The effect of solidification rate and chemicalcomposition (different Fe andMn) content on microstructure, tensile and fatigue properties of the Al–10%Si–2%Cu casting alloy was investigated. A special apparatus was used to produce cast specimens under controlled solidification conditions, in order to obtain two values of the secondary dendrite arm spacing (SDAS), equal to about 10 and 50m. Microstructural characterization of the alloy was carried out by optical and scanning electron microscopy, to evaluate the effect of cooling rate and chemical composition on solidification defects and others microstructural features, such as SDAS aswell as morphology and composition of the Fe-rich intermetallic compounds. In the samples with high-Fe content these compounds were mainly -(Al5FeSi), with their typical needlelike morphology, while also the -(Al15(Fe,Mn)3Si2) and -(Al8FeMg3Si6) phases, with a Chinese-script morphology, were observed in the samples containing Mn. High cooling rate induced a reduction of the SDAS, aswell as of the volume fraction and size of the solidification defects, with a consequent important increase of the tensile and fatigue properties. Microstructural factors, such as shape and composition of the Fe-rich intermetallic compounds, only influenced the tensile and fatigue response of the specimens with the lower SDAS and smaller solidification defects. The chemical composition had a negligible effect on tensile strength (UTS, YS), while it influenced the elongation to failure, that was significantly lower in the alloy with the larger volume fraction of Fe-rich intermetallics. The presence of high volume fraction of these intermetallics also increased the fatigue resistance at high applied stress, while it decreased the cycles to failure at low applied stress.
L. Ceschini, I. Boromei, A. Morri, Salem Seifeddine, Ingvar L. Svensson (2009). Microstructure, tensile and fatigue properties of the Al-10%Si-2%Cu alloy with different Fe and Mn content cast under controlled conditions. JOURNAL OF MATERIALS PROCESSING TECHNOLOGY, 209, 5669-5679 [10.1016/j.jmatprotec.2009.05.030].
Microstructure, tensile and fatigue properties of the Al-10%Si-2%Cu alloy with different Fe and Mn content cast under controlled conditions
CESCHINI, LORELLA;BOROMEI, IURI;MORRI, ALESSANDRO;
2009
Abstract
The effect of solidification rate and chemicalcomposition (different Fe andMn) content on microstructure, tensile and fatigue properties of the Al–10%Si–2%Cu casting alloy was investigated. A special apparatus was used to produce cast specimens under controlled solidification conditions, in order to obtain two values of the secondary dendrite arm spacing (SDAS), equal to about 10 and 50m. Microstructural characterization of the alloy was carried out by optical and scanning electron microscopy, to evaluate the effect of cooling rate and chemical composition on solidification defects and others microstructural features, such as SDAS aswell as morphology and composition of the Fe-rich intermetallic compounds. In the samples with high-Fe content these compounds were mainly -(Al5FeSi), with their typical needlelike morphology, while also the -(Al15(Fe,Mn)3Si2) and -(Al8FeMg3Si6) phases, with a Chinese-script morphology, were observed in the samples containing Mn. High cooling rate induced a reduction of the SDAS, aswell as of the volume fraction and size of the solidification defects, with a consequent important increase of the tensile and fatigue properties. Microstructural factors, such as shape and composition of the Fe-rich intermetallic compounds, only influenced the tensile and fatigue response of the specimens with the lower SDAS and smaller solidification defects. The chemical composition had a negligible effect on tensile strength (UTS, YS), while it influenced the elongation to failure, that was significantly lower in the alloy with the larger volume fraction of Fe-rich intermetallics. The presence of high volume fraction of these intermetallics also increased the fatigue resistance at high applied stress, while it decreased the cycles to failure at low applied stress.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.