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Effects of seawater on mechanical performance of composite sandwich structures: a machine learning framework

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Sandwich structures made with fibre-reinforced plastics are commonly used in maritime vessels thanks to their high strength-to-weight ratios, corrosion resistance, and buoyancy. Understanding their mechanical performance after moisture uptake and the implications of moisture up-take for their structural integrity and safety within out-of-plane loading regimes is vital for material optimisation. The use of modern methods such as acoustic emission (AE) and machine learning (ML) could provide effective techniques for the assessment of mechanical behaviour and structural health monitoring. In this study, the AE features obtained from quasi-static indentation tests on sandwich structures made from E-glass fibre face sheets with polyvinyl chloride foam cores were employed. Time- and frequency-domain features were then used to capture the relevant information and patterns within the AE data. A k-means++ algorithm was utilized for clustering analysis, providing insights into the principal damage modes of the studied structures. Three ensemble learning algorithms were employed to develop a damage-prediction model for samples exposed and unexposed to seawater and were loaded with indenters of different geometries. The developed models effectively identified all damage modes for the various indenter geometries under different loading conditions with accuracy scores between 86.4 and 95.9%. This illustrates the significant potential of ML for the prediction of damage evolution in composite structures for marine applications.

Funding

Nigerian Air Force grant number:OPS/1282DTG27145AJUL2

Royal Society, grant number: RGS\R1\221368

History

School

  • Mechanical, Electrical and Manufacturing Engineering

Published in

Materials

Volume

17

Issue

11

Publisher

MDPI

Version

  • VoR (Version of Record)

Rights holder

© the authors

Publisher statement

This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license (https://creativecommons.org/licenses/by/4.0/).

Acceptance date

2024-05-22

Publication date

2024-05-25

Copyright date

2024

Notes

This article belongs to the Special Issue Non-destructive Testing of Materials and Parts: Techniques, Case Studies and Practical Applications.

Language

  • en

Depositor

Norman Osa-Uwagboe. Deposit date: 27 May 2024

Article number

2549

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