Achieving high damping capacity and strength simultaneously in a high-zinc aluminum alloy via melt spinning and hot extrusion

High-Zn AlZn alloys exhibited a high damping capacity but a low strength, which restricted their applications in many structural components under vibration conditions. To overcome this problem, grain refinement and alloying (by adding Mg, Cu and Zr) were employed to enhance the strength of high-Zn AlZn alloys while retaining the high damping capacity. In this work, fine-grained high-Zn AlZnMgCuZr alloys extruded at different extrusion ratios were achieved by a combination of melt spinning and hot extrusion. The rapidly-solidified and extruded alloys were observed to contain numerous second-phase particles (Zn and eta-phase) at grain boundaries, high-density nano-sized precipitates (GP-zones and eta'-phase) present in equiaxed alpha-Al grains, along with high solute solubility and many ribbon interfaces. These special microstructural features provided the high-Zn alloys with excellent room/high-temperature damping capacity and high strength. With increasing extrusion ratio, the damping capacity decreased gradually due to the reduction in the density of second-phase particles, the increases in both solute solubility of alpha-Al matrix and density of coherent GP-zones, and the improvement of bonding strength of ribbon interfaces. The overall high strength of the high-Zn alloys was attributed to strong grain refinement strengthening, solution strengthening and precipitation strengthening.

Automated summary

This study improved the strength and damping capacity of high-Zn AlZn alloys through grain refinement and alloying, and achieved the preparation of fine-grained high-Zn AlZnMgCuZr alloys. The microstructure of the alloys included numerous second-phase particles, high-density nano-sized precipitates, high solute solubility, and many interfaces. These special structural features provided the alloys with excellent strength and damping capacity.