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A Laboratory Study of Electrochemical Removal of Noble Elements from Secondary Aluminium

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REWAS 2016

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Abstract

At present, recycled aluminium is “diluted” by primary metal to keep the impurity concentrations at acceptable levels. Future increase in recycling will require a new process for efficient removal of all impurities, including noble elements, from secondary aluminium. In the current preliminary laboratory study, an electrochemical method based on the well-known three-layer refining cell was explored. Metal with purity comparable to primary metal could be obtained from highly alloyed scrap feeds containing elements more noble than aluminium, such as iron, copper, manganese, and zinc. The energy consumption was as low as 8.5 kWh/kg Al, indicating that the process can be expected to be less expensive than for production of primary metal, but with higher costs than re-melting.

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References

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Author information

Authors and Affiliations

  1. SINTEF Materials and Chemistry, P.O. Box 4760 Sluppen, NO-7465, Trondheim, Norway

    Ole S. Kjos, Sverre Rolseth, Henrik Gudbrandsen, Egil Skybakmoen, Asbjørn Solheim & Trond H. Bergstrøm

Authors
  1. Ole S. Kjos
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  2. Sverre Rolseth
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  3. Henrik Gudbrandsen
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  4. Egil Skybakmoen
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  5. Asbjørn Solheim
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  6. Trond H. Bergstrøm
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Editor information

Editors and Affiliations

  1. Department Materials Engineering of KU Leuven, Belgium

    Bart Blanpain (full professor, co-director for the I/UCRC ‘Center for Resource Recovery and Recycling’, co-editor-in-chief for the Journal of Sustainable Metallurgy) (full professor, co-director for the I/UCRC ‘Center for Resource Recovery and Recycling’, co-editor-in-chief for the Journal of Sustainable Metallurgy)

  2. Umicore Precious Metals Refining, Hoboken, Belgium

    Christina Meskers (senior manager and leading the Market Intelligence and Business Research team) (senior manager and leading the Market Intelligence and Business Research team)

  3. Department of Materials Science and Engineering, MIT, USA

    Elsa Olivetti (Thomas Lord Assistant Professor) (Thomas Lord Assistant Professor)

  4. Worcester Polytechnic Institute (WPI), USA

    Diran Apelian (Alcoa-Howmet Professor of Engineering and Founding Director of the Metal Processing Institute (MPI) & Brajendra Mishra (Kenneth G. Merriam Distinguished Professor of Mechanical Engineering and Assoc. Director of the Metal Processing Institute, Director of the National Science Foundation’s Industry/University Collaborative Research Center on Resource Recovery & Recycling) (Alcoa-Howmet Professor of Engineering and Founding Director of the Metal Processing Institute (MPI) &  (Kenneth G. Merriam Distinguished Professor of Mechanical Engineering and Assoc. Director of the Metal Processing Institute, Director of the National Science Foundation’s Industry/University Collaborative Research Center on Resource Recovery & Recycling)

  5. Purdue University, USA

    John Howarter (assistant professor in materials engineering) (assistant professor in materials engineering)

  6. SINTEF, Norway

    Anne Kvithyld (senior research scientist) (senior research scientist)

  7. IND LLC, USA

    Neale R. Neelameggham (‘The Guru’) (‘The Guru’)

  8. Argonne National Laboratory, USA

    Jeff Spangenberger (engineering specialist, Sr) (engineering specialist, Sr)

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© 2016 TMS (The Minerals, Metals & Materials Society)

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Kjos, O.S., Rolseth, S., Gudbrandsen, H., Skybakmoen, E., Solheim, A., Bergstrøm, T.H. (2016). A Laboratory Study of Electrochemical Removal of Noble Elements from Secondary Aluminium. In: Kirchain, R.E., et al. REWAS 2016. Springer, Cham. https://doi.org/10.1007/978-3-319-48768-7_37

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