Effect of rotation speed on microstructure and mechanical anisotropy of Al-5083 alloy builds fabricated by friction extrusion additive manufacturing

The final builds with multiple layers for a non-age-hardenable aluminum alloy were successfully fabricated under different rotation speeds using friction extrusion additive manufacturing, a force-controlled friction-based additive manufacturing process that allows the free design of the deposition p...

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Bibliographic Details
Published in:Materials science & engineering. A, Structural materials : properties, microstructure and processing Structural materials : properties, microstructure and processing, 2022-12, Vol.860, p.144237, Article 144237
Main Authors: Tang, Wenshen, Yang, Xinqi, Tian, Chaobo, Gu, Chao
Format: Article
Language:English
Subjects:
Additive manufacturing
Aluminum base alloys
Al–Mg alloy
Anisotropy
Deformation
Deformation effects
Dislocation density
Elongation
Extrusion rate
Friction
Grain refinement
Grain size
Hardenability
Interlayers
Manufacturing
Microstructure
Plastic deformation
Recrystallization
Rotation
Solid-state additive manufacturing
Strength mechanism
Tensile anisotropy
Tensile properties
Tensile strength
Thickness
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Summary:The final builds with multiple layers for a non-age-hardenable aluminum alloy were successfully fabricated under different rotation speeds using friction extrusion additive manufacturing, a force-controlled friction-based additive manufacturing process that allows the free design of the deposition path. The single layer thickness increased from 1.7 mm to 3.0 mm when the rotation speed was reduced from 800 r/min to 400 r/min for a given layer thickness of 4 mm. The grain size at the interface was refined to 3.8–5.0 μm at 800 r/min because less recrystallization occurred, resulting in a higher geometrically necessary dislocations density. The grains formed at the interface at 800 r/min were mainly determined by recrystallization textures Cube, CubeRD, and CubeND and deformation texture S. However, a stronger coupling effect between heat and plastic deformation at 600 r/min leads to the dominance of shear textures B/B‾ and RtCu and deformation textures S. The final deposits superior to the wrought Al alloy 5083-H112 in terms of tensile properties were obtained at 600 r/min due to the largest contribution of grain refinement strengthening. Grain refinement increases strength at the interface and interlayer by 113.1 MPa and 92.1 MPa, respectively. The tensile strength, yield strength, and elongation at break in the Z direction reach 290.2 MPa, 163.3 MPa, and 12.6%, respectively. Due to the existence of kissing bonding at 800 rpm, the value of the elongation at break in the Z direction is only 19% of the value in the X direction. •Rotation speed detrmines layer thickness of additively manufactured Al 5083.•Shear textures governed the interface without defects at lower rotation speed.•A strength prediction model was developed for additively manufactured Al 5083.•Al 5083 with wrought like properties obtained under higher deposition rate.
ISSN:0921-5093
1873-4936
DOI:10.1016/j.msea.2022.144237