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Microstructure evolution and tensile behaviour of fine-grained 6082 Al wire with high ultimate strength and high work hardening by friction stir extrusion of bulk Al sheet

Microstructure evolution and tensile behaviour of fine-grained 6082 Al wire with high ultimate strength and high work hardening by friction stir extrusion of bulk Al sheet
Microstructure evolution and tensile behaviour of fine-grained 6082 Al wire with high ultimate strength and high work hardening by friction stir extrusion of bulk Al sheet
Driven by the highly enhanced demand for metallic materials with excellent strength-ductility synergy, fine-grained alloy fabricated by severe plastic deformation (SPD) is a long-lasting research interest. In this study, a fine-grained aluminium (Al) alloy wire with high ultimate tensile strength (316.8 MPa) and high work hardening capability (n = 0.34) was developed via a novel bulk-consolidation friction stir extrusion (FSE) enabled by CoreFlow™ process based on FSE processed 6082-T6 Al sheet. Grain refinement of 200 times occurred in CoreFlowed Al alloy, which is rarely observed in FSEed Al alloy counterpart based on milling metal chips. The undesirable feature of coarse and preferred secondary phase particles in the initial 6082-T6 Al billet was well tailored during CoreFlow™ process, which led to an attractive characteristic of dispersed and refined particle phases in CoreFlowed Al alloy. Texture components of S (V = 8.24%) and Goss (V = 6.86%) were observed, however, the overall micro-texture intensity of CoreFlowed Al wire was significantly weakened. Due to the cooperative deformation modes consisting of dislocation slip and grain boundary sliding, as well as the positive compatibility effect of fine-grains on deformation, CoreFlowed Al specimens demonstrated an excellent ductility (EI = 19.3%) and acceptable yield strength (YS = 182 MPa) compared to initial 6082-T6 Al sheet (EL = 10.4%, and YS = 225 MPa). Benefiting from the higher work hardening capability, the final ultimate tensile strength (UTS) of CoreFlowed Al (316.8 MPa) reached almost the same level as the 6082-T6 Al sheet (324.6 MPa). Furthermore, after one simple post-processing one-step heat treatment (175 °C for 10 h), the wire's yield strength was improved to 250 MPa, although only maintaining 9% elongation. This low elongation could be attributed to micro-cracks induced by coarsening of the second phases, while high yield strength resulted from fine grain size and precipitate strengthening. The wide range of variations in the mechanical properties of CoreFlowed Al wire under different conditions provides significant freedom in tailoring the mechanical properties of alloy wire in applications.
6082 Al alloy wire, CoreFlow™, Ductility, Grain refinement, Secondary phase particles, Work hardening capability
0921-5093
Yuan, Liang
b30b3b6f-1f8a-4192-98ef-177d3d799f27
Zeng, Xun
ff832409-a044-4a72-af7a-2c89874387f3
Zhao, Xingjian
484e066b-380d-4205-afd4-67516641f12c
Xie, Yanheng
5177e927-4702-4ad4-bd85-f833ae6abc51
Gandra, Joao
a375aea8-5ce3-4f34-8685-f0e1f8e9863a
Guan, Dikai
d20c4acc-342a-43fa-a204-7283f0cc33bf
Yuan, Liang
b30b3b6f-1f8a-4192-98ef-177d3d799f27
Zeng, Xun
ff832409-a044-4a72-af7a-2c89874387f3
Zhao, Xingjian
484e066b-380d-4205-afd4-67516641f12c
Xie, Yanheng
5177e927-4702-4ad4-bd85-f833ae6abc51
Gandra, Joao
a375aea8-5ce3-4f34-8685-f0e1f8e9863a
Guan, Dikai
d20c4acc-342a-43fa-a204-7283f0cc33bf

Yuan, Liang, Zeng, Xun, Zhao, Xingjian, Xie, Yanheng, Gandra, Joao and Guan, Dikai (2023) Microstructure evolution and tensile behaviour of fine-grained 6082 Al wire with high ultimate strength and high work hardening by friction stir extrusion of bulk Al sheet. Materials Science and Engineering: A, 864 (2), [144589]. (doi:10.1016/j.msea.2023.144589).

Record type: Article

Abstract

Driven by the highly enhanced demand for metallic materials with excellent strength-ductility synergy, fine-grained alloy fabricated by severe plastic deformation (SPD) is a long-lasting research interest. In this study, a fine-grained aluminium (Al) alloy wire with high ultimate tensile strength (316.8 MPa) and high work hardening capability (n = 0.34) was developed via a novel bulk-consolidation friction stir extrusion (FSE) enabled by CoreFlow™ process based on FSE processed 6082-T6 Al sheet. Grain refinement of 200 times occurred in CoreFlowed Al alloy, which is rarely observed in FSEed Al alloy counterpart based on milling metal chips. The undesirable feature of coarse and preferred secondary phase particles in the initial 6082-T6 Al billet was well tailored during CoreFlow™ process, which led to an attractive characteristic of dispersed and refined particle phases in CoreFlowed Al alloy. Texture components of S (V = 8.24%) and Goss (V = 6.86%) were observed, however, the overall micro-texture intensity of CoreFlowed Al wire was significantly weakened. Due to the cooperative deformation modes consisting of dislocation slip and grain boundary sliding, as well as the positive compatibility effect of fine-grains on deformation, CoreFlowed Al specimens demonstrated an excellent ductility (EI = 19.3%) and acceptable yield strength (YS = 182 MPa) compared to initial 6082-T6 Al sheet (EL = 10.4%, and YS = 225 MPa). Benefiting from the higher work hardening capability, the final ultimate tensile strength (UTS) of CoreFlowed Al (316.8 MPa) reached almost the same level as the 6082-T6 Al sheet (324.6 MPa). Furthermore, after one simple post-processing one-step heat treatment (175 °C for 10 h), the wire's yield strength was improved to 250 MPa, although only maintaining 9% elongation. This low elongation could be attributed to micro-cracks induced by coarsening of the second phases, while high yield strength resulted from fine grain size and precipitate strengthening. The wide range of variations in the mechanical properties of CoreFlowed Al wire under different conditions provides significant freedom in tailoring the mechanical properties of alloy wire in applications.

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Accepted/In Press date: 4 January 2023
Published date: 7 February 2023
Additional Information: Funding Information: The authors gratefully acknowledge funding through UKRI MRC Future Leaders Fellowship (No. MR/T019123/1 ). L.Y. would like to thank China Scholarship Council (CSC) for the award of fellowship (No. 201908610075). Publisher Copyright: © 2023 The Authors
Keywords: 6082 Al alloy wire, CoreFlow™, Ductility, Grain refinement, Secondary phase particles, Work hardening capability

Identifiers

Local EPrints ID: 474020
URI: http://eprints.soton.ac.uk/id/eprint/474020
DOI: doi:10.1016/j.msea.2023.144589
ISSN: 0921-5093
PURE UUID: c17912ef-f214-42cf-b2b6-5e05d84ff1b5
ORCID for Dikai Guan: ORCID iD orcid.org/0000-0002-3953-2878

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Date deposited: 08 Feb 2023 18:10
Last modified: 17 Mar 2024 04:17

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Author: Liang Yuan
Author: Xun Zeng
Author: Xingjian Zhao
Author: Yanheng Xie
Author: Joao Gandra
Author: Dikai Guan ORCID iD

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