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Supervised by Ministry of Industry and Information Technology of The People's Republic of China Sponsored by Harbin Institute of Technology Editor-in-chief Yu Zhou ISSNISSN 1005-9113 CNCN 23-1378/T

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Related citation:Rehan Qayyume,Sha-Sha Zhao,Hao-Yan Diao,Chao-Li Ma,Xiao-Wei Wu,Yong Wang.Hot Deformation Behavior of Aluminum Alloy 5083 for Automotiveand Aviation Applications[J].Journal of Harbin Institute Of Technology(New Series),2013,20(5):87-95.DOI:10.11916/j.issn.1005-9113.2013.05.016.
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Hot Deformation Behavior of Aluminum Alloy 5083 for Automotiveand Aviation Applications
Author NameAffiliation
Rehan Qayyume Key Laboratory of Aerospace Advanced Materials and Performance, Ministry of Education, School of Material Science and Engineering, Beihang University, Beijing 100191, China 
Sha-Sha Zhao Key Laboratory of Aerospace Advanced Materials and Performance, Ministry of Education, School of Material Science and Engineering, Beihang University, Beijing 100191, China 
Hao-Yan Diao Key Laboratory of Aerospace Advanced Materials and Performance, Ministry of Education, School of Material Science and Engineering, Beihang University, Beijing 100191, China 
Chao-Li Ma Key Laboratory of Aerospace Advanced Materials and Performance, Ministry of Education, School of Material Science and Engineering, Beihang University, Beijing 100191, China 
Xiao-Wei Wu Beijing Research Institute of Mechanical & Electrical Technology, Beijing 100083, China 
Yong Wang Beijing Research Institute of Mechanical & Electrical Technology, Beijing 100083, China 
Abstract:
This article concentrates on the investigation of hot deformation behavior of conventionally rolled commercial grade AA5083 alloy (Al-4.5Mg), for automotive and aviation applications. The superplastic response of the alloy was investigated at high strain rates (≥10-3 s-1), and a temperature range of 400 ℃ to 550 ℃. An elongation to failure of 201% was achieved at low temperature (425 ℃) and high strain rate (10-2s-1), which indicates sufficient ductility under hot deformation for manufacturing of extremely complex shapes using superplastic forming technology. Furthermore, the alloy exhibited a maximum elongation of about 470% at strain rate of 10-3s-1 and a temperature of 525 ℃. The deformation and failure mechanisms at both the critical conditions were studied as a function of strain rate and temperature. The contributions of strain-rate sensitivity and strain hardening were analyzed in relation to the observed tensile ductilities. Deformation mechanism of the alloy was also investigated with reference to Strain rate sensitivity index (m) and Activation energy (Q) for the given test condition. Empirical calculations reveal that dominant deformation mechanism responsible for hot deformation of the alloy is grain boundary sliding (GBS), which is further supported by deformed surface examination using scanning electron microscopy (SEM). Fracture surfaces of the samples deformed to failure, at relatively higher and lower strain rates, was examined to investigate the micro-mechanisms governing failure. Phenomenon of cavity nucleation, growth and coalescence was observed to be the failure mechanism in the investigated alloy.
Key words:  Al-Mg alloys  superplasticity  hot deformation  microstructure evolution  cavitation
DOI:10.11916/j.issn.1005-9113.2013.05.016
Clc Number:TG146.2
Fund:

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