Author(s):
1. Spomenka Kobe, Jožef Stefan Institute Slovenia, Slovenia
Abstract:
The European Union has set itself the goal of achieving climate neutrality by 2050, a milestone that depends on the continent's ability to develop and implement clean energy and mobility solutions in a way that is both economically viable and environmentally sustainable. The amount of critical raw materials (CRM) needed to facilitate this energy transition is significant. In addition, industrial and household appliances will need to meet stringent energy efficiency standards to support this transition. The most energy-efficient electric motors and generators contain rare earth permanent magnets. While EU companies are world leaders in the production of electric motors, they are completely dependent on imports for the entire value chain of rare earth magnet materials. (Bernd Schaferet.al, A Report of the Rare Earth Magnets and Motors Cluster, Berlin 2021).
Rare earth elements (REEs) are essential components of these permanent magnets, which are critical for many applications that are vital to Europe's future. It is well known that REEs from China have been the main source for Europe, that supplies are uncertain, and that the Chinese production chain is generally unsustainable. At the same time, the demand for REEs for the production of new PMs is expected to double in 15 years.
In light of this data, our work focuses on the collection of EOL magnets and the sustainable recycling and reprocessing of PM from sources, concentrating on the most common and readily available source of economically recyclable electric motors: domestic appliances. We are developing new dismantling and recovery processes for PM on high-availability scrap and reprocessing lines. In HPMS (Hydrogen Processing of Magnetic Scrap)1,2 we use an already established method of hydrogenation followed by grinding, degassing, and coating of sensitive powders. The HDDR (Hydrogenation-Disproportionation-Desorption-Regeneration)3 process has been implemented to simplify and minimize the steps in the recycling process.
Initial, ongoing pilot trials for the production of sintered and bonded magnets from recycled magnets confirm the waste-free, economic processing and future independence from unstable REE sources. For the production of sintered magnets, a new sustainable process of rapid consolidation is used, while for bonded magnets the most sensitive part to protect the reactive powders is the coating with a few monolayers of chemically bound coating precursor. In addition to magnetic measurements, various analytical techniques (SEM, HRTEM, XPS) are used to characterize the powders obtained by HPMS and HDDR processes, as well as the final magnets.
*This work is part of the “INSPIRES” project financed by EIT RawMaterials, Proposal Number 20090 (project website: https://eitrawmaterials.eu/project/inspires/).
1. C. Burkhardt, A. Lehmann, B. Podmiljšak, S. Kobe, A systematic classification and labelling approach to support a circular economy ecosystem for NdFeB-type magnet, J. mater. sci. eng., B, 2020
2. C. Burkhardt, A. Lehmann, P. Fleissner, L. Grau, L. Trautz, M. Mungenast, B. Podmiljšak, S. Kobe, Comparative evaluation of anti-corrosion coatings for NdFeB-type magnets with respect to performance and recyclability via hydrogen-assisted recycling (HPMS), Mater. Proc. 2021, 5(1), 87; https://doi.org/10.3390/materproc2021005087
3. Walton, A., Williams, A.J., Speight, J.D. and Harris, I.R.; US Patent No. US 13/169,839. “Magnet recycling” (Priority 2010, Application 2012, granted 2014)
Key words:
Rare-Earth Magnets,HDDR
Thematic field:
SYMPOSIUM A - Science of matter, condensed matter and physics of solid states
Date of abstract submission:
28.06.2024.
Conference:
Contemporary Materials 2024 - Savremeni Materijali