Ultrafine-Grained Microstructure and Improved Mechanical Behaviors of Friction Stir Welded Cu and Cu-30Zn Joints

doi:10.1007/s40195-018-0719-3

Abstract

Abstract:

Ultra-strong joints of pure Cu and Cu-30Zn alloy were obtained by friction stir welding under flowing water. The effects of heat inputting condition and material characteristics on the morphologies, microstructures and mechanical properties of welding joints were studied. Defect-free stirring zones of pure Cu and Cu-30Zn were characterized by onion-ringed structure and plastic flowing bands, respectively. Both low stacking fault energy and fast cooling condition contributed to the formation of small recrystallized grains less than 1 μm in stirring zones. The welding joints in both materials exhibited enhanced mechanical performances due to ultrafine-grained microstructure in stirring zones and disappearance of soft heat-affected-zone. The technique of digital image correlation was used to study the tensile deformation behaviors of welding joints and verify the improved tensile properties.

Key words: Friction stir welding, Ultrafine grain, Mechanical properties, Stacking fault energy, Digital image correlation (DIC)

Yan-Fei Wang, Jian An, Kun Yin, Ming-Sai Wang, Yu-Sheng Li, Chong-Xiang Huang. Ultrafine-Grained Microstructure and Improved Mechanical Behaviors of Friction Stir Welded Cu and Cu-30Zn Joints[J]. Acta Metallurgica Sinica (English Letters), 2018, 31(8): 878-886.

Figures/Tables 7

Fig. 1 Optical images of FSW welds for pure Cu a, b and Cu-30Zn c, d for overall appearances a, c and stirring veins in SZs b, d. The coordinate system inserted in c denotes the principal directions of welding geometry, welding direction (WD), transverse direction (TD) and normal direction (ND)

Fig. 2 Cross-sectional SEM morphologies of FSW joints for pure Cu a-c and Cu-30Zn d-f in overall cross sections a, d, transition areas between the SZ and the BM b, e, and enlarged images for SZs c, f. AS and RS denote the advancing side and the retreating side of stirring geometry

Fig. 3 EBSD micrographs showing microstructures of FSW joints: a BM of Cu; b SZ of Cu; c BM of Cu-30Zn; d SZ of Cu-30Zn; e grain size (d) distributions in SZs; f distributions of grain boundary misorientations in SZs (d* represents the average grain size. The insets in b, d show the inverse pole figures of the SZs)

Fig. 4 TEM images in SZs of a pure Cu, b Cu-30Zn

Fig. 5 Hardness distributions in welding joints (the indentations were carried out along a line 500 μm far away beneath the friction surface on the cross section)

Fig. 6 a Tensile engineering stress-strain curves of FSW pure Cu, b engineering stress-strain curves of FSW Cu-30Zn, c strain hardening rate (Θ) and true stress (σT) versus true strain for ultrafine-grained SZs

Fig. 7 Macroscopic appearances and DIC-characterized strain fields of transverse samples for pure Cu a1-a3 and Cu-30Zn b1-b3: a1, b1 tensile specimens before and after test. The white frames mark the effective DIC measured areas; a2, b2 strain maps in the stage of nominally uniform plastic deformation; a3, b3 strain maps in the necking stage. ε ydenotes the strain along tensile direction Y, while ε x denotes the strain along transverse direction X. The numbers on the top of each strain subgraph indicate the applied strain; c1, c2 evolution of local strain (locations of A, B and C marked in a2, b2) with the tensile strain

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