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Interface microstructural control by probe length adjustment in friction stir welding of titanium and steel lap joint
Highlights The titanium and steel were tightly bonded together. The joint interface microstructure was well controlled by parameter adjustment. Both of non-intermixed and intermixed joint interfaces were observed. The joint interfaces were consisted of β-Ti and Fe–Ti intermetallic compound.
Abstract The dissimilar lap joining of commercially pure Ti (CP-Ti) plate of 1.0mm in thickness and structural steel (SPCC) plate of 3.2mm in thickness was conducted by friction stir welding using different tools with probe lengths from 0.8 to 1.2mm for the purpose of controlling the joint interface microstructure. The sound joints showing the base plate fracture of CP-Ti have been obtained by using the tools with the probe lengths of 0.9 and 1.0mm. The transmission electron microscope examination revealed the two types of the interface microstructure. One was a non-intermixed type interface with a single interlayer of about 50–100nm in thickness, composed of FeTi intermetallic compound and β-Ti phase at the joint with the probe length of 0.9mm. The other was an intermixed interface with lamellar structure in which a FeTi or FeTi+Fe2Ti intermetallic compound layer of about 100nm in thickness and a β-Ti layer of about 1μm in thickness were alternately formed at the joint with the probe length of 1.0mm.
Interface microstructural control by probe length adjustment in friction stir welding of titanium and steel lap joint
Highlights The titanium and steel were tightly bonded together. The joint interface microstructure was well controlled by parameter adjustment. Both of non-intermixed and intermixed joint interfaces were observed. The joint interfaces were consisted of β-Ti and Fe–Ti intermetallic compound.
Abstract The dissimilar lap joining of commercially pure Ti (CP-Ti) plate of 1.0mm in thickness and structural steel (SPCC) plate of 3.2mm in thickness was conducted by friction stir welding using different tools with probe lengths from 0.8 to 1.2mm for the purpose of controlling the joint interface microstructure. The sound joints showing the base plate fracture of CP-Ti have been obtained by using the tools with the probe lengths of 0.9 and 1.0mm. The transmission electron microscope examination revealed the two types of the interface microstructure. One was a non-intermixed type interface with a single interlayer of about 50–100nm in thickness, composed of FeTi intermetallic compound and β-Ti phase at the joint with the probe length of 0.9mm. The other was an intermixed interface with lamellar structure in which a FeTi or FeTi+Fe2Ti intermetallic compound layer of about 100nm in thickness and a β-Ti layer of about 1μm in thickness were alternately formed at the joint with the probe length of 1.0mm.
Interface microstructural control by probe length adjustment in friction stir welding of titanium and steel lap joint
Gao, Y. (author) / Nakata, K. (author) / Nagatsuka, K. (author) / Liu, F.C. (author) / Liao, J. (author)
2014-08-12
7 pages
Article (Journal)
Electronic Resource
English
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