Laser-induced graphene as an embedded sensor for impact damage in composite structures assisted by machine learning
Laser-induced graphene as an embedded sensor for impact damage in composite structures assisted by machine learning
Laser-induced graphene (LIG) enables the creation of cost-effective sensing devices via one-step laser scribing on organic substrates. This work aims to demonstrate the feasibility of LIG as an embedded damage sensor in structural composite materials. LIG was produced on an inexpensive cork substrate using a low-power blue light laser engraving system. The LIG was characterised to establish the relationship between the LIG’s physical properties and the lasing parameters. Using the lasing parameters which offer the optimal LIG properties, a LIG mesh pattern lased on the cork substrate was embedded in a glass fibre composite laminate as the damage-sensing core material to assess its sensing capability for impact damage. By measuring the electrical resistance change in the LIG mesh pattern consisting of a series of horizontal and vertical channels before and after impact loading, it was able to define the location of internal damage and its damage size, validated by X-ray computed tomography results. It is demonstrated that the test data can be used to train a machine learning algorithm to develop a simple damage-sensing system with a high accuracy rate of 94.3%, which significantly reduces the manual effort for large-scale composite structural health monitoring. This simple damage sensing system can be used to monitor internal impact damage in composite structures, such as off-shore wind turbine blades, which are inaccessible for inspection by conventional non-destructive testing.
damage-sensing, fibre-reinforced polymeric composites, Laser-induced graphene, machine learning, structural health monitoring
Chen, Xue
78813301-5484-4b91-9291-31da562d5bff
Gan, Khong Wui
b0c1e988-d375-4bbc-acdc-c77a6da1f904
Pu, Suan Hui
8b46b970-56fd-4a4e-8688-28668f648f43
Jalalvand, Meisam
21ef0df8-fc7c-4466-a2fc-ee98ed3408a2
Hamilton, Andrew R.
9088cf01-8d7f-45f0-af56-b4784227447c
16 January 2025
Chen, Xue
78813301-5484-4b91-9291-31da562d5bff
Gan, Khong Wui
b0c1e988-d375-4bbc-acdc-c77a6da1f904
Pu, Suan Hui
8b46b970-56fd-4a4e-8688-28668f648f43
Jalalvand, Meisam
21ef0df8-fc7c-4466-a2fc-ee98ed3408a2
Hamilton, Andrew R.
9088cf01-8d7f-45f0-af56-b4784227447c
Chen, Xue, Gan, Khong Wui, Pu, Suan Hui, Jalalvand, Meisam and Hamilton, Andrew R.
(2025)
Laser-induced graphene as an embedded sensor for impact damage in composite structures assisted by machine learning.
Structural Health Monitoring.
(doi:10.1177/14759217241311516).
Abstract
Laser-induced graphene (LIG) enables the creation of cost-effective sensing devices via one-step laser scribing on organic substrates. This work aims to demonstrate the feasibility of LIG as an embedded damage sensor in structural composite materials. LIG was produced on an inexpensive cork substrate using a low-power blue light laser engraving system. The LIG was characterised to establish the relationship between the LIG’s physical properties and the lasing parameters. Using the lasing parameters which offer the optimal LIG properties, a LIG mesh pattern lased on the cork substrate was embedded in a glass fibre composite laminate as the damage-sensing core material to assess its sensing capability for impact damage. By measuring the electrical resistance change in the LIG mesh pattern consisting of a series of horizontal and vertical channels before and after impact loading, it was able to define the location of internal damage and its damage size, validated by X-ray computed tomography results. It is demonstrated that the test data can be used to train a machine learning algorithm to develop a simple damage-sensing system with a high accuracy rate of 94.3%, which significantly reduces the manual effort for large-scale composite structural health monitoring. This simple damage sensing system can be used to monitor internal impact damage in composite structures, such as off-shore wind turbine blades, which are inaccessible for inspection by conventional non-destructive testing.
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chen-et-al-2025-laser-induced-graphene-as-an-embedded-sensor-for-impact-damage-in-composite-structures-assisted-by
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e-pub ahead of print date: 16 January 2025
Published date: 16 January 2025
Keywords:
damage-sensing, fibre-reinforced polymeric composites, Laser-induced graphene, machine learning, structural health monitoring
Identifiers
Local EPrints ID: 500971
URI: http://eprints.soton.ac.uk/id/eprint/500971
ISSN: 1475-9217
PURE UUID: af2e3628-718d-47c1-aa22-265d02119f7c
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Date deposited: 20 May 2025 16:33
Last modified: 30 Aug 2025 02:04
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Author:
Xue Chen
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