An Equivalent-Effect Phenomenon in Eddy Current Non-Destructive Testing of Thin Structures

Yin, Wuliang; Tang, Jiawei; Lü, Mingyang; Xu, Hanyang; Huang, Ruochen; Zhao, Qian; Zhang, Zhijie; Peyton, Anthony

doi:10.1109/access.2019.2916980

Cited by 30 publications

(28 citation statements)

References 24 publications

(18 reference statements)

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“…In (1) and (2),

and

vary with the frequency

of the exciting current and coating thickness

is the variable of integration, which is related to the wavenumber of the incident transverse electric (TE) planar electromagnetic wave [ 47 , 48 , 51 , 52 ].

is the material-dependent phase term for the mutual inductance.…”

Section: Analytical Algorithmsmentioning

confidence: 99%

Evaluation of Coating Thickness Using Lift-Off Insensitivity of Eddy Current Sensor

Meng

Lü

Yin

et al. 2021

Sensors

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Defect detection in ferromagnetic substrates is often hampered by nonmagnetic coating thickness variation when using conventional eddy current testing technique. The lift-off distance between the sample and the sensor is one of the main obstacles for the thickness measurement of nonmagnetic coatings on ferromagnetic substrates when using the eddy current testing technique. Based on the eddy current thin-skin effect and the lift-off insensitive inductance (LII), a simplified iterative algorithm is proposed for reducing the lift-off variation effect using a multifrequency sensor. Compared to the previous techniques on compensating the lift-off error (e.g., the lift-off point of intersection) while retrieving the thickness, the simplified inductance algorithms avoid the computation burden of integration, which are used as embedded algorithms for the online retrieval of lift-offs via each frequency channel. The LII is determined by the dimension and geometry of the sensor, thus eliminating the need for empirical calibration. The method is validated by means of experimental measurements of the inductance of coatings with different materials and thicknesses on ferrous substrates (dual-phase alloy). The error of the calculated coating thickness has been controlled to within 3% for an extended lift-off range of up to 10 mm.

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“…In (1) and (2),

and

vary with the frequency

of the exciting current and coating thickness

is the variable of integration, which is related to the wavenumber of the incident transverse electric (TE) planar electromagnetic wave [ 47 , 48 , 51 , 52 ].

is the material-dependent phase term for the mutual inductance.…”

Section: Analytical Algorithmsmentioning

confidence: 99%

Evaluation of Coating Thickness Using Lift-Off Insensitivity of Eddy Current Sensor

Meng

Lü

Yin

et al. 2021

Sensors

Self Cite

View full text Add to dashboard Cite

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“…is the fixed distance between the transmitter and receiver along − axis. α and α 1 are related to the wavenumber of the EM plane wave of Transverse electric (TE) mode [17] in the free space and test piece, respectively. α = √ 2 + 2 (5) (3) and h( , )e j( r + ) in (4) are the Fourier transform of the free-space magnetic scalar potential generated by the driving transmitter and pick-up receiver respectively, with h( , ) defined as the following expression.…”

Section: A Original Formulas Of Thin-skin Regime -Mutual-impedance Omentioning

confidence: 99%

Determination of Surface Crack Orientation Based on Thin-Skin Regime Using Triple-Coil Drive-Pickup Eddy-Current Sensor

Lü

Meng

Huang

et al. 2020

Preprint

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Electromagnetic sensors have been used for inspecting small surface defects of metals. Based on the eddy-current thin-skin regime, a revised algorithm is proposed for a triple-coil drive-pickup eddy-current sensor scanning over long surface crack slots (10 mm) with different rotary angles. The method is validated by the voltage measurement of the designed EC sensor scanning over a benchmark (ferromagnetic) steel with surface defects of different depths and rotary angles. With an additional sensing coil for the designed EC sensor, the defect angle (or orientation) can be measured without spatially and coaxially rotating the excitation coil. By referring to the voltage change (due to the defect) diagram (voltage sum versus voltage different) of two sensing pairs, the rotary angle of the surface crack is retrieved with a maximum residual deviation of 3.5 %.

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“…After picked up by the receiving coil, the secondary magnetic field induces electric current which would finally be measured by the impedance analyzer. The eddy current sensor is widely used in non-destructive test [10]- [12] due to non-contact, fast measuring, and economical devices. In [13]- [15], eddy current sensors are utilized to measure the conductivity.…”

Section: Introductionmentioning

confidence: 99%

A Novel Conductivity Classification Technique for Non-Magnetic Tilting Metals by Eddy Current Sensors

Zhang

Yin

et al. 2020

IEEE Access

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The classification of conductivity is significant for recycling metallic scraps. The eddy current sensor is distinct from other classification methods by its merits of non-contact, economical setup , fast measuring, and so forth. By introducing a setup that could ensure the single-valued mutual inductance trajectory on the complex plane, we propose the circle fitting method to extract the global features of different trajectories. It is subsequently observed that the fitting circle centers-one of the global featuresfor the same conductivity with various tilting angles are distributed longitudinally close to each other. The feature line, which is parallel to the abscissa axis, is introduced to represent this gathering distribution behavior. The feature lines for different conductivity are distinguishable. Thus, we construct a simple classification method with only two steps. The test results show great fidelity of the proposed classification technique which can successfully classify the tilting metallic samples within 11.3 • .

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An Equivalent-Effect Phenomenon in Eddy Current Non-Destructive Testing of Thin Structures

Cited by 30 publications

References 24 publications

Evaluation of Coating Thickness Using Lift-Off Insensitivity of Eddy Current Sensor

Evaluation of Coating Thickness Using Lift-Off Insensitivity of Eddy Current Sensor

Determination of Surface Crack Orientation Based on Thin-Skin Regime Using Triple-Coil Drive-Pickup Eddy-Current Sensor

A Novel Conductivity Classification Technique for Non-Magnetic Tilting Metals by Eddy Current Sensors

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