Defect Detection using Power Spectrum of Torsional Waves in Guided-Wave Inspection of Pipelines

Mahal, Houman Nakhli; Yang, Kai; Nandi, Asoke K.

doi:10.3390/app9071449

Cited by 10 publications

(5 citation statements)

References 20 publications

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“…In each iteration, the signal is normalised, and its corresponding power spectrum is generated to detect the Torsional wave. However, due to significant changes in the excitation sequences, it is not recommended to use this algorithm with frequencies higher than 42 kHz [5].…”

Section: Pipesmentioning

confidence: 99%

“…The multi-modal and dispersive nature of guided waves makes the signal processing particularly challenging, which has been the subject of several studies over the years [4][5][6]. The used techniques are not necessary only for the interpretation of the received ultrasonic signals but also for procedure automation, which improves the non-destructive testing and evaluation, along with their reliability and replicability.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

A Review of Signal Processing Techniques for Ultrasonic Guided Wave Testing

Diogo

Moreira²,

Gouveia³

et al. 2022

Metals

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Ultrasonic guided wave testing (UGWT) is a non-destructive testing (NDT) technique commonly used in structural health monitoring to perform wide-range inspection from a single point, thus reducing the time and effort required for NDT. However, the multi-modal and dispersive nature of guided waves makes the extraction of essential information that leads to defect detection an extremely challenging task. The purpose of this article is to give an overview of signal processing techniques used for filtering signals, isolating modes and identifying and localising defects in UGWT. The techniques are summarised and grouped according to the geometry of the studied structures. Although the reviewed techniques have led to satisfactory results, the identification of defects through signal processing remains challenging with space for improvement, particularly by combining signal processing techniques and integrating machine learning algorithms.

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Section: Pipesmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

A Review of Signal Processing Techniques for Ultrasonic Guided Wave Testing

Diogo

Moreira²,

Gouveia³

et al. 2022

Metals

View full text Add to dashboard Cite

show abstract

“…The results show that the reflection coefficient of axisymmetric cracks increases monotonically with depth. Houman [16] proposed a method using the power spectrum difference between torsional waves and flexural waves to detect the torsional waves and determine the defect location. Kim and Park [17,18] used the basic torsional Sensors 2023, 23, 8734 2 of 12 mode to characterize the axial and inclined defects in the pipe and found that at a fixed depth of the defect, the reflection coefficient is a linear function of the ratio of the equivalent circumference range of the defect to the outer circumference of the pipe, and is almost independent of the axial range.…”

Section: Introductionmentioning

confidence: 99%

Circumferential Damage Monitoring of Steel Pipe Using a Radar Map Based on Torsional Guided Waves

Zheng,

Zhang

2023

Sensors

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Ultrasonic guided wave technology has been successfully applied to detect multiple types of defects in pipes. However, the circumferential location and coverage of a defect are less studied because it is difficult to determine. In this study, the fundamental torsional mode T (0, 1) is selected to conduct monitoring of the circumferential defect in pipelines because of its almost non-dispersive property. A radar map of the peak wave signals at 30 circumferential positions is proposed to detect the damage. The circumferential defect of a steel pipe is thoroughly investigated using numerical simulation. First, the circumferential positioning of defects in various areas of the pipe is studied. Second, the results are compared to those based on longitudinal guide waves. Finally, the circumferential coverage of a defect in the pipeline is determined. The waves are excited and received using the pitch–catch approach, and the collected monitoring signals are processed using the Hilbert transformation. According to the findings, the circumferential defect in the pipe can be effectively identified from a ‘T’ shape in the radar image, and the monitoring method by the torsional guided wave is superior to the longitudinal wave method. The results clearly demonstrate the advantages of torsional guided waves in defect monitoring. The proposed method is expected to provide a promising solution to circumferential damage identification in pipelines.

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“…Performance degradation of pipelines will undoubtedly affect normal operation and cause serious accidents like explosions and leakages. In order to check the working state of pipelines, many researchers have proposed various effective methods, by which defects have been successfully detected [1][2][3][4][5][6][7][8] .…”

Section: Introductionmentioning

confidence: 99%

An analytical approach to reconstruction of axisymmetric defects in pipelines using T(0, 1) guided waves

Wang

Liu

et al. 2020

Appl. Math. Mech.-Engl. Ed.

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Torsional guided waves have been widely utilized to inspect surface corrosion in pipelines due to their simple displacement behavior and the ability of long-range transmission. Especially, the torsional mode T(0,1), which is the first order of torsional guided waves, plays the irreplaceable position and role, mainly because of its non-dispersion characteristic property. However, one of the most pressing challenges faced in modern quality inspection is to detect surface defects in pipelines with a high level of accuracy. Taking into account this situation, a quantitative reconstruction method using the torsional guided wave T(0,1) is proposed in this paper. The methodology for defect reconstruction consists of three steps. Firstly, reflection coefficients of the guided wave T(0,1) scattered by different sizes of axisymmetric defects are calculated using the developed hybrid finite element method (HFEM). Then, applying the boundary integral equation and Born approximation, Fourier transform of the surface defect profile can be analytically derived as the correlative product of reflection coefficients of torsional guided wave T(0,1) and the fundamental solution of the intact pipeline in frequency domain. Finally, reconstruction of defects is precisely performed by inverse Fourier transform of the product in the frequency domain. Numerical experiments show that the proposed approach is suitable for the detection of surface defects with arbitrary shapes.Meanwhile, effects of the depth and width of surface defects on the accuracy of defect reconstruction have been investigated. It is noted that the reconstructive error is less than 10%, providing the defect depth is no more than half of the pipe thickness.

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Defect Detection using Power Spectrum of Torsional Waves in Guided-Wave Inspection of Pipelines

Cited by 10 publications

References 20 publications

A Review of Signal Processing Techniques for Ultrasonic Guided Wave Testing

A Review of Signal Processing Techniques for Ultrasonic Guided Wave Testing

Circumferential Damage Monitoring of Steel Pipe Using a Radar Map Based on Torsional Guided Waves

An analytical approach to reconstruction of axisymmetric defects in pipelines using T(0, 1) guided waves

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