Additive friction stir deposition-enabled upcycling of automotive cast aluminum chips

Additive friction stir deposition (AFSD), a deformation-based, near-net-shaping additive technology, is used to consolidate Al chips from automotive castings to produce fully-dense components, while addressing the energy, environmental, and efficiency challenges associated with recycling these chips via melting. Cold pressing of the chips results in feed-rods with a relative density of 68%. AFSD of these porous feed-rods leads to porosity-free material in the as-printed state. Compared to the base material of bulk cast Al, the as-printed material increases the tensile elongation from less than 1% to 17.8%, while exhibiting significant strain hardening. This upcycling effect is shown to originate from microstructure evolution during deposition, including the second-phase particles and the grain structure. The received Al chips have a hypereutectic composition and thus contain a high proportion of primary Si particles. The minor presence of Fe causes additional intermetallic particles as well. After deposition, these Si and Fe-based particles are refined, spherodized, and uniformly distributed in the Al matrix. Meanwhile, the cast Al microstructure is converted to an equiaxed grain structure with the grain size reduced from -25 ������������ to -2 ������������. Finally, the energy consumption of AFSD-enabled upcycling is compared to melt-based recycling; potential pathways are evaluated for energy consumption reduction.

Automated summary

Additive Friction Stir Deposition (AFSD) technology is used to consolidate Al chips from automotive castings into fully-dense components, addressing the challenges of energy, environment, and efficiency in chip recycling. AFSD of cold-pressed porous feed-rods results in porosity-free material with improved tensile elongation and strain hardening due to microstructure evolution. Si and Fe-based particles in the chips are refined and uniformly distributed in the Al matrix after deposition, leading to an equiaxed grain structure. The energy consumption of AFSD-enabled upcycling is compared to melt-based recycling, and potential pathways for energy consumption reduction are evaluated.