TY - JOUR
T1 - Interface microstructure evolution and mechanical properties of Al/Cu bimetallic tubes fabricated by a novel friction-based welding technology
AU - Li, Wenya
AU - Wen, Quan
AU - Yang, Xiawei
AU - Wang, Yansong
AU - Gao, Dalu
AU - Wang, Weibin
N1 - Publisher Copyright:
© 2017 Elsevier Ltd
PY - 2017/11/15
Y1 - 2017/11/15
N2 - In this study, a novel friction-based welding technology was proposed for fabricating Al/Cu bimetallic tubes. The frictional heat and radial pressure during the friction-based welding process are used to achieve the metallurgical bonding between Al and Cu tubes in a rapid and efficient way. Successful joints indicate that this technology has the potential for fabricating bimetallic tubes. Microstructure evolution, bonding mechanism and mechanical properties of Al/Cu bimetallic tubes were also analyzed. Results reveal that columnar α-Al, intermediate transition layer and intermetallic compounds (IMC) are identified at the rotational speed of 950 rpm. While the rotational speed is decreased to 95 rpm, only solid-state diffusion occurs at the interface which results in three IMC layers, Al2Cu, AlCu, and Al2Cu3. The thickness of the Al2Cu is more significantly affected by the rotational speed than that of AlCu and Al2Cu3. Maximum hardness is observed at the reaction layer due to the formation of IMC. The appearance of intermediate transition and thick Al2Cu layer weakens the bonding strength of bimetallic tubes. The joints are fractured at the reaction layers, and the fracture exhibits typical brittle characteristic. Three crack propagation paths are observed at the interface of Al/Cu bimetallic tubes.
AB - In this study, a novel friction-based welding technology was proposed for fabricating Al/Cu bimetallic tubes. The frictional heat and radial pressure during the friction-based welding process are used to achieve the metallurgical bonding between Al and Cu tubes in a rapid and efficient way. Successful joints indicate that this technology has the potential for fabricating bimetallic tubes. Microstructure evolution, bonding mechanism and mechanical properties of Al/Cu bimetallic tubes were also analyzed. Results reveal that columnar α-Al, intermediate transition layer and intermetallic compounds (IMC) are identified at the rotational speed of 950 rpm. While the rotational speed is decreased to 95 rpm, only solid-state diffusion occurs at the interface which results in three IMC layers, Al2Cu, AlCu, and Al2Cu3. The thickness of the Al2Cu is more significantly affected by the rotational speed than that of AlCu and Al2Cu3. Maximum hardness is observed at the reaction layer due to the formation of IMC. The appearance of intermediate transition and thick Al2Cu layer weakens the bonding strength of bimetallic tubes. The joints are fractured at the reaction layers, and the fracture exhibits typical brittle characteristic. Three crack propagation paths are observed at the interface of Al/Cu bimetallic tubes.
KW - Bimetallic tubes
KW - Bonding strength
KW - Friction-based welding
KW - Intermetallic compound
UR - http://www.scopus.com/inward/record.url?scp=85028724158&partnerID=8YFLogxK
U2 - 10.1016/j.matdes.2017.08.065
DO - 10.1016/j.matdes.2017.08.065
M3 - 文章
AN - SCOPUS:85028724158
SN - 0264-1275
VL - 134
SP - 383
EP - 393
JO - Materials and Design
JF - Materials and Design
ER -