverse loading of metal–composite ring specimen (part 1)
As a building block towards improved understanding and design of Composite Overwrapped Pressure Vessels (COPV), this paper presents simulations and experimental validation of a 3D finite element model for a metal–composite ring structure subjected to quasi-static indentation, used as a proxy for low velocity impact (LVI). The focus of the work is to model composite ply delamination as well as metal–composite separation, using cohesive elements. A methodology is presented to determine the parameters used for the traction-separation law that controls the cohesive elements. The model was calibrated and validated using a hybrid metal–composite ring at reasonable engineering length-scales, corresponding to structures with 159 mm outer diameter and 50 mm length. Each ring specimen was loaded in displacement controlled compression up to 20 mm, i.e. the point at which composite delamination and plastic deformation of the metallic layer has occurred. Validation is performed by comparing experimental force–displacement curves, strain fields and damage mechanisms to results obtained from the finite element (FE) model. Results from the numerical modelling are in good agreement with experimental values.
Montes De Oca Valle, Erick
40baadf7-905b-4a9b-9c8b-0aaeb6195e89
Spearing, Mark
9e56a7b3-e0e8-47b1-a6b4-db676ed3c17a
Sinclair, Ian
6005f6c1-f478-434e-a52d-d310c18ade0d
Allen, Trevor
3b152fc9-4013-4a41-9d8f-ff38aba5330c
Hepples, Warren
2ef2a0f5-159e-4601-b48f-81d015fa9381
4 May 2023
Montes De Oca Valle, Erick
40baadf7-905b-4a9b-9c8b-0aaeb6195e89
Spearing, Mark
9e56a7b3-e0e8-47b1-a6b4-db676ed3c17a
Sinclair, Ian
6005f6c1-f478-434e-a52d-d310c18ade0d
Allen, Trevor
3b152fc9-4013-4a41-9d8f-ff38aba5330c
Hepples, Warren
2ef2a0f5-159e-4601-b48f-81d015fa9381
Montes De Oca Valle, Erick, Spearing, Mark, Sinclair, Ian, Allen, Trevor and Hepples, Warren
(2023)
Model-experiment comparison for transverse loading of metal–composite ring specimen (part 1).
International Journal of Pressure Vessels and Piping, 205, [104964].
(doi:10.1016/j.ijpvp.2023.104964).
Abstract
As a building block towards improved understanding and design of Composite Overwrapped Pressure Vessels (COPV), this paper presents simulations and experimental validation of a 3D finite element model for a metal–composite ring structure subjected to quasi-static indentation, used as a proxy for low velocity impact (LVI). The focus of the work is to model composite ply delamination as well as metal–composite separation, using cohesive elements. A methodology is presented to determine the parameters used for the traction-separation law that controls the cohesive elements. The model was calibrated and validated using a hybrid metal–composite ring at reasonable engineering length-scales, corresponding to structures with 159 mm outer diameter and 50 mm length. Each ring specimen was loaded in displacement controlled compression up to 20 mm, i.e. the point at which composite delamination and plastic deformation of the metallic layer has occurred. Validation is performed by comparing experimental force–displacement curves, strain fields and damage mechanisms to results obtained from the finite element (FE) model. Results from the numerical modelling are in good agreement with experimental values.
Text
1-s2.0-S0308016123000819-main
- Version of Record
More information
Accepted/In Press date: 20 April 2023
e-pub ahead of print date: 25 April 2023
Published date: 4 May 2023
Identifiers
Local EPrints ID: 494054
URI: http://eprints.soton.ac.uk/id/eprint/494054
ISSN: 0308-0161
PURE UUID: bed6ba3d-8311-4dd5-9f66-0185c0a62db2
Catalogue record
Date deposited: 20 Sep 2024 16:48
Last modified: 21 Sep 2024 01:40
Export record
Altmetrics
Contributors
Author:
Erick Montes De Oca Valle
Author:
Trevor Allen
Author:
Warren Hepples
Download statistics
Downloads from ePrints over the past year. Other digital versions may also be available to download e.g. from the publisher's website.
View more statistics
