Normal surface displacement around a circular hole by reflection holographic interferometry

Abstract

In a previous paper1, a fringe-compensation technique was developed to improve the possibilities of stress analysis by real-time holographic interferometry. The technique is specially well suited for the measurement of small displacements in the direction of viewing. As an application of this method, the surface displacements caused by strains in the thickness direction are measured around a circular hole in a plate loaded in tension in its plane. Independent prior knowledge of the in-plane displacement is required, however, in data processing. An analytical solution to the problem is used for that purpose. The experimental results are compared to those obtained theoretically from the classical two-dimensional analysis, and from a three-dimensional analysis. The two-dimensional theory assumes a state of ‘generalized plane stress’. The three-dimensional theory, made by Alblas2, takes into account the existence of stresses in the thickness direction, and the variation of the in-plane stresses through the thickness. Both theories give the same results away from the hole. They differ significantly, however, when the hole boundary is approached, where the proximity of the hole induces three-dimensional effects. The experimentally measured displacement is found to be in good agreement with both theories away from the hole. Close to the hole, a large departure from the two-dimensional results is observed. The experimental results here are close to those of three-dimensional results. The experiment is thus in good agreement with the three-dimensional theory over the whole field. But the two-dimensional theory is valid only at large distances from the hole.