Additive manufacturing of Fe-3.5 wt.-%Si electrical steel via laser powder bed fusion and subsequent thermomechanical processing

A novel additive manufacturing approach is proposed to produce an electrical steel (Fe-3.5%Si) by laser powder bed fusion (LPBF) followed by conventional thermomechanical processing. The aim of this proof-of-concept study is to develop a new processing route for grain-oriented electrical steels from...

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Bibliographic Details
Published in:Journal of materials science 2024-03, Vol.59 (9), p.4019-4038
Main Authors: Lyrio, M. S., Aota, L. S., Sandim, M. J. R., Sandim, H. R. Z.
Format: Article
Language:English
Subjects:
Additive manufacturing
Annealing
Characterization and Evaluation of Materials
Chemistry and Materials Science
Classical Mechanics
Cold rolling
Crystallography and Scattering Methods
Electrical steels
Grain boundaries
Grain growth
Grain orientation
Manufacturing
Materials Science
Metals & Corrosion
Nanoparticles
Polymer Sciences
Porosity
Powder beds
Recrystallization
Rotation
Silicon dioxide
Solid Mechanics
Thermomechanical treatment
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Summary:A novel additive manufacturing approach is proposed to produce an electrical steel (Fe-3.5%Si) by laser powder bed fusion (LPBF) followed by conventional thermomechanical processing. The aim of this proof-of-concept study is to develop a new processing route for grain-oriented electrical steels from LPBF-processed plates with strong texture and SiO 2 nanoparticles followed by cold rolling and long-term annealing to trigger abnormal grain growth. The slabs were processed with two different scanning strategies; e.g., with (90R) and without 90° rotation (0R) between layers aiming at intensifying the as-built textures near-Goss and/or cube components. The as-built slabs were cold rolled to 83% reduction and annealed for subsequent monitoring of primary recrystallization and abnormal grain growth. Goss or near-Goss nuclei were identified for both strategies after cold rolling. Abnormal grain growth occurred more intensely in samples with a 90° rotation between layers. Goss-oriented grains are bounded by high-angle boundaries with peak misorientations of 50° in 90R and 37.5° in 0R strategy. Porosity in 0R is three times higher than in 90R, while the total fraction of CSL boundaries is similar for both strategies (about 6%). Boundary mobility seems to be higher in 90R, which explains easier grain boundary depinning from oxide nanoparticles than in 0R strategy. In comparison with grain-oriented commercial products, increased total magnetic losses can be explained by thickness effects, porosity and deviation from ideal Goss orientation. Graphical Abstract
ISSN:0022-2461
1573-4803
DOI:10.1007/s10853-024-09418-6