The following dissertation details the development of a simple defect-tolerant based
model for determining the fatigue properties of a 5383-H321 aluminium alloy and metal
inert gas and friction stir welded butt joints in the same alloy. The model considers the
fatigue life to consist of three regimes, crack initiation and short and long crack growth, in
contrast to the typical defect-tolerant approaches which only consider the long crack
growth period.
Crack initiation was considered to consist of an initial short crack, present prior to fatigue
loading, identical in length to the crack initiator. The short crack growth rate was
considered to be a function of the crack length and stress amplitude, whilst the long crack
growth regime was described through the Paris equation, dcldN = C(AK)m. The model
also considers the effect on the crack initiation and growth rates of the microstructure,
macrostructure and residual stresses, with the latter being determined both through the
conventional hole-drilling approach and the emerging technique of synchrotron strain
scanning.
The accuracy of the model was verified through integration of the short and long crack
growth regimes, with the predicted lifespan being compared to results obtained from S-N
testing of identical welded specimens. A good correlation between the experimental and
theoretical results was observed for the parent material and friction stir welded joints for
lives in the region 105-106 cycles, although the approach, in its current format, appeared
less suitable for determining the fatigue properties of the MIG welded joints.
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Date of Award | 2003 |
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Original language | English |
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Awarding Institution | |
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Sponsors | Corus Research, Development and Technology |
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Fatigue properties of metal inert gas and friction stir welded aluminium alloy 5383-H321
Bradley, G. R. (Author). 2003
Student thesis: PhD