Abstract
The fatigue crack retardation mechanisms operating after an overload event are investigated for a bainitic steel using high spatial resolution energy dispersive synchrotron X-ray diffraction. The elastic crack-tip strain fields are mapped at mid-thickness of compact tension samples at R-ratios of 0.1 and 0.4. The same overload stress intensity factor (KOL = 60 MPa m1/2) is applied in each case with the cracks then propagating under the same applied stress intensity range, ΔKapp = 27 MPa m1/2. The competing retardation mechanisms are directly quantified and separated, with the associated fatigue crack growth (FCG) rates then being predicted according to a 2-parameter Walker-type assessment and validated against those measured. The stress intensity factor associated with the overload residual stress field is calculated using a weight function approach. For R=0.1, shielding from residual stress controls retardation when crack growth through the overload plastic zone, rpOL, is small (specifically <0.6rpOL). For more extensive crack growth, discontinuous crack closure controls the retardation behaviour, with significant load transfer across opposing crack faces being observed at minimum load (for R=0.1). These crack face tractions are associated with the plastic asperity created during overload. The traction forces holding the crack faces open at minimum load are, for the first time, used to directly quantify the associated stress intensity factor, Kmintract as a function of crack growth. While no crack shielding is expected, nor observed, for R=0.4, the variation in FCG rate after overload is explained by changes in effective R-ratio.
Highlights
Subcritical fatigue crack growth (FCG) is conventionally understood according to linear elastic fracture mechanics (LEFM), which provides us with parameters such as the stress intensity factor, K, that characterise the conditions experienced at the crack-tip
This is considered to be a useful measure of the crack position, when normalised against the overload plastic zone size, rOL. This is a convenient, and generalised, app proach to defining the extent and impact of overload retardation mechanisms (e.g. a/rOL = 1 p should indicate when the crack has grown through the residual stress field introduced by the overload)
We have considered the impact of overload and R-ratio on residual stress, closure mechanisms and thereby FCG retardation in a bainitic steel
Summary
Subcritical fatigue crack growth (FCG) is conventionally understood according to linear elastic fracture mechanics (LEFM), which provides us with parameters such as the stress intensity factor, K, that characterise the conditions experienced at the crack-tip. These parameters are defined by direct, accessible macroscale measurements of variables such as the applied load, P app, sample geometry and crack length. This serves as a convenient and, broadly speaking, reliable method by Preprint submitted to Journal of the Mechanics and Physics of Solids the e↵ective stress intensity factor range, Keff.
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