High performance piezo electric nanocomposite sensor nodes for structural health monitoring

Mohamad Fotouhi, Bill Xiao, Thomas Pozegic, Meisam Jalalvand, Ian Hamerton, Michael R. Wisnom

Research output: Contribution to conferencePaper

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Abstract

The increased usage of composite materials has raised the need for a more reliable damage detection strategy for structural health monitoring (SHM) systems. An important, and as yet unsolved, limitation of existing composite laminates is their susceptibility to impact damage. Low-velocity impact-induced damage is often hard to spot from the impacted side in a routine visual inspection, but it has a significant effect on the mechanical performance of laminates. This work investigates the possibility of embedding poly (vinylidene fluoride) (PVDF) as a sensor node for a passive SHM system in SE70 glass/epoxy laminates to monitor the damage while being subjected to an indentation test. The mechanical test results for the laminates both with and without embedded sensors indicate that the embedment of the PVDF sensors does not change the measured mechanical properties of the laminates. Acoustic emission (AE) signals obtained using the embedded PVDF sensor were compared with an identical PVDF sensor attached on the laminate’s surface. The results showed the possibility of successfully embedding PVDF sensors in composite laminates and the functionality of the PVDF sensors after the embedding procedure, i.e. their ability to withstand the composite curing temperature without experiencing degradation. However, the amplitude level of the AE signals obtained with the PVDF is lower than that of the commercial sensor, which is due to the low coupling factor and dielectric constant of the PVDF. Therefore, the development of two- and three-phase AE sensors (lead zirconate titanate (PZT)/epoxy and graphene nanoplatelets (GnPs)) were also explored to improve the sensitivity of the embedded sensor. The fabrication methods have been developed and the fabricated sensors showed better performance than PVDF sensors during the Hsu-Nielsen Source test. This is a continuing project, therefore further research will be conducted to implant the PZT nanocomposite sensors into composite laminate plates to examine the applicability of these novel sensors as flexible and light weight embedded sensor nodes for structural health monitoring systems.

Original languageEnglish
Number of pages9
Publication statusPublished - 25 Aug 2017
Event21st International Conference on Composite Materials, ICCM 2017 - Xi'an, China
Duration: 20 Aug 201725 Aug 2017

Conference

Conference21st International Conference on Composite Materials, ICCM 2017
CountryChina
CityXi'an
Period20/08/1725/08/17

Fingerprint

Structural health monitoring
Sensor nodes
Nanocomposites
Laminates
Sensors
Acoustic emissions
Composite materials
polyvinylidene fluoride
Graphite
Damage detection
Indentation
Graphene
Curing
Permittivity
Inspection

Keywords

  • acoustic emission
  • composite laminates
  • graphene platelets
  • nanocomposite sensors
  • PVDF
  • emission signals
  • acoustic emission testing
  • tructural health monitoring (SHM) systems

Cite this

Fotouhi, M., Xiao, B., Pozegic, T., Jalalvand, M., Hamerton, I., & Wisnom, M. R. (2017). High performance piezo electric nanocomposite sensor nodes for structural health monitoring. Paper presented at 21st International Conference on Composite Materials, ICCM 2017, Xi'an, China.
Fotouhi, Mohamad ; Xiao, Bill ; Pozegic, Thomas ; Jalalvand, Meisam ; Hamerton, Ian ; Wisnom, Michael R. / High performance piezo electric nanocomposite sensor nodes for structural health monitoring. Paper presented at 21st International Conference on Composite Materials, ICCM 2017, Xi'an, China.9 p.
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Fotouhi, M, Xiao, B, Pozegic, T, Jalalvand, M, Hamerton, I & Wisnom, MR 2017, 'High performance piezo electric nanocomposite sensor nodes for structural health monitoring' Paper presented at 21st International Conference on Composite Materials, ICCM 2017, Xi'an, China, 20/08/17 - 25/08/17, .

High performance piezo electric nanocomposite sensor nodes for structural health monitoring. / Fotouhi, Mohamad; Xiao, Bill; Pozegic, Thomas; Jalalvand, Meisam; Hamerton, Ian; Wisnom, Michael R.

2017. Paper presented at 21st International Conference on Composite Materials, ICCM 2017, Xi'an, China.

Research output: Contribution to conferencePaper

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T1 - High performance piezo electric nanocomposite sensor nodes for structural health monitoring

AU - Fotouhi, Mohamad

AU - Xiao, Bill

AU - Pozegic, Thomas

AU - Jalalvand, Meisam

AU - Hamerton, Ian

AU - Wisnom, Michael R.

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KW - composite laminates

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KW - emission signals

KW - acoustic emission testing

KW - tructural health monitoring (SHM) systems

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Fotouhi M, Xiao B, Pozegic T, Jalalvand M, Hamerton I, Wisnom MR. High performance piezo electric nanocomposite sensor nodes for structural health monitoring. 2017. Paper presented at 21st International Conference on Composite Materials, ICCM 2017, Xi'an, China.