Microstructure evolution and phase transformation of traditional cast and spray-formed hypereutectic aluminium-silicon alloys induced by heat treatment

Long-gang Hou; Yuan-hua Cai; Hua Cui; Ji-shan Zhang

doi:10.1007/s12613-010-0308-6

International Journal of Minerals, Metallurgy, and Materials ›› 2010, Vol. 17 ›› Issue (3) : 297 -306. DOI: 10.1007/s12613-010-0308-6

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Microstructure evolution and phase transformation of traditional cast and spray-formed hypereutectic aluminium-silicon alloys induced by heat treatment

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Abstract

Microstructural evolution and phase transformation induced by different heat treatments of the hypereutectic aluminium-silicon alloy, Al-25Si-5Fe-3Cu (wt%, signed as 3C), fabricated by traditional cast (TC) and spray forming (SF) processes, were investigated by differential scanning calorimetry (DSC) and scanning electron microscopy (SEM) combined with energy dispersive X-ray spectroscopy and X-ray diffraction techniques. The results show that Al₇Cu₂Fe phase can be formed and transformed in TC- and SF-3C alloys between 802–813 K and 800–815 K, respectively. The transformation from β-Al₅FeSi to δ-Al₄FeSi₂ phase via peritectic reaction can occur at around 858–870 K and 876–890 K in TC- and SF-3C alloys, respectively. The starting precipitation temperature of δ-Al₄FeSi₂ phase as the dominant Fe-bearing phase in the TC-3C alloy is 997 K and the exothermic peak about the peritectic transformation of δ-Al₄FeSi₂→β-Al₅FeSi is not detected in the present DSC experiments. Also, the mechanisms of the microstructural evolution and phase transformation are discussed.

Keywords

hypereutectic Al-Si alloy / spray forming / cast / microstructure / phase transformation

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Long-gang Hou, Yuan-hua Cai, Hua Cui, Ji-shan Zhang. Microstructure evolution and phase transformation of traditional cast and spray-formed hypereutectic aluminium-silicon alloys induced by heat treatment. International Journal of Minerals, Metallurgy, and Materials, 2010, 17(3): 297-306 DOI:10.1007/s12613-010-0308-6

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References

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[1]	Miller W.S., Zhuang L., Bottema J., et al. Recent development in aluminium alloys for the automotive industry. Mater. Sci. Eng. A, 2000, 280, 37.

[2]	J.B. Andrews and M.V.C. Seneviratne, A new, highly wear-resistant aluminum-silicon casting alloy for automotive engine block applications, AFS Trans, 1984, p.209.

[3]	Akbulut H., Durman M., Yilmaz F. A comparison of as-cast and heat treated properties in short fiber reinforced Al-Si piston alloys. Scripta Mater., 1997, 36(7): 835.

[4]	Pohl A. Wear resistant sintered aluminium parts for automotive applications. Powder Metall., 2006, 49(2): 104.

[5]	Mondolfo L.F. Aluminum Alloys: Structure and Properties, 1976 London & Tonbridge, The Whitefriars Press Ltd., 534.

[6]	Belov N.A., Eskin D.G., Avxentieva N.N. Constituent phase diagrams of the Al-Cu-Fe-Mg-Ni-Si system and their application to the analysis of aluminium piston alloys. Acta Mater., 2005, 53, 4709.

[7]	Hirosawa S., Sato T., Kamio A., Flower H.M. Classification of the role of microalloying elements in phase decomposition of Al based alloys. Acta Mater., 2000, 48, 1797.

[8]	Radjai A., Miwa K., Nishio T. An investigation of the effects caused by electromagnetic vibrations in a hypereutectic Al-Si alloy melt. Metall. Mater. Trans. A, 1998, 29, 1477.

[9]	Kyffin W.J., Rainforth W.M., Jones H. Effect of treatment variables on the size refinement by phosphide inoculants of primary silicon in hypereutectic Al-Si alloy. Mater. Sci. Technol., 2001, 17, 901.

[10]	Crepeau P.N. Effect of iron in Al-Si casting alloys: a critical review. AFS Trans., 1995, 103, 361.

