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- Title
Digital image correlation measurement of near-tip fatigue crack displacement fields: constant amplitude loading and load history effects.
- Authors
NOWELL, D.; KARTAL, M. E.; DE MATOS, P. F. P.
- Abstract
ABSTRACT Recent work by de Matos and colleagues employed digital image correlation to measure near tip displacement fields for fatigue cracks in 6082 T6 aluminium alloy. The main focus of this work was to directly measure fatigue crack closure, but the measurements can also be used to examine conditions at and ahead of the crack tip. In this paper, the results are re-analysed and compared to two crack-tip deformation models. The first assumes simple elastic deformation (according the Westergaard solution). This allows the history of crack-tip stress intensity to be examined. Reasonable agreement with the elastic model is obtained, although there is a residual stress intensity caused by the plastic wake, which gives rise to crack closure. The second model examined is a simple elastic-plastic assumption, proposed by Pommier and colleagues. This can be applied to constant amplitude loading, although the results obtained here are very similar to the elastic case. A slightly more complex load case (a single overload in an otherwise constant amplitude variation of load) gives a much more complicated crack-tip history. Here, the importance of crack-tip plastic displacement, represented by the second term in Pommier's model becomes much clearer. Load history effects are captured by the residual value of this term and its associated displacement fields as well as by stress intensity factor. The implications for further modelling and experimental work are discussed.
- Subjects
MATERIAL fatigue; DIGITAL image correlation; CRACK propagation (Fracture mechanics); DISPLACEMENT (Mechanics); ALUMINUM alloys; ELASTIC deformation; STRESS intensity factors (Fracture mechanics); CRACK closure
- Publication
Fatigue & Fracture of Engineering Materials & Structures, 2013, Vol 36, Issue 1, p3
- ISSN
8756-758X
- Publication type
Article
- DOI
10.1111/j.1460-2695.2012.01707.x