Abstract
The presence of non-metallic inclusions in aluminium has become a more critical issue with increasing demands on surface quality and low final wall thicknesses of products. Aluminium carbide particles form during the primary aluminium production due to the contact between aluminium and carbon/carbonaceous species in the electrolysis cell . These particles are typically very small (<3 μm), however, they may have crucial impacts on the mechanical and optical properties of products when they agglomerate due to poor wetting/high surface tension with/in aluminium melts. The carbide concentration is typically reduced after metal re-melting . The current paper experimentally examines this concentration change and the measured effect of re-melting temperature, atmosphere and rate of carbide reduction during holding of the liquid metal. The study showed that electrolysis metal, initially containing approximately 35 ppm Al 4C3, retained carbide contents after re-melting in alumina crucibles at 700, 750 or 800 °C at similar levels (2–12 ppm) as previously reported as corresponding to carbon saturation in the melt. The study also illustrated that the carbide level is rapidly decreased during re-melting , and that the reduction is faster in air than in argon, suggesting that the removal takes place via direct oxidation of carbide particles close to—or at the melt surface.
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References
Engh, T (1992) Principles of Metal Refining. Oxford Science Publications
R.C. Dorward. Aluminium carbide contamination of molten aluminium. Aluminium, 49(10):686{689, October 1973.
Novak B, Tschöpe K, Ratvik AP, Grande T (2012) Fundamentals of Aluminum Carbide Formation. Light Metals:1343–1348
Dorward R (1973) Aluminium carbide contamination of molten aluminium. Aluminium, 49(10):686–689
Simensen C (1989) Comments on the solubility of carbon in molten aluminum. Metallurgical Transactions A, 20(1):191
Rødseth J, Rasch B, Lund O, Thonstad J (2002) Solubility of carbon in aluminium and its effect upon the casting process. Light Metals:883–888
Simensen C (1978) Gas-chromatographic analysis of carbides in aluminium and magnesium. Fresenius’ Zeitschrift Für Analytische Chemie 292(3):207–212
Outotec (2017) HSC 9 (software)
Dorward R (1990) Discussion of “comments on the solubility of carbon in molten aluminum”. Metallurgical Transactions A, 21(1):255–257
Obinata I and Komatsu N (1964), Solubility of carbon in liquid aluminium, Journal of Japan Institute of Light Metals, 14(4), pp. 226–230
Acknowledgements
The authors wish to thank staff at Hydro Aluminium Sunndalsøra for supplying electrolysis metal and for carrying out all carbide analyses. The assistance of Henning Dahl, carrying out a part of the experiments, is gratefully acknowledged. Fruitful discussions with Snorre Kjørstad Fjeldbo around carbides in aluminium , is also much appreciated. The work was funded through the “BEST” project, jointly financed by the Research Council of Norway, Hydro Aluminium , Alcoa Norway, Gränges Aluminium and Hycast.
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© 2019 The Minerals, Metals & Materials Society
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Gökelma, M., Storm Aarnæs, T., Maier, J., Friedrich, B., Tranell, G. (2019). Behaviour of Aluminium Carbide in Al-Melts During Re-melting. In: Chesonis, C. (eds) Light Metals 2019. The Minerals, Metals & Materials Series. Springer, Cham. https://doi.org/10.1007/978-3-030-05864-7_126
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DOI: https://doi.org/10.1007/978-3-030-05864-7_126
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