castings consists of two parts: fatigue crack initiation life and fatigue crack propagation life, which can be further divided into short and long fatigue


2


Procedure At GM, MSF models


have been developed to predict fatigue life of cast aluminum components


with various degrees of porosity, oxide levels and microstructural features. When pore and oxide sizes are larger than competing microstructural weak links (such as eutectic silicon particles), crack initiation life can be ignored. However, when the flaw size in the casting approaches the microstructural feature size (~25-50 µm), crack initia- tion life from microstructural con- stituents such as persistent slip bands can dominate the total fatigue life.


crack propagation life. Te research- ers reviewed the latest understand- ing in fatigue crack initiation, crack propagation and life prediction with


Fatigue cracks usually initiate from flaws in aluminum castings. In coarse microstructures, the dendrite cell walls act as grain boundaries because they are surrounded by a nearly continuous array of eutectic particles. Te researchers applied MSF models to estimate the fatigue life of cast alu- minum alloys A356 and 319. Tey used extreme values of the characteristic flaw and microstructure features that were assumed to have nominal value (50% probability) and 99.94% (+3 standard deviations) probability of occurrence. A comparison of the calculated propagation life based on both long


special emphasis on the influences of short cracks and the uncertainty of multiscale flaws and microstructure constituents.


and short crack models with empiri- cally derived constants to actual fatigue life (Nf) was made. Te calculated crack propagation life (Np) was in good agreement with the actual fatigue life. Tis indicated the total fatigue life of cast 319 alloys failing from porosity is mainly comprised of crack propaga- tion and the assumed initiation life near zero is reasonable. Compared to the short crack model, the long crack model is simpler and fits the data over the useful life range of most compo- nents. Given the inherent scatter in fatigue life data, predictions within an order of magnitude of measured


Fig. 1. A fatigue crack was initiated from porosity in a sand-cast A356-T6 casting. (Image was taken using secondary electron imaging.)


Fig. 2. This fatigue crack was initiated from an (old) oxide film in a sand-cast A356-T6 casting. (Image was taken using secondary electron imaging.)


Fig. 3. Fatigue cracks were initiated from (left) fractured and (right) debonded eutectic particles in a sand-cast A356-T6 casting. (Images were taken using secondary electron imaging.)


May/Jun 2013 | METAL CASTING DESIGN & PURCHASING | 39


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