Application of a √ area -Approach for Fatigue Assessment of Cast Aluminum Alloys at Elevated Temperature

This paper contributes to the effect of elevated temperature on the fatigue strength of common aluminum cast alloys EN AC-46200 and EN AC-45500. The examination covers both static as well as cyclic fatigue investigations to study the damage mechanism of the as-cast and post-heat-treated alloys. The...

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Bibliographic Details
Published in:Metals (Basel ) 2018-12, Vol.8 (12), p.1033
Main Authors: Aigner, Roman, Garb, Christian, Leitner, Martin, Stoschka, Michael, Grün, Florian
Format: Article
Language:English
Subjects:
Aluminum base alloys
aluminum cast
Casting alloys
Casting defects
Cooling
Crack initiation
Crack propagation
defects
elevated temperature
Fatigue failure
Fatigue strength
Fatigue tests
Fracture surfaces
hardness
Heat
Heat treatment
High temperature
Investigations
Mechanical properties
Operating temperature
Room temperature
Silicon
Temperature
tensile tests
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Summary:This paper contributes to the effect of elevated temperature on the fatigue strength of common aluminum cast alloys EN AC-46200 and EN AC-45500. The examination covers both static as well as cyclic fatigue investigations to study the damage mechanism of the as-cast and post-heat-treated alloys. The investigated fracture surfaces suggest a change in crack origin at elevated temperature of 150 ∘ C. At room temperature, most fatigue tests reveal shrinkage-based micro pores as their crack initiation, whereas large slipping areas occur at elevated temperature. Finally, a modified a r e a -based fatigue strength model for elevated temperatures is proposed. The original a r e a model was developed by Murakami and uses the square root of the projected area of fatigue fracture-initiating defects to correlate with the fatigue strength at room temperature. The adopted concept reveals a proper fit for the fatigue assessment of cast Al-Si materials at elevated temperatures; in detail, the slope of the original model according to Murakami should be decreased at higher temperatures as the spatial extent of casting imperfections becomes less dominant at elevated temperatures. This goes along with the increased long crack threshold at higher operating temperature conditions.
ISSN:2075-4701
2075-4701
DOI:10.3390/met8121033