| Article ID | Journal | Published Year | Pages | File Type |
|---|---|---|---|---|
| 295280 | NDT & E International | 2012 | 9 Pages |
A semi-analytical solution for evaluation of field distributions around the surface of a conductive half space which contains a hidden long crack and excited by a three-dimensional (3D) current-carrying inducing coil at arbitrary frequency is presented. The governing Helmholtz equation is solved in three dimensions by separation of variables. The solution is obtained by developing a two-dimensional (2D) Fourier series model and using exponential functions in the third dimension. To expand all possible field components in the problem, we assume the conductor as a lossy material. The displacement current in the crack mouth is regarded to have a nonzero value accordingly. After imposing boundary conditions and using the mode matching technique, a linear system of AX=B is solved to obtain the unknown coefficients. The accuracy of the proposed modeling technique is demonstrated by comparing our results with those obtained numerically for a 3D inducing coil.
► Analytical modeling of EM fields around a metal with a hidden long crack. ► Excitation field by an arbitrary-shape wire loop operating at arbitrary frequency. ► Hypothesizing a waveguide partially filled with a lossy dielectric. ► Introducing a TM mode to represent the displacement current in the crack mouth. ► Improving crack detection sensitivity by varying the operating frequency.
