Analysis of eddy-current interaction with a surface-breaking crack

Harfield, N.; Bowler, John R.

doi:10.1063/1.357259

Cited by 14 publications

(11 citation statements)

References 3 publications

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“…Eddy current testing, for example, as a particular technique of non destructive testing, remains one of the most popular tools in the quality control of conducting test pieces, and an important number of papers in the electric engineering community, mostly based on integral equation techniques, is devoted to numerical methods for crack detection (see e.g. [11,12,14,15,27]). In a typically configuration of eddy current testing, a coil carrying an alternative current is placed in proximity to the conducting test piece.…”

Section: Introductionmentioning

confidence: 99%

Analysis of eddy current formulations in two-dimensional domains with cracks

Lohrengel

Nicaise

2015

ESAIM: M2AN

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In this paper, the eddy current problem in a two-dimensional conductor containing a crack is studied. The decomposition of the electric field into a piecewise regular part and a singular part deriving from scalar potentials localized at the crack tip and at the crack mouth is proved. At the crack mouth, the electric field is shown to have standard singularities inside the conductor, but presents a singularity outside the conductor that does not belong to the classical L 2 -space. Well-posedness of the E-based model and the A − ψ-formulation of combined potentials are proved and an un-gauged discretization of the latter formulation is discussed.

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Section: Introductionmentioning

confidence: 99%

Analysis of eddy current formulations in two-dimensional domains with cracks

Lohrengel

Nicaise

2015

ESAIM: M2AN

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“…The solutions of independent 'face', 'edge' and 'corner' problems together yield that for the crack. While it has recently been shown that the solution of Kahn et al (1977) does indeed arise in the high-frequency limit of a rigorous solution in which decoupling is not assumed at the outset (Harfield & Bowler 1995b) and the impedance change has now been evaluated in closed form rather than numerically (Harfield & Bowler 1994), the solution of this fundamental problem has remained essentially unimproved. The technique introduced in this work improves the solution of Kahn et al (1977) by providing a systematic means by which the coupling between the perturbed fields at the crack edge and mouth can be evaluated.…”

Section: Solved Problemsmentioning

confidence: 99%

“…The second contribution accounts for the fact that the current distribution is non-Laplacian at the edge of the crack (buried in the conductor) and in the corners where the crack meets the conductor surface. The 1122 N. Harfield and J. R. Bowler edge and corner contributions for a crack of finite length have been approximated by Auld (1981) from their exact values for an infinitely long crack in a uniform field (Kahn et al 1977;Harfield & Bowler 1994).…”

Section: Introductionmentioning

confidence: 99%

A geometrical theory for eddy-current non-destructive evaluation

Harfield

Bowler

1997

Proc. R. Soc. Lond. A

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In eddy-current non-destructive evaluation, an electromagnetic field is induced in a metal by means of an eddy-current probe and the presence of a flaw is indicated by a change in probe impedance. In order to predict the impedance change, it is necessary to calculate the electromagnetic field in the region of the flaw. We present a new method, based on the geometrical theory of diffraction, by which approximate analytical solutions for the electromagnetic field near to a crack can be calculated for intermediate and high frequencies. Two-dimensional field solutions are found for (i) a buried crack and (ii) a surface-breaking crack in a conducting half-space. The fields are constructed using solutions which satisfy the field equations exactly but approximate the boundary conditions. The degree to which the predicted fields match the required boundary values on the plane of the crack and the air-conductor interface plane is assessed and very good agreement is obtained for cracks whose edges lie half a skin-depth or more below the conductor surface. The impedance change due to the crack is calculated in closed form.

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“…There have been several studies of simulating scattering of eddy-currents from cracks in a conducting half-space during recent decades, see Auld and Moulder. 4 Harfield and Bowler 5 give a closed form expression for the change in electromagnetic impedance of a conductor due to the presence of an infinitely long, perpendicular surface-breaking crack in a normally incident, uniform electric field. The perturbed electromagnetic field was more accurately calculated using Wiener-Hopf technique than Auld et al 6 A similar problem is considered by Kahn et al 7 Harfield and Bowler 8 develop a method based on geometrical theory of diffraction (GTD) for eddy-current nondestructive evaluation.…”

Section: Introductionmentioning

confidence: 99%

Integral equation method for evaluation of eddy-current impedance of a tilted, surface-breaking crack

Larsson

Boström

Bövik

et al. 2013

Journal of Applied Physics

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An integral equation method for solving the eddy-current nondestructive evaluation problem for a flat, tilted, and surface-breaking crack in a conducting half-space is presented. The method involves use of a half-space Green's tensor and the Bowler potential. This potential describes the jump in the electric field over the crack and is expanded in basis functions related to the Chebyshev polynomials, being a more analytical approach than the commonly used boundary element method. In the method, the scatterer defines a transformation operator to be applied on the incoming field. This is practical in simulations of the eddy-current inspection where this operator is independent of the position of the probe. The numerical calculations of the change in impedance due to the crack are compared to a Finite Element model of the problem and good agreement is found. V

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Analysis of eddy-current interaction with a surface-breaking crack

Cited by 14 publications

References 3 publications

Analysis of eddy current formulations in two-dimensional domains with cracks

Analysis of eddy current formulations in two-dimensional domains with cracks

A geometrical theory for eddy-current non-destructive evaluation

Integral equation method for evaluation of eddy-current impedance of a tilted, surface-breaking crack

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