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Experimental and numerical investigations of platinum foil/titanium plate interfaces prepared by explosive welding
https://orcid.org/http://orcid.org/0000-0002-4461-0201
Platinum/titanium (Pt/Ti) bimetal composite is of utmost interest to the electrochemical industry for its superior functionality. Here, an improved explosive welding (EW) technology was introduced to join Pt foil and Ti sheet, and the microstructure evolution of the achieved Pt/Ti joint as well as the thermodynamic behaviors during the EW process was systematically investigated by various microscopic observations and smoothed particles hydrodynamics (SPH) simulation. It was found that the Pt/Ti EW interface was featured by a straight metallurgical reaction layer with a width of ~ 30 μm, and its formation mechanism was related to localized melting followed by intense mechanical mixing of participant metals. In the reaction layer, both elements of Pt and Ti were detected, and the average phase was determined to be Pt0.69Fe0.31. The EBSD analyses revealed a remarkable grain structure change near the interface, such as grain orientation deflection in Pt matrix, heat-induced grain growth in Ti matrix, and the formation of extra fine nanograins in the reaction layer. The SPH simulation well captured the morphology features of the Pt/Ti interface, and quantificationally revealed the extreme thermodynamic states of high heat of ~ 2000 K, high pressure of ~ 5 GPa, and large strain of ~ 3 during the EW process. Finally, the nanoindentation results revealed inhomogenous mechanical behaviors near the bonding interface.
Experimental and numerical investigations of platinum foil/titanium plate interfaces prepared by explosive welding
https://orcid.org/http://orcid.org/0000-0002-4461-0201
Platinum/titanium (Pt/Ti) bimetal composite is of utmost interest to the electrochemical industry for its superior functionality. Here, an improved explosive welding (EW) technology was introduced to join Pt foil and Ti sheet, and the microstructure evolution of the achieved Pt/Ti joint as well as the thermodynamic behaviors during the EW process was systematically investigated by various microscopic observations and smoothed particles hydrodynamics (SPH) simulation. It was found that the Pt/Ti EW interface was featured by a straight metallurgical reaction layer with a width of ~ 30 μm, and its formation mechanism was related to localized melting followed by intense mechanical mixing of participant metals. In the reaction layer, both elements of Pt and Ti were detected, and the average phase was determined to be Pt0.69Fe0.31. The EBSD analyses revealed a remarkable grain structure change near the interface, such as grain orientation deflection in Pt matrix, heat-induced grain growth in Ti matrix, and the formation of extra fine nanograins in the reaction layer. The SPH simulation well captured the morphology features of the Pt/Ti interface, and quantificationally revealed the extreme thermodynamic states of high heat of ~ 2000 K, high pressure of ~ 5 GPa, and large strain of ~ 3 during the EW process. Finally, the nanoindentation results revealed inhomogenous mechanical behaviors near the bonding interface.
Experimental and numerical investigations of platinum foil/titanium plate interfaces prepared by explosive welding
https://orcid.org/http://orcid.org/0000-0002-4461-0201
Platinum/titanium (Pt/Ti) bimetal composite is of utmost interest to the electrochemical industry for its superior functionality. Here, an improved explosive welding (EW) technology was introduced to join Pt foil and Ti sheet, and the microstructure evolution of the achieved Pt/Ti joint as well as the thermodynamic behaviors during the EW process was systematically investigated by various microscopic observations and smoothed particles hydrodynamics (SPH) simulation. It was found that the Pt/Ti EW interface was featured by a straight metallurgical reaction layer with a width of ~ 30 μm, and its formation mechanism was related to localized melting followed by intense mechanical mixing of participant metals. In the reaction layer, both elements of Pt and Ti were detected, and the average phase was determined to be Pt0.69Fe0.31. The EBSD analyses revealed a remarkable grain structure change near the interface, such as grain orientation deflection in Pt matrix, heat-induced grain growth in Ti matrix, and the formation of extra fine nanograins in the reaction layer. The SPH simulation well captured the morphology features of the Pt/Ti interface, and quantificationally revealed the extreme thermodynamic states of high heat of ~ 2000 K, high pressure of ~ 5 GPa, and large strain of ~ 3 during the EW process. Finally, the nanoindentation results revealed inhomogenous mechanical behaviors near the bonding interface.
Experimental and numerical investigations of platinum foil/titanium plate interfaces prepared by explosive welding
Archiv.Civ.Mech.Eng
Wang, Fei (author) / Yang, Ming (author)
2022-12-29
Article (Journal)
Electronic Resource
English
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