Structural Health Monitoring of Pressure Vessel Based on Guided Wave Technology. Part II: Damage Localization Accuracy Influencing Factors

The capabilities of detection and localization of damage in a structure, using a guided wave-based structural health monitoring (GWSHM) system, depend on the damage location and the chosen sensor array setup. This paper presents a novel approach to assess the reliability of an SHM system enabling to quantify localization accuracy. A two-step technique is developed to combine multiple paths to generate one probability of detection (POD) curve that provides information regarding the detection capability of an SHM system at a defined damage position. Moreover, a new method is presented to analyze localization accuracy. Established probability-based diagnostic imaging using a signal correlation algorithm is used to determine the damage location. The resultant output of the localization accuracy analysis is the smallest damage size at which a defined accuracy level can be reached at a determined location. The proposed methods for determination of detection probability and localization accuracy are applied to a plate-like CFRP structure with an omega stringer with artificial damage of different sizes at different locations. The results show that the location of the damage influences the sensitivity of detection and localization accuracy for the used detection and localization methods. Localization accuracy is enhanced as it becomes closer to the array’s center, but its detection sensitivity deteriorates.

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Damage Localization in Complex Composite Panels Using Guided Wave Based Structural Health Monitoring System

ASME 2011 Conference on Smart Materials, Adaptive Structures and Intelligent Systems, Volume 2 ◽

10.1115/smasis2011-5069 ◽

2011 ◽

Author(s):

Yingtao Liu ◽

Seung Bum Kim ◽

Aditi Chattopadhyay ◽

Derek Doyle

Keyword(s):

Structural Health Monitoring ◽

Health Monitoring ◽

Composite Structures ◽

Composite Plates ◽

Guided Wave ◽

Damage Localization ◽

Composite Panels ◽

Time Frequency ◽

Structural Health ◽

Damage Location

Knowledge of the damage location in composite structures is a necessary output for both Non-Destructive Evaluation (NDE) and Structural Health Monitoring (SHM). Although several damage localization approaches using a triangulation method and Time-of-Flight (ToF) of guided waves have been reported in literature, the damage localization technique is still not mature for composite structures with complex material properties, varying thickness and complex geometries. This paper investigates the development of a new approach for SHM and damage localization using a guided wave based active sensing system. In contrast to the traditional ellipse method, the proposed method does not require the information of structural thickness, ToF, or the estimation of group velocities of each guided wave mode at different propagation angles, which is one of the main limitations of most current ToF methodologies involving composites. This approach uses time-frequency analysis to calculate the difference of the ToF of the converted modes for each sensor signal. The damage location and the group velocity are obtained by solving a set of nonlinear equations. The proposed method can be used for composite structures with unknown lay-up and thickness. To validate the proposed method, experiments were conducted on both composite plates and stiffened composite panels. Eight piezoelectric (PZT) transducers were surface-bonded on each composite specimen and used in four pairs. The PZT transducers in each pair were bonded close to each other. In the PZT array, one PZT transducer from one PZT pair was used as the actuator and the other three pairs were used as sensors. A windowed cosine signal was used as the excitation signal. The locations of the delaminations in the composite specimens were validated using a flash thermography system. The accuracy of the proposed method in localizing delaminations was examined through comparison with the experimental measurements.

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Propagation of Guided Waves in Pressure Vessel and its Application for Damage Detection

Volume 4: Dynamics, Control and Uncertainty, Parts A and B ◽

10.1115/imece2012-86297 ◽

2012 ◽

Author(s):

Xuewei Sun ◽

Fucai Li ◽

Jinfu Wang ◽

Guang Meng ◽

Limin Zhou

Keyword(s):

Structural Health Monitoring ◽

Health Monitoring ◽

Pressure Vessel ◽

Guided Waves ◽

Pressure Vessels ◽

Guided Wave ◽

Special Equipment ◽

Element Analysis ◽

Structural Health ◽

Monitoring Technique

Pressure vessel is a kind of special equipment with explosion and leakage dangerous. Therefore, structural health monitoring (SHM) techniques for pressure vessel should ensure the safe operation of this kind of equipments and is becoming more crucial in petroleum, chemical, and relative industries. Guided wave-based structural health monitoring technique can be an appropriate method for real-time and online non-destructive damage monitoring technique. In recent years, applications of guided wave-based structural health monitoring techniques are mainly limited in simple structures, such as plates and tubes. Relatively few research papers focused on the application of this technique in large and complex structures like pressure vessels. Propagation characteristics of guided waves in pressure vessel are investigated in this study. Dispersion curves calculated by using numerical methods for longitudinal, circumferential, and torsional modes are presented. On the basis of comprehensive analysis of the guided waves dispersion and experimental waveforms, the parameters of the excitation wave are therefore optimized. In order to overcome the difficulties to identify the damage characteristics of signal, the layout scheme of sensor network is designed and optimized in this paper to simplify the waveform. Furthermore, both finite element analysis (FEA) and experiment methods are employed to investigate the propagation of elastic guided waves in a standard pressure vessel.

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Statistical Analysis of Guided Wave Imaging Algorithms Performance Illustrated by a Simple Structural Health Monitoring Configuration

Journal of Nondestructive Evaluation Diagnostics and Prognostics of Engineering Systems ◽

10.1115/1.4049571 ◽

2021 ◽

Vol 4 (3) ◽

Author(s):

Andrii Kulakovskyi ◽

Olivier Mesnil ◽

Bastien Chapuis ◽

Oscar d’Almeida ◽

Alain Lhémery

Keyword(s):

Structural Health Monitoring ◽

Health Monitoring ◽

Minimum Variance ◽

Guided Wave ◽

Localization Accuracy ◽

Structural Health ◽

Defect Interaction ◽

Wave Imaging ◽

Imaging Algorithms ◽

Defect Imaging

Abstract A guided wave-based structural health monitoring (GW-SHM) system aims at determining the integrity of a wide variety of plate-like structures such as aircraft fuselages, pipes, and fuel tanks. It is often based on a sparse grid of piezoelectric transducers for exciting and sensing GWs that under certain conditions interact with damage while propagating. In recent years, various defect imaging algorithms have been proposed for processing GWs signals and, particularly, for computing an image representing the integrity of the studied structure. The performance of the GW-SHM system highly depends on a signal processing methodology. This paper compares defect localization accuracy of the three state-of-art defect imaging algorithms (delay-and-sum, minimum variance, and excitelet) applied to an extensive simulated database of GWs propagation and GWs-defect interaction in aluminum plate under varying temperature and transducers degradation. This study is conducted in order to provide statistical inferences, essential for SHM system performance demonstration.

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A Comparison of Representation Learning Methods for Damage Detection With Guided Wave Structural Health Monitoring

10.1115/1.0002313v ◽

2021 ◽

Author(s):

KANG YANG ◽

Sungwon Kim ◽

Rongting Yue ◽

Joel B. Harley

Keyword(s):

Structural Health Monitoring ◽

Damage Detection ◽

Health Monitoring ◽

Representation Learning ◽

Guided Wave ◽

Learning Methods ◽

Structural Health

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A Scalable Temperature Compensation Method for Guided Wave Based Structural Health Monitoring of Anisotropic CFRP Structures

Lecture Notes in Civil Engineering - European Workshop on Structural Health Monitoring ◽

10.1007/978-3-030-64908-1_50 ◽

2021 ◽

pp. 539-549

Author(s):

Nan Yue ◽

M. H. Aliabadi

Keyword(s):

Structural Health Monitoring ◽

Health Monitoring ◽

Temperature Compensation ◽

Guided Wave ◽

Compensation Method ◽

Structural Health

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Research on the Progress of Interdigital Transducer (IDT) for Structural Damage Monitoring

Journal of Sensors ◽

10.1155/2021/6630658 ◽

2021 ◽

Vol 2021 ◽

pp. 1-10

Author(s):

Wang Ziping ◽

Xiong Xiqiang ◽

Qian Lei ◽

Wang Jiatao ◽

Fei Yue ◽

...

Keyword(s):

Structural Health Monitoring ◽

Health Monitoring ◽

Structural Damage ◽

Large Scale ◽

Safety Information ◽

Health And Safety ◽

Guided Wave ◽

Structural Safety ◽

Structural Health ◽

Damage Monitoring

In the application of Structural Health Monitoring (SHM) methods and related technologies, the transducer used for electroacoustic conversion has gradually become a key component of SHM systems because of its unique function of transmitting structural safety information. By comparing and analyzing the health and safety of large-scale structures, the related theories and methods of Structural Health Monitoring (SHM) based on ultrasonic guided waves are studied. The key technologies and research status of the interdigital guided wave transducer arrays which used for structural damage detection are introduced. The application fields of interdigital transducers are summarized. The key technical and scientific problems solved by IDT for Structural Damage Monitoring (SHM) are presented. Finally, the development of IDT technology and this research project are summarised.

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