Ravi Sankar Haridas, Anurag Gumaste, Pranshul Varshney, Bodhi Ravindran Manu, Kumar Kandasamy, Nilesh Kumar & Rajiv S. Mishra

Deformation-based solid-state additive manufacturing techniques are known for high build rates, absence of process-induced defects that are detrimental to mechanical performance, refined equiaxed microstructure, large-scale customization, and manufacturing at ambient conditions. We introduce a novel severe plastic deformation-based SolidStir® additive manufacturing (SolidStir® AM) technique here. The process utilizes frictional heating between a non-consumable rotating tool and a feedstock to soften and plasticize the material inside a process chamber at high temperature, which is subsequently deposited in a layer-by-layer fashion under the coupled action of compressive and shear forces. In this work, aluminum 6061-T6 was used as the feedstock material for feasibility study of SolidStir® AM. The deposited material possessed a defect-free, refined, and wrought-like microstructure (~ 11 µm average grain size), enhanced ductility (~ 160% improvement), and better corrosion resistance than the base material. Based on preliminary results, SolidStir® AM appears to be a promising solid-state additive manufacturing tool that can be applied in many applications.

JOM, 2023-08-16, Volume 75, Issue 10, Pages 4231-4241, Springer Link, ISSN 1543-1851

https://doi.org/10.1007/s11837-023-06063-3
DOI    10.1007/s11837-023-06063-3