Hot deformation behavior of Cu/Al laminated composites under interface constraint effect

In order to understand the hot deformation behavior of novel Cu/Al laminated composites and evaluate the effect of interface on deformation, isothermal compression tests were conducted on the Cu/Al composites with and without a bonding interface and monometallic Al. Results show that after hot compr...

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Bibliographic Details
Published in:Materials research express 2018-06, Vol.5 (6), p.66531
Main Authors: Liu, Shuaiyang, Wang, Aiqin, Liang, Tingting, Xie, Jingpei
Format: Article
Language:English
Subjects:
constitutive equation
Cu/Al laminated composites
deformation behavior
interface
microstructure
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Summary:In order to understand the hot deformation behavior of novel Cu/Al laminated composites and evaluate the effect of interface on deformation, isothermal compression tests were conducted on the Cu/Al composites with and without a bonding interface and monometallic Al. Results show that after hot compression, there is a obvious relative sliding between Cu and Al layers of the Cu/Al composites without a bonding interface. As for the Cu/Al composites with a bonding interface, soft Al layer trends to flow synchronously with hard Cu layer under the interface constraint effect. And further microstructure examinations indicate the cooperative deformation capability of Cu/Al composites increases with increasing stain rate and decreasing deformation temperature. Strain hardening exponent, calculated based on the true stress-true strain data, also proves the effect of deformation temperature and strain rate on the cooperative deformation behavior. Meanwhile, because softening mechanism of Al layer plays a dominant role at high deformation temperature, the interface constraint effect was weaken and the flow stress of Cu/Al composites was similar to that of monometallic Al. Due to the unique composites structure, the dynamic softening mechanism of Al layer in Cu/Al composites is dynamic recrystallization during isothermal deformation. Additionally, the deformation activation energy of Cu/Al composites was calculated to be 186.43 KJ mol−1.
ISSN:2053-1591
2053-1591
DOI:10.1088/2053-1591/aacaeb