Effects of thermomechanical treatment on grain refinement, second-phase particle dissolution, and mechanical properties of 2219 Al alloy

[Display omitted] •Thermomechanical treatment for improving properties of 2219 Al-Cu alloy is studied.•Dislocation tangles around Al2Cu particles form preferential recrystallization nucleation sites.•High dislocation density promotes dissolution of Al2Cu particles during solution treatment.•Grain re...

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Published in:Journal of materials processing technology 2020-04, Vol.278, p.116506, Article 116506
Main Authors: He, Hailin, Yi, Youping, Huang, Shiquan, Guo, Wanfu, Zhang, Yuxun
Format: Article
Language:English
Subjects:
Aging (natural)
Al alloy
Aluminum base alloys
Anisotropy
Cold forging
Cold forgings
Cold treatment
Deformation
Dissolution
Grain refinement
Heat treating
Mechanical properties
Nucleation
Precipitates
Predeformation
Second-phase particles
Solution heat treatment
Thermomechanical treatment
Ultimate tensile strength
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Summary:[Display omitted] •Thermomechanical treatment for improving properties of 2219 Al-Cu alloy is studied.•Dislocation tangles around Al2Cu particles form preferential recrystallization nucleation sites.•High dislocation density promotes dissolution of Al2Cu particles during solution treatment.•Grain refinement occurs and higher-destiny precipitates form during new process.•New TMT process leads to improved strength, elongation, and low anisotropy. An improved thermomechanical treatment, which included 50% hot deformation at 440°C, 10% cold predeformation at 25°C, and a subsequent heat treatment (solution, 2.5% cold deformation and aging treatment), was performed on 2219 Al alloy forgings. For comparison, a 2219 Al alloy forging was also manufactured using the conventional process, which involved 50% hot deformation at 440°C and a subsequent heat treatment. The evolution of the microstructures of the forgings during the treatments and their final mechanical properties were evaluated. A large number of Al2Cu particles were formed during the hot-deformation process. Further, tangled dislocation structures were formed around these particles after 10% cold deformation in the forging manufactured by the improved process, resulting in a significant grain refinement during the solution treatment because of particle stimulated nucleation as well as a weakened texture. In addition, more coarse Al2Cu particles dissolved into the Al matrix during the solution treatment in the case of the forging subjected to the improved treatment, because the tangled dislocation structures promoted the dissolution of these particles, thus increasing the density of the precipitates after T8-aging. The forging manufactured by the improved treatment exhibited a higher ultimate tensile strength (by 34.3 MPa), higher yield strength (by 43.2 MPa), and significantly lower anisotropy, as well as improved elongations in the axial and radial directions (lower-performance directions).
ISSN:0924-0136
1873-4774
DOI:10.1016/j.jmatprotec.2019.116506