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Experimental Mechanics @
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EM Basics: Caustics |
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Caustic from mode I crack. |
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Basic principles:
The shadow optical method of caustics is an experimental technique
which may be used in stress concentration problems and is particularly useful
in the determination of stress intensity factors. The figure shows a
transparent plate in tension containing a mode I crack. The singular stresses
at the crack tip cause: (1) a reduction in thickness due to Poisson's Ratio
effects (2) a change in the refractive index. If light is incident on the
plate, both the thickness and the refractive index influence the light rays
as the light passes through the plate. If a screen is placed at some distance
from the specimen, the light pattern may be viewed. The light concentration
is a caustic curve and the shadow area is known as the shadow spot.
This diagram is in two dimensions. In reality the rays form a three
dimensional envelope of light which is cut by a two dimensional screen or
reference plane in order to view the caustic. This light deflection due to a
stress field is the main principle behind the method of caustics. Since the
shape and size of the caustic are caused by light deflections, which are due
to the change in thickness and refractive index of the material; and these
are due to the stress singularity; then the caustic shape is related directly
to the singularity and therefore can be related to parameters such as the
stress intensity factor. The method of caustics may be used in any
engineering problem where a steep stress gradient exists. Examples of these
include crack tip analysis, contact mechanics and stress concentrations
around holes. |
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