Experimental setup for measuring the mechanical behavior of loaded thin compliant joints with highest precision
Abstract
Compliant mechanisms with flexure hinges represent a defining element of many precision devices in various fields of science and technology. Due to their importance, the ability of
modeling their behavior with high precision represents the key for a further enhancement of their
performance. The present scientific work contributes to the experimental verification of distinct
mechanical models for thin semicircular flexure hinges. For this purpose an experimental setup for
the load application on the hinge has been developed, designed and set up. The device is designed
to precisely determine the rotational stiffness of thin flexure hinges in their elastic range
with a minimal notch height of 50, 75 and 100 ➭m, but can be applied in a wider context in other
applications as well. Two sets of hinges were analyzed, both manufactured by wire EDM in different
companies. Although both sets were made with the same geometric dimensions, pronounced
differences in their stiffness were measured. It is demonstrated that manufacturing has a large
impact on the stiffness of the hinges because it affects the resulting geometry in the microscopic
scale. The experimental results for one of the hinge sets are in good agreement with the
calculations using the finite element method. Further research is required to confirm this trend.
This would provide solid evidence for the invalidity of existing analytical stiffness equations for
flexure hinges in the considered thickness range.
Temas
Uniones--Experimentos
Uniones--Elasticidad
Uniones--Elasticidad
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Maestro en Ingeniería Mecatrónica
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