Debonding detection in a carbon fibre reinforced concrete structure using guided waves

Giri, Paritosh; Kharkovsky, Sergey; Zhu, Xinqun; Clark, S. M.; Samali, Bijan

doi:10.1088/1361-665x/ab0b6e

Cited by 19 publications

(7 citation statements)

References 35 publications

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“…SHM based on guided waves can be used to monitor large thin-walled structures, as guided waves have the ability to travel over long distances with little loss of energy [ 24 ] and strongly interact with structural changes. Hence, guided waves can be used to detect structural damages of many kinds, such as cracks in riveted plates [ 25 ], delaminations in composite materials [ 26 ], debondings in carbon fiber reinforced concrete structures [ 27 ], among many others. However, guided wave-based SHM methods need advanced signal processing to correctly interpret the complex signals back-scattered from structural boundaries and potential damages, which is particularly challenging for complex and small structural components as the necked double shear lug considered in the present investigation.…”

Section: Introductionmentioning

confidence: 99%

Crack Identification in Necked Double Shear Lugs by Means of the Electro-Mechanical Impedance Method

Winklberger

Kralovec

Humer

et al. 2020

Sensors

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This contribution investigates fatigue crack detection, localization and quantification in idealized necked double shear lugs using piezoelectric transducers attached to the lug shaft and analyzed by the electro-mechanical impedance (EMI) method. The considered idealized necked lug sample has a simplified geometry and does not includes the typical bearing. Numerical simulations with coupled-field finite element (FE) models are used to study the frequency response behavior of necked lugs. These numerical analyses include both pristine and cracked lug models. Through-cracks are located at 90∘ and 145∘ to the lug axis, which are critical spots for damage initiation. The results of FE simulations with a crack location at 90∘ are validated with experiments using an impedance analyzer and a scanning laser Doppler vibrometer. For both experiments, the lug specimen is excited and measured using a piezoelectric active wafer sensor in a frequency range of 1 kHz to 100 kHz. The dynamic response of both numerical calculations and experimental measurements show good agreement. To identify (i.e., detect, locate, and quantify) cracks in necked lugs a two-step analysis is performed. In the first step, a crack is detected data-based by calculating damage metrics between pristine and damaged state frequency spectra and comparing the resulting values to a pre-defined threshold. In the second step the location and size of the detected crack is identified by evaluation of specific resonance frequency shifts of the necked lug. Both the search for frequencies sensitive to through-cracks that allow a distinction between the two critical locations and the evaluation of the crack size are model-based. This two-step analysis based on the EMI method is demonstrated experimentally at the considered idealized necked lug, and thus, represents a promising way to reliably detect, locate and quantify fatigue cracks at critical locations of real necked double shear lugs.

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Section: Introductionmentioning

confidence: 99%

Crack Identification in Necked Double Shear Lugs by Means of the Electro-Mechanical Impedance Method

Winklberger

Kralovec

Humer

et al. 2020

Sensors

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“…Despite the fact the acoustic emission, ultrasonic detection, infrared thermography, electrochemical impedance spectroscopy and PZT methods can successfully detect the bond defect between concrete and CFRP, few of them have been implemented successfully to interfacial damage monitoring [20]. Moreover, the guided wave techniques described above require embedded PZTs inside the structure which require special interrogation and preparation [21]. In addition, some of the mentioned techniques involve access to the FRP lamina.…”

Section: Introductionmentioning

confidence: 99%

Wave Propagation and Scattering due to Debonding in CFRP Strengthened Reinforced Concrete Beams

Masri¹,

Gan²

2020

RPM

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Carbon fibre reinforced polymer (CFRP) systems as sheets or plates are commonly used to strengthen and retrofit damaged reinforced concrete beams. In general, the bond between the FRP element and concrete defines the effectiveness of the externally bonded FRP materials. In most cases, the interface bonding behaviour is usually tested via static loading conditions. In this paper, the bonding is verified under dynamic conditions. Wave propagation is modelled in delaminated CFRP strengthened reinforced concrete beam. First, the Wave Finite Element (WFE) is applied to predict the wave characteristics of the waveguides. Having established free wave solutions, one can couple it to a damaged segment that can be modelled in FE. The bond-slip model is used to simulate the CFRP to concrete interface bonding behaviour. Then, wave scattering characteristics are identified at the damaged section. Partial loss of debonding results in high refection coefficient of higher order modes. This study can lead to further advance based damage detection techniques related to debonding of FRP element to concrete with no required access to the FRP lamina.

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“…Although some attempt has been made in the past for EB FRP reinforcement using this approach, the limitations are clear [15]. More frequently, different statistical metrics, such as the root mean square deviation (RMSD), the correlation coefficient (CC), or the covariance (Cov), have been used to characterize damage from changes of the impedance signatures [16,17]. However, the use of a single type of metric for EMI based identification has some limitations regarding damage location and severity.…”

Section: Introductionmentioning

confidence: 99%

An EMI-Based Clustering for Structural Health Monitoring of NSM FRP Strengthening Systems

Perera

Torres

Ruíz

et al. 2019

Sensors

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The use of fiber-reinforced polymers (FRP) in civil construction applications with the near-surface mounted (NSM) method has gained considerable popularity worldwide and can produce confident strengthening and repairing systems for existing concrete structures. By using this technique, the FRP reinforcement is installed into slits cut into the concrete cover using cement mortar or epoxy as bonding materials, yielding an attractive method to strengthen concrete structures as an advantageous alternative to the external bonding of FRP sheets. However, in addition to the two conventional failure modes of concrete beams, sudden and brittle debonding failures are still likely to happen. Due to this, a damage identification technology able to identify anomalies at early stages is needed. In this work, some relevant cluster-based methods and their adaptation to electromechanical impedance (EMI)-based damage detection in NSM-FRP strengthened structures are developed and validated with experimental tests. The performance of the proposed clustering approaches and their evaluation in comparison with the experimental observations have shown a strong potential of these techniques as damage identification methodology in an especially complex problem such as NSM-FRP strengthened concrete structures.

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Debonding detection in a carbon fibre reinforced concrete structure using guided waves

Cited by 19 publications

References 35 publications

Crack Identification in Necked Double Shear Lugs by Means of the Electro-Mechanical Impedance Method

Crack Identification in Necked Double Shear Lugs by Means of the Electro-Mechanical Impedance Method

Wave Propagation and Scattering due to Debonding in CFRP Strengthened Reinforced Concrete Beams

An EMI-Based Clustering for Structural Health Monitoring of NSM FRP Strengthening Systems

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