Characterisation and Application of Bio-Inspired Hybrid Composite Sensors for Detecting Barely Visible Damage under Out-of-Plane Loadings

Traditional inspection methods often fall short in detecting defects or damage in fibre-reinforced polymer (FRP) composite structures, which can compromise their performance and safety over time. A prime example is barely visible impact damage (BVID) caused by out-of-plane loadings such as indentati...

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Published in:Sensors (Basel, Switzerland) Switzerland), 2024-08, Vol.24 (16), p.5170
Main Authors: Tabatabaeian, Ali, Mohammadi, Reza, Harrison, Philip, Fotouhi, Mohammad
Format: Article
Language:English
Subjects:
barely visible impact damage
Bending stresses
bio-inspired mechanochromic composites
Carbon
Design
Energy
hybrid composite sensor
Impact tests
Load
Radio frequency identification
Sensors
Velocity
visual inspection
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Mohammadi, Reza
Harrison, Philip
Fotouhi, Mohammad
description Traditional inspection methods often fall short in detecting defects or damage in fibre-reinforced polymer (FRP) composite structures, which can compromise their performance and safety over time. A prime example is barely visible impact damage (BVID) caused by out-of-plane loadings such as indentation and low-velocity impact that can considerably reduce the residual strength. Therefore, developing advanced visual inspection techniques is essential for early detection of defects, enabling proactive maintenance and extending the lifespan of composite structures. This study explores the viability of using novel bio-inspired hybrid composite sensors for detecting BVID in laminated FRP composite structures. Drawing inspiration from the colour-changing mechanisms found in nature, hybrid composite sensors composed of thin-ply glass and carbon layers are designed and attached to the surface of laminated FRP composites exposed to transverse loading. A comprehensive experimental characterisation, including quasi-static indentation and low-velocity impact tests alongside non-destructive evaluations such as ultrasonic C-scan and visual inspection, is conducted to assess the sensors' efficacy in detecting BVID. Moreover, a comparison between the two transverse loading types, static indentation and low-velocity impact, is presented. The results suggest that integrating sensors into composite structures has a minimal effect on mechanical properties such as structural stiffness and energy absorption, while substantially improving damage visibility. Additionally, the influence of fibre orientation of the sensing layer on sensor performance is evaluated, and correlations between internal and surface damage are demonstrated.
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subjects barely visible impact damage
Bending stresses
bio-inspired mechanochromic composites
Carbon
Design
Energy
hybrid composite sensor
Impact tests
Load
Radio frequency identification
Sensors
Velocity
visual inspection
title Characterisation and Application of Bio-Inspired Hybrid Composite Sensors for Detecting Barely Visible Damage under Out-of-Plane Loadings
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