Crack initiation and propagation of cast A356 aluminum alloy under multi-axial cyclic loadings

Mechanical fatigue tests were conducted on specimens of A356-T6 casting alloys under uniaxial and multi-axial cyclic loadings. SEM and quantitative metallography technique were used to examine fracture surfaces and statistically to analyze particle cracking after fatigue tests, respectively. The existence of casting defects has considerable influence on fatigue behavior, and the dominant fatigue crack preferentially nucleates from porosity and oxide films near the outside surface of the specimen. In the absence of these defects, the crack nucleation occurs from the large and cracked eutectic silicon particles. The number of cracked particles increases with the number of fatigue cycles, but the damage rate depends on the particular loading paths. Large and elongated particles with their major axes parallel to the tensile axis show the greatest tendency to cracking. The cracks in particles can be regarded as micro-cracks in this material which can coalesce together and provide a weak path for fatigue crack propagation. Final fracture occurs when the percentage of cracked particles increases to a threshold level during the fatigue process, over 50 pct in this study.

[1]  David L. McDowell,et al.  Computational micromechanics analysis of cyclic crack-tip behavior for microstructurally small cracks in dual-phase Al–Si alloys , 2001 .

[2]  J. Griffiths,et al.  Damage by eutectic particle cracking in aluminum casting alloys A356/357 , 2003 .

[3]  Peter D. Lee,et al.  Scatter in fatigue life due to effects of porosity in cast A356-T6 aluminum-silicon alloys , 2003 .

[4]  A. Gokhale,et al.  Relationship between microstructural extremum and fracture path in a cast Al-Si-Mg alloy , 1997 .

[5]  David L. McDowell,et al.  On the driving force for fatigue crack formation from inclusions and voids in a cast A356 aluminum alloy , 2001 .

[6]  A. Wickberg,et al.  Microstructural Effects on the Fatigue Properties of a Cast Al7SiMg Alloy , 1984 .

[7]  R. Fournelle,et al.  Effect of strontium modification on near- threshold fatigue crack growth in an Al-Si-Cu die cast alloy , 1996 .

[8]  David L. McDowell,et al.  Microstructure-based fatigue modeling of cast A356-T6 alloy , 2003 .

[9]  J. R. Griffiths,et al.  CASTING DEFECTS AND THE FATIGUE BEHAVIOUR OF AN ALUMINIUM CASTING ALLOY , 1990 .

[10]  F. V. Lawrence,et al.  MODELING THE LONG‐LIFE FATIGUE BEHAVIOR OF A CAST ALUMINUM ALLOY , 1993 .

[11]  Fan,et al.  The influence of modified intermetallics and Si particles on fatigue crack paths in a cast A356 Al alloy , 2000 .

[12]  D. McDowell,et al.  The debonding and fracture of Si particles during the fatigue of a cast Al-Si alloy , 1999 .

[13]  D. Koss,et al.  Porosity and crack initiation during low cycle fatigue , 1990 .

[14]  Ding,et al.  Small‐crack growth and fatigue life predictions for high‐strength aluminium alloys. Part II: crack closure and fatigue analyses , 2000 .

[15]  Diran Apelian,et al.  Fatigue behavior of A356/357 aluminum cast alloys. Part II – Effect of microstructural constituents , 2001 .

[16]  P. Forsyth Fatigue damage and crack growth in aluminium alloys , 1963 .

[17]  D. Apelian,et al.  Fatigue behavior of A356-T6 aluminum cast alloys. Part I. Effect of casting defects , 2001 .

[18]  Bjørn Skallerud,et al.  Fatigue life assessment of aluminum alloys with casting defects , 1993 .

[19]  Kazuaki Shiozawa,et al.  CRACK INITIATION AND SMALL FATIGUE CRACK GROWTH BEHAVIOUR OF SQUEEZE‐CAST Al‐Si ALUMINIUM ALLOYS , 1997 .

[20]  F. Samuel,et al.  Effect of silicon particles on the fatigue crack growth characteristics of Al-12 Wt Pct Si-0.35 Wt Pct Mg-(0 to 0.02) Wt Pct Sr casting alloys , 1995 .