An up-scaling temperature compensation framework for guided wave–based structural health monitoring in large composite structures

Giannakeas, Ilias N.; Khodaei, Zahra Sharif; Aliabadi, M.H.

doi:10.1177/14759217221095415

Cited by 15 publications

(2 citation statements)

References 45 publications

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“…In case measurements are performed at notably different temperatures, application of temperature compensation algorithms for the extracted wave velocities may be necessary. Examples of such algorithms can be found in literature [62][63][64][65][66]. Secondly, the presence of background noise interfering with the input signal may influence the measurement accuracy.…”

Section: Limitations and Practical Remarksmentioning

confidence: 99%

In Situ Non-Destructive Stiffness Assessment of Fiber Reinforced Composite Plates Using Ultrasonic Guided Waves

Adams,

Huijer,

Kassapoglou

et al. 2024

Sensors

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The multimodal and dispersive character of ultrasonic guided waves (UGW) offers the potential for non-destructive evaluation of fiber-reinforced composite (FRC) materials. In this study, a methodology for in situ stiffness assessment of FRCs using UGWs is introduced. The proposed methodology involves a comparison between measured wave speeds of the fundamental symmetric and antisymmetric guided wave modes with a pre-established dataset of UGW speeds and translation of them to corresponding stiffness properties, i.e., ABD-components, in an inverse manner. The dispersion relations of guided waves have been calculated using the semi-analytical finite element method. First, the performance of the proposed methodology has been assessed numerically. It has been demonstrated that each of the independent ABD-components of the considered laminate can be approximated with an error lower than 10.4% compared to its actual value. The extensional and bending stiffness properties can be approximated within an average error of 3.6% and 9.0%, respectively. Secondly, the performance of the proposed methodology has been assessed experimentally. This experimental assessment has been performed on a glass fiber-reinforced composite plate and the results were compared to mechanical tensile and four-point bending tests on coupons cut from the plate. Larger differences between the estimated ABD-components according to UGW and mechanical testing were observed. These differences were partly attributed to the variation in material properties across the test plate and the averaging of properties over the measurement area.

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Section: Limitations and Practical Remarksmentioning

confidence: 99%

In Situ Non-Destructive Stiffness Assessment of Fiber Reinforced Composite Plates Using Ultrasonic Guided Waves

Adams,

Huijer,

Kassapoglou

et al. 2024

Sensors

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“…Guided wave structural health monitoring (GSHM) can be used to ensure the structural integrity of composites [11]. The following tasks can be achieved, such as damage detection, localization, and quantification [12][13][14][15][16]. Baseline-dependent SHM techniques require data from both defect-free and defective specimens.…”

Section: Introductionmentioning

confidence: 99%

Delamination Localization in Multilayered CFRP Panel Based on Reconstruction of Guided Wave Modes

Papanaboina,

Jasiuniene,

Samaitis

et al. 2023

Applied Sciences

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Multi-layered composite materials are being used in various engineering fields, such as aerospace, automobile, and wind energy, because of their superior material properties. Due to various impact loads during the service life of composite structures, different types of defects can occur, such as matrix cracking, fiber breakage, delaminations, etc. In this research, a novel SHM technique for delamination detection and localization using a minimum number of sensors is proposed. The analytical, numerical, and experimental analysis of GW was performed to increase the probability of detection and localization of delaminations in CFRP material. A new analytical model was developed, which enables identifying converted and transmitted modes in the presence of multiple GW modes. A 2D FFT-based spatial filtering was used to filter the GW modes. The dominant A0 mode was separated to inspect the delamination. Phase velocity is one of the important features in GW inspection to localize the delamination. A phase spectrum approach was developed to reconstruct the phase velocity dispersion of the GW modes in case material properties are unknown.

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Adaptive GMM and OTWD-based structural crack quantification under random load

Fang

Qiu

Yuan

et al. 2023

International Journal of Mechanical Sciences

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An up-scaling temperature compensation framework for guided wave–based structural health monitoring in large composite structures

Cited by 15 publications

References 45 publications

In Situ Non-Destructive Stiffness Assessment of Fiber Reinforced Composite Plates Using Ultrasonic Guided Waves

In Situ Non-Destructive Stiffness Assessment of Fiber Reinforced Composite Plates Using Ultrasonic Guided Waves

Delamination Localization in Multilayered CFRP Panel Based on Reconstruction of Guided Wave Modes

Adaptive GMM and OTWD-based structural crack quantification under random load

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