Microstructure and property inhomogeneity investigations of bonded Zr/Ti/steel trimetallic sheet fabricated by explosive welding

Compared to Ti/steel bimetallic sheets, Zr/Ti/steel trimetallic sheets have improved service performance in severely corrosive environments because the corrosion resistance of zirconium and titanium are complementary. The inhomogeneities of the microstructure and mechanical properties as well as the...

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Bibliographic Details
Published in:Journal of alloys and compounds 2017-03, Vol.698, p.835-851
Main Authors: Ning, Jie, Zhang, Lin-jie, Xie, Miao-xia, Yang, Han-Xin, Yin, Xian-qing, Zhang, Jian-xun
Format: Article
Language:English
Subjects:
Bend tests
Bimetals
Corrosion resistance
Deformation mechanisms
Diamond pyramid hardness tests
Digital imaging
Explosive bonding
Explosive welding
Inhomogeneity
Intermetallic compounds
Mechanical properties
Metal sheets
Microstructure
Plastic deformation
Shear strength
Steel
Steel plates
Steels
Strain inhomogeneity between layers
Tensile tests
Titanium alloys
Welding
Zr/Ti/steel composite sheet
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Summary:Compared to Ti/steel bimetallic sheets, Zr/Ti/steel trimetallic sheets have improved service performance in severely corrosive environments because the corrosion resistance of zirconium and titanium are complementary. The inhomogeneities of the microstructure and mechanical properties as well as the underlying mechanism of the interactions in the Zr/Ti/steel trimetallic composite sheets fabricated by explosive welding were investigated. The shear strength of the Ti/steel interface and Zr/Ti interface was found to be anisotropic and isotropic respectively, which could be explained by the wide and unambiguous wavy morphology of the former and relatively narrow and obscure wavy morphology of the latter. A transient strain field on the bending specimen was achieved through the digital image correlation (DIC) method during a bending test and it was found that the change of von Mises strain across the Ti/steel interface was much more significant than that across the Zr/Ti interface. This could be related to the through-thickness heterogeneous mechanical properties verified by Vickers hardness tests and tensile tests of the stratified samples of the Zr/Ti/steel plate. Large blocks of FeTi intermetallic compounds were formed in the local melted zone (LMZ) at the Ti/steel interface, while uncoordinated plastic deformation across the interface resulted in the failure appearing at the Ti/steel interface during the bending test. Importantly, the values of shear strength and impact energy of the studied Zr/Ti/steel sheet met the requirements of ASME S264. [Display omitted] •Structural inhomogeneity of Zr/Ti/steel trimetallic sheet was studied.•Mechanical inhomogeneity of Zr/Ti/steel trimetallic sheet was studied.•Variation of chemical composition across both interfaces was studied.•Dependence of shear strength of both interfaces on shear direction was compared.•Uncoordinated plastic strain across both interfaces in bending test was studied.
ISSN:0925-8388
1873-4669
DOI:10.1016/j.jallcom.2016.12.213