Strength and structure of the bonding interface in friction-welded 1050 aluminum and AZ31 magnesium alloy joint.

Morozümi, Shotaro; Sakurai, Takeo; Minegishi, Tomoya; Kato, K.; Tokisue, Hiroshi

doi:10.2464/jilm.40.209

Cited by 11 publications

(4 citation statements)

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“…In this case, the joint efficiency of some joints was obtained 100% or higher, because the parallel part length of the joint tensile test specimen was shorter. The IMC interlayer at the weld interface of the joint affected to the tensile strength of its joint, and that was also reported by some authors although the friction welding conditions differed [28][29][30]. Fig.…”

Section: Properties Of As-welded Jointsupporting

confidence: 57%

Joint properties of friction welded joint between pure magnesium and pure aluminium with post-weld heat treatment

2015

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Section: Properties Of As-welded Jointsupporting

confidence: 57%

Joint properties of friction welded joint between pure magnesium and pure aluminium with post-weld heat treatment

2015

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“…Therefore, it is most likely that Li is dissolved in Al 3 Mg 2 without changing the crystal structure. It should be noted that the reaction phases observed in this Mg-Li/pure Al joint system are different from a previously reported AZMg/1050Al joint system fabricated by the friction welding method [13].…”

Section: Microstructurementioning

confidence: 82%

Fabrication of pure Al/Mg–Li alloy clad plate and its mechanical properties

Matsumoto

Watanabe

Hanada

2005

Journal of Materials Processing Technology

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“…According to Morozumi [6] and Hirano [7], when a Mg-Al-Zn alloy and Al were firmly bonded, an intermetallic compound (IMC) layer of Mg-Al system was formed between the Mg-Al-Zn alloy substrate and the Al layer. Moreover, Matsumoto [8] reported that Al 3 Mg 2 was formed as the IMC when the Mg-Li alloy and Al were firmly bonded.…”

Section: Intermetallic Compoundmentioning

confidence: 99%

“…Figure 9 reveals that the existence of Li in the Al/Mg-alloy retards the growth of the IMC. Morozumi [6] reported the thickness of Al 3 Mg 2 IMC was 20 µm when the AZ31 alloy and Al were bonded by friction welding. Hiraishi [9] reported the thickness of diffusion layer was 60 µm when the AZ31B and Al were bonded by pressure welding.…”

Section: Intermetallic Compoundmentioning

confidence: 99%

Corrosion Resistance and Tensile Property of Al-Coated Mg-Li Alloy Produced by Hot Extrusion

Tomita

Matsuura

Ohno

et al. 2015

KEM

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Al-coated Mg-Li alloy rods and plates having a homogeneous coating layer of 180μm in thickness have been produced by hot extrusion of Mg-Li alloy billets together with Al disks. The Al-coated Mg-Li alloy exhibits an excellent corrosion resistance in a weight-loss test with a 0.5 mass% HCl aqueous solution, and it has been revealed by a potentiometric corrosion test with a 3 mass% NaCl aqueous solution that the Al-coated Mg-Li alloy has the same electric potential as that of pure Al. Al-coated Mg-Li alloy sheets produced by hot forging of the extruded plates exhibits good elongation of 22 %, 40 % and 130 % at room temperature, 200 °C and 300 °C, respectively.

show abstract

Strength and structure of the bonding interface in friction-welded 1050 aluminum and AZ31 magnesium alloy joint.

Cited by 11 publications

References 0 publications

Joint properties of friction welded joint between pure magnesium and pure aluminium with post-weld heat treatment

Joint properties of friction welded joint between pure magnesium and pure aluminium with post-weld heat treatment

Fabrication of pure Al/Mg–Li alloy clad plate and its mechanical properties

Corrosion Resistance and Tensile Property of Al-Coated Mg-Li Alloy Produced by Hot Extrusion

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