[11]	Dinnis C.M., Taylor J.A., Dahle A.K. As-cast morphology of iron-intermetallics in Al-Si foundry alloys. Scripta Mater., 2005, 53, 955.

[12]	Ashtari P., Tezuka H., Sato T. Influence of Sr and Mn additions on intermetallic compound morphologies in Al-Si-Cu-Fe cast alloys. Mater. Trans., 2003, 44(12): 2611.

[13]	L. Backerud, L. Arnberg, and G. Chai, Method of Reducing the Formation of Primary Platelet-shaped Beta-phase in Iron Containing AlSi Alloys, in Particular in Al-Si-Mn-Fe Alloys, US Patent, No.US6267829B1, 2001.

[14]	Zhou J., Duszczyk J., Korevaar B.M. As-spray-deposited structure of an Al-20Si-5Fe Osprey preform and its development during subsequent processing. J. Mater. Sci., 1991, 26, 5275.

[15]	Srivastava A.K., Srivastava V.C., Gloter A., et al. Micro structural features induced by spray processing and hot extrusion of an Al-18%Si-5%Fe-1.5%Cu alloy. Acta Mater., 2006, 54, 1741.

[16]	C.Y. Tsao, Y.H. Su, and C.H. Chiang, Aluminum Alloy with Improved Mechanical Properties at High Temperature, US Patent, No.US20060081311A1, 2006.

[17]	Khalifa W., Samuel F.H., Gruzleski J.E. Iron intermetallic phases in the Al corner of the Al-Si-Fe system. Metall. Mater. Trans. A, 2003, 34, 807.

[18]	Raghavan V. Al-Fe-Si (aluminum-iron-silicon). J. Phase Equilibria Diffus., 2009, 30(2): 184.

[19]	Lalpoor M., Eskin D.G., Katgerman L. Fracture behavior and mechanical properties of high strength aluminum alloys in the as-cast condition. Mater. Sci. Eng. A, 2008, 497(1–2): 186.

[20]	Wang J.S., Lee P.D., Hamilton R.W., et al. The kinetics of Fe-rich intermetallic formation in aluminium alloys: In situ observation. Scripta Mater., 2009, 60, 516.

[21]	Gutierrez-Miravete E., Lavernia E.J., Trapaga G.M., et al. A mathematical model of the liquid dynamic compaction process: Part 2. Formation of the deposit. Int. J. Rapid Solidification, 1988, 4, 125.

[22]	Su S., Liang X., Moran A., et al. Solidification behavior of an Al-6Si alloy during spray atomization and deposition. Int. J. Rapid Solidification, 1994, 8, 161.

[23]	Gutierrez-Miravete E., Lavernia E.J., Trapaga G.M., et al. A mathematical model of the spray deposition process. Metall. Trans. A, 1989, 20, 71.

[24]	Zhang J.S., Cui H., Duan X.J., et al. An analytical simulation of solidification behavior within deposited preform during spray forming process. Mater. Sci. Eng. A, 2000, 276, 257.

[25]	Xu Q., Gupta V.V., Lavernia E.J. Thermal behavior during droplet-based deposition. Acta Mater., 2000, 48, 835.

[26]	Belov N.A., Eskin D.G., Aksenov A.A. Multicomponent Phase Diagram: Application for Commercial Aluminum Alloys, 2005 the Netherlands, Elsevier, 97.

[27]	Massalski T.B., Okamoto H., Subramanian P.R., et al. Binary Alloy Phase Diagrams, Volume 1, 1986 2nd Ed. Metals Park, American Society for Metals, 141.

[28]	Klug H.P., Alexander L.E. X-ray Diffraction Procedures for Polycrystalline and Amorphous Materials, 1974 2nd Ed. New York, Wiley-VCH, 441.

[29]	Davis J.R. Metals Handbook, 1998 2nd Ed. Metals Park, American Society for Metals, 1.

[30]	Hayounea A., Hamanab D. Structural evolution during non-isothermal ageing of a dilute Al-Cu alloy by dilatometric analysis. J. Alloys Compd., 2009, 474, 118.