High-Strength Aluminium Alloys and Their Use in Foundry Industry of Nickel Superalloys

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Of great importance in the selection of materials for cast structures is keeping a proper balance between the mechanical and plastic properties, while preserving the relevant casting properties. This study has been devoted to an analysis of the choice and application of high-strength aluminium-based alloys maintaining sufficient level of casting properties. The high level of tensile strength (Rm > 500 MPa) matched with satisfactory elongation (A > 3%) is important because materials of this type are used for cast parts operating in the aerospace, automotive, and military industries. These beneficial relationships between the high tensile strength and toughness are relatively easy to obtain in the Al-Zn-Mg-Cu alloys subjected to plastic forming and proper heat treatment. In gravity cast products, on the other hand, whether poured into sand moulds or metal moulds (dies), obtaining this favourable combination of properties poses a number of research problems (mostly resulting from the alloy chemical composition) as well as technical and technological difficulties.

[1] Taub, A.I., Krajewski, P.E., Luo, A.A. & Owens J.N. (2007). The Evolution of Technology for Materials Processing over the Last 50 Years. The Automotive Example. JOM. 59(2), 48-57.

[2] Luo, A.A., Sachdev, A.K. & Powell, B.R. (2010). Advanced casting technologies for lightweight automotive applications. China Foundry. 7(4), 463-469.

[3] Ashby, M.F. et al. (2012). Materials Engineering 1. Łódź, Poland: Galaktyka. (in Polish).

[4] Sobczak, J. & Wojciechowski, S. (2002). Modern trends in the practical application of metal matrix composites. Composites. 2(3), 24-37.

[5] Oczoś, K.E. (2008). Shaping by machining of titanium and its alloys in the aerospace industry and medical technology. Part I. Mechanic. 8-9, 639-656.

[6] Oczoś K.E., Kawalec A. (2012). Shaping of light metals. Warszawa, Poland: PWN. (in Polish).

[7] Andersson, J.O., et al. (2002). Thermo-Calc & DICTRA, computational tools for materials science. Calphad. 26(2), 273-312.

[8] Bazhenov, V.E. & Koltygin A.V. (2011). Optimizatsiya sostava splava AK5M s pomoshchyu programmy. ProCast. Liteynoe proizvodstvo. 12, 27-28.

[9] http://www.magmasoft.com

[10] Abhijeet, Misra (2012). Design of high-strength aluminum alloy casting – A case study on the importance of multicomponent diffusion to materials design. NIST Diffusion Workshop Series. 3-4, from: http://www.nist.gov

[11] Stoganov, G.B. (1985). Vysokoprochnye liteynye alyuminievye splavy. Moskva: Izd. Metallurgiya. (in Russian).

[12] Hatch, J.E. (1993). Aluminium. Properties and Physical Metallurgy. Ohio: American Society for Metals (ASM), Metals Park.

[13] Metals handbook Vol. 2. (1990). Properties and Selection: Nonferrous and Special-purpose Materials. Ohio: ASM International, Materials Park.

[14] Rzadkosz, S., Staszczak, L. (2007). High-grade casting aluminium-based alloys. In 10th Foundry Conference TECHNICAL, 59-68.

[15] Postnikom, N.S. (1983). Uprochnenie alyuminievykh splavov i otlivok. Moskva: Izd. Metallurgiya. (in Russian).

[16] PN-EN 1706:2011 (2011). Aluminum and aluminum alloys. Castings. Chemical composition and mechanical properties. Warszawa: PKN. (in Polish).

[17] Czekaj, E., Dybiec, H., Fajkiel, A., Sadowski, P. (2011). Casting of zinc-based silumins. In XIV Scientific-Technical Conference on Casting of Non-Ferrous Metals „Science and Technology”, Zakopane, 2÷4 June 2011, 17-27 Kraków, Poland: AGH.

[18] Institute of Cast Metals Engineers (2011). Aluminium investment casting replaces forged part for military transporter. Foundry Trade Journal International. 185(3686), 202.

Archives of Foundry Engineering

The Journal of Polish Academy of Sciences

Journal Information

CiteScore 2016: 0.42

SCImago Journal Rank (SJR) 2016: 0.192
Source Normalized Impact per Paper (SNIP) 2016: 0.316


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