Microstructure evolution of cast Al-Si-Cu alloys in solution treatment

Dingfei Zhang; Jian Peng; Guangjie Huang; Dingding Zeng

doi:10.1007/s11595-006-2184-5

Journal of Wuhan University of Technology Materials Science Edition ›› 2008, Vol. 23 ›› Issue (2) : 184 -188. DOI: 10.1007/s11595-006-2184-5

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Microstructure evolution of cast Al-Si-Cu alloys in solution treatment

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Abstract

To develop a software to predict the evolution of microstructure and the development of mechanical properties during the heat treatment of cast aluminum alloys, we modeled the redistribution of solute during the solution treatment of multicomponent alloys. The predictions of solidifi cation simulation software or the results of experiment provided the initial microstructure and solute distribution for simulation of heat treatment. Binary through quinary aluminum alloys with silicon, copper, magnesium, and iron were modeled. The basic model assumed local equilibrium (no undercooling due to nucleation or growth) and computed diffusion in the solid constituents during solidification. The evolution of microstructure during solution treatment was followed by qualitative and quantitative metallography. The results of simulation for the ternary alloy Al-7%Si-3.5%Cu were compared to experimental observation.

Keywords

Al-Si-Cu alloys / solution treatment / microstructure / simulation

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Dingfei Zhang, Jian Peng, Guangjie Huang, Dingding Zeng. Microstructure evolution of cast Al-Si-Cu alloys in solution treatment. Journal of Wuhan University of Technology Materials Science Edition, 2008, 23(2): 184-188 DOI:10.1007/s11595-006-2184-5

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References

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[1]	Byczynski G. E., Kierkus F. The Effect of Quench Rate on Mechanical-properties of 319-Aluminum-alloy Castings[J]. Materials Science Forum, 1996, 217: 783-788.

[2]	Crepeau P. N., Antolovich S. D., Worden J. A. Structure-property Relationships in Aluminum Alloy 339-T5: Tensile Behavior at Room and Elevated Temperature[J]. Transactions of the American Foundrymen’s Society, 1990, 98: 813-822.

[3]	Wang G., Bin X. Influence of Cu and Minor Elements on Solution Treatment of Al-Si-Cu-Mg Cast Alloys[J]. Materials Letters, 2003, 80: 1-5.

[4]	Chen B., Chai C., Peng J. A High-Fe Aluminum Matrix Welding Filler Metal for Hardfacing Aluminum-Silicon Alloys[J]. J. Wuhan University of Technology-Mater.Sci.Ed.., 2003, 18(1): 25-28.

[5]	L F Mondolfo. Aluminum Alloys: Structure and Properties. London-Boston: Butterworths, 1976: 98–128

[6]	Li R. X., Li R. D. Age Harding Characteristics of High Strength Cast Al-Si-Cu-Mg Alloy[J]. Foundry, 2003, 52(6): 67-72.

[7]	Purtee M. L. Aging Effects of an Aluminum-based 319 Alloy[J]. Foundry Management And Technology, 1998, 126(10): 42-44.

[8]	Liu S., Yuan D. Heat Treatment Process of the Al-Mg-Si-Cu Alloy. Heat Treatment of Metal[J], 2005, 30(11): 55-57.

[9]	A I Garcia-Celis, E Velasco. Cooling Effects on Aging in a Cast Aluminum Alloy. Automotive Alloys II: TMS. Proceedings of the TMS Annual Meeting. USA: TMS Press, 1998: 135–143

[10]	Zeren M. Effect of Copper and Silicon Content on Mechanical Properties in Al-Cu-Si-Mg Alloys[J]. Journal of Materials Processing Technology, 2005, 169(10): 292-298.

[11]	Awano Y., Shimizu Y. Non-equilibrium Crystallization of AlFeSi Compound in Melt-superheated Al-Si Alloy Castings[J]. Transactions of the American Foundrymen’s Society, 1990, 98: 21-24.

[12]	Ferreira I. L., Garcia A., Nestler B. On Macrosegregation in Ternary Al-Cu-Si Alloys: Numerical and Experimental Analysis[J]. Scripta Materialia, 2004, 50(2): 407-411.