Microstructural evolution of Ti–6Al–4V/UD-Cf/LAS composites joint brazed by graphene nanosheets reinforced composite filler.

Abstract A graphene nanosheets reinforced Ag-Cu composite filler (Ag-Cu + GNSs) was developed by introducing GNSs into Ag-Cu powder filler. Unidirectional carbon fiber reinforced lithium aluminosilicate matrix composites (UD-C f /LAS composites) and Ti–6Al–4V alloy were brazed with Ag-Cu + GNSs composite filler. The typical interfacial microstructure of joint was Ti–6Al–4V/Ti(s,s)/Ti 2 Cu/TiCu/Ag(s,s)/Ti 3 Cu 4 /Cu(s,s)+TiCu + TiC/Ti 3 Cu 4 /TiC + TiSi 2 /UD-C f /LAS composites. The in situ synthesized TiCu + TiC composite from the reaction between Ti and GNSs had the following benefits: 1) refined the microstructure of the joint; 2) reinforced the joint; 3) alleviated the thermal stress of the joint by constraining the growth of continuous Ti 3 Cu 4 intermetallic layers. Moreover, with the increase of GNSs content, the amount of TiCu + TiC phases increased. Ag(s,s) and Ti 3 Cu 4 became uniform and fine in the interlayer. Both the thickness of reaction layers and the size of granular Ti 3 Cu 4 and TiCu + TiC phases firstly increased and then decreased with the rise of the brazing temperature. On the contrary, the content of Ag based composite decreased at first and then increased. The highest shear strength of joints reached 45.5 MPa with 0.5% GNSs addition when brazed at 900 °C for 10 min. Based on the experimental results, the interface evolution mechanism of the Ti–6Al–4V/Ag-Cu + GNSs/UD-C f /LAS composites joint was investigated. Highlights • TC4/C f /LAS composites joints were brazed by GNSs reinforced composite filler. • The determination of interface reaction phases was realized by TEM. • Brazing temperature and addition of GNSs had influence on the joints microstructure. • The highest shear strength of joints reached 45.5 MPa. • Microstructural evolution mechanism and reactions of brazed joints were expounded. [ABSTRACT FROM AUTHOR]