Double-cantilever beams (DCBs) are widely
used to study mode-I fracture behavior and to measure
mode-I fracture toughness under quasi-static loads. Recently, the authors have developed analytical solutions
for DCBs under dynamic loads with consideration of
structural vibration and wave propagation. There are
two methods of beam-theory-based data reduction to
determine the energy release rate: (i) using an effective built-in boundary condition at the crack tip, and
(ii) employing an elastic foundation to model the uncracked interface of the DCB. In this letter, analytical corrections for a crack-tip rotation of DCBs under
quasi-static and dynamic loads are presented, afforded
by combining both these data-reduction methods and
the authors’ recent analytical solutions for each. Convenient and easy-to-use analytical corrections for DCB
tests are obtained, which avoid the complexity and difficulty of the elastic foundation approach, and the need
for multiple experimental measurements of DCB compliance and crack length. The corrections are, to the
best of the authors’ knowledge, completely new. Verification cases based on numerical simulation are presented to demonstrate the utility of the corrections.
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