Structural Coupled Electromagnetic Sensing of Defects Diagnostic System

Ru, Gaige; Gao, Bin; Liu, D.; Ma, Qiuping; Li, Haoran; Woo, Wai Lok

doi:10.1109/tie.2022.3148755

Cited by 24 publications

(3 citation statements)

References 35 publications

(29 reference statements)

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“…The voltage source provides alternating current for the excitation coil. Under the action of alternating current, the excitation coil generates an excitation magnetic field [35,36]. The excitation coil and the induction coil are resonantly coupled.…”

Section: Theorymentioning

confidence: 99%

Working Stress Measurement of Prestressed Rebars Using the Magnetic Resonance Method

et al. 2023

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Prestressed rebars are usually used to apply vertical prestress to concrete to prevent web cracking. The reduction of working stress will affect the durability of the structure. However, the existing working stress detection methods for prestressed rebars still need to be improved. To monitor the working stress of rebars, a magnetic resonance sensor was introduced to carry out experimental research. The correlation between rebar stress and the sensor’s induced voltage was theoretically analyzed using the magnetoelastic effect and magnetic resonance theory. A working stress monitoring method for prestressed rebars based on magnetic resonance was proposed. Working stress monitoring experiments were carried out for 16 mm, 18 mm, and 20 mm diameter rebars. The results showed that the induced voltage peak-to-peak value and the rebar prestress were nonlinearly correlated under different working conditions. Correlations between the characteristic indicators and the rebar working stress were obtained using nonlinear and linear fit. The cubic polynomial segmented fit outperformed the gradient overall linear fit, with the goodness of fit R2 greater than 0.96. The average relative error values of working stress monitoring were less than 5% under different working conditions. This provides a new method for working stress measurement of vertical prestressed rebars.

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Section: Theorymentioning

confidence: 99%

Working Stress Measurement of Prestressed Rebars Using the Magnetic Resonance Method

et al. 2023

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“…Pipelines are the key infrastructure for transferring natural gas and oil from producing areas to refineries, chemical plants, home consumers, and other business requirements, which formed the largest pipeline network in the world. , However, the pipeline could be damaged by human vandalism or natural hazards. − Furthermore, due to corrosion and metal loss, the pipeline leakage is responsible for 5% of major industrial accidents and causes serious environmental problems. , Therefore, rapid repair with lower cost and time consumption for pipeline leakage in outdoor environments without electricity and heat supply is the key issue that should be resolved . Moreover, the detection of different defects is challenging for nondestructive testing (NDT) in pipeline integrity diagnosis. − Strikingly, polymer adhesives and polymer-based flexible sensing devices possess high potential utilization for repairing metallic pipes and defect detection …”

Section: Introductionmentioning

confidence: 99%

Low-Temperature Rapid Polymerization of Intrinsic Conducting PAD/OC Hydrogels with a Self-Adhesive and Sensitive Sensor for Outdoor Damage Repair and Detection

Liu,

Chen,

Zhang

2024

ACS Appl. Mater. Interfaces

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Intrinsic conducting hydrogels fabricated in situ at low temperatures with self-adhesive properties and excellent flexibility hold significant promise for energy applications and outdoor damage repair. However, challenges such as low polymerization rate and self adhesion, insufficient ionic conductivity, inflexibility, and poor stability under extreme cold conditions have hindered their utilization as high-performance sensors. In this study, we designed an intrinsic conducting hydrogel (PADOC) composed of acrylic acid, acryloyloxyethyltrimethylammonium chloride, N,N′-methylenebis(2-propenamide), self-fabricated oxidized curdlan (OC), and a water/glycerol binary solvent. The novel hydrogel exhibited rapid gelation (30 s) at 0 °C facilitated by the promotion of OC, without the need for external energy input. Our findings from FT-IR, NMR, XPS, XRD, EPR spectra, MS, and DSC analyses revealed that OC underwent selective oxidation via the evolved Fenton reaction at 30 °C, serving as bioaccelerators for PAD polymerization. Due to OC's reductive structure and increased solubility, the reaction activation energy of the PAD polymerization reaction significantly reduced from 103.2 to 54.4 kJ/mol. PADOC ionic hydrogels demonstrated an electrical conductivity of 1.00 S/m, 0.7% low hysteresis, 39.6 kPa self-adhesive strength, and 923% strain-at-break and kept even at −20 °C owing to dense hydrogen and ionic bonds between PAD and OC chains. Furthermore, PADOC ionic hydrogels exhibited antifatigue properties for 10 cycles (0−100%) due to electrostatic interactions and hydrogen bonding. Remarkably, using a selfdesigned device, the rapid polymerization of PADOC effectively repaired copper pipeline leakage under 86 kPa pressure and detected 1% strain variation as a strain sensor. This study opens a new avenue for the rapid gelation of self-adhesive and flexible intrinsic conducting hydrogels with robust sensor performance.

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“…Magnetic flux leakage detection is a popular non-destructive method, and when using this method, it is easy to obtain signals [9]. The theoretical basis of magnetic flux leakage is that the pipeline is magnetically saturated under the external magnetic field, and a magnetic leakage can be detected at the defective location; however, there are still limitations in terms of insensitivity to cracks that are parallel to the direction of magnetization [10]. Therefore, a new type of sensor that is non-destructive, easy to fabricate, highly sensitive, and highly durable is needed.…”

Section: Introductionmentioning

confidence: 99%

Flexible Mica-Based PZT Sensor for Real-Time Monitoring of the Airflow

Miao

Zhai

et al. 2023

Crystals

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Pipeline leakage causes enormous safety and economic concerns; therefore, sensors which are high-performance and durable are in high demand for improving monitoring accuracy and for avoiding economic loss. In this work, mica-based flexible PZT sensors showed high sensitivity, with 140 mV N−1 and 467 mV N−1 for the output voltage, with regard to the tapping and bending modes, respectively. They can monitor airflow in normal conditions with high sensitivity and a linearity of 424 mV MPa−1 and 0.99, respectively. In the event of a pipeline leak, the mica-based sensors exhibited a rapid response time as short as 0.578 s. Furthermore, they generated distinct voltage levels at different distances from the leakage point, thus providing valuable information for accurately locating the source of the leakage.

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Structural Coupled Electromagnetic Sensing of Defects Diagnostic System

Cited by 24 publications

References 35 publications

Working Stress Measurement of Prestressed Rebars Using the Magnetic Resonance Method

Working Stress Measurement of Prestressed Rebars Using the Magnetic Resonance Method

Low-Temperature Rapid Polymerization of Intrinsic Conducting PAD/OC Hydrogels with a Self-Adhesive and Sensitive Sensor for Outdoor Damage Repair and Detection

Flexible Mica-Based PZT Sensor for Real-Time Monitoring of the Airflow

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