As magnetic particle testing (MT) detects microcracks using a simplified method, it is used for the non-destructive inspection of steel materials in various industrial fields. In non-destructive inspections, the ability to both assess the influence of a detected crack on a test object and quantitatively evaluate the crack dimensions is necessary. However, a quantitative technique for evaluating the crack dimensions (in particular, depth and width) has not been established in conventional MT. Then, we processed multiple test objects with various crack depths and widths and used a high-speed video camera to characterize the process by which the magnetic particles indicate the cracks. As a result, we developed a technique for estimating the crack dimensions on the basis of the adhered magnetic particles observed in MT. In previous study, evaluation was conducted under ideal conditions of MT where the crack and the magnetization directions are perpendicular. However, because the crack cannot be visually detected in actual field inspections, the direction of the crack is not understood beforehand. In this study, we assessed the adhesion of magnetic particles to surface-breaking cracks under varying magnetization directions, and explored its applicability for quantitative crack evaluation.
Katsuhiro Fukuoka (Sun,) studied this question.