Increased hot forgeability of 2024Al/Al18B4O33w whisker composites at high strain rates

Whisker reinforced aluminum alloy composites are attractive for structural applications in automotive and aerospace applications. However, their forgeability is limited by their poor ductility at room temperature. The effects of temperatures (350-520 degrees C) and strain rates (0.01-50 s(-1)) on the resistance to microcracking and on the closure of voids are investigated for 2024Al/Al(18)B(4)O(33)w whisker composite as well as unreinforced AA2024 alloy. Under elevated temperature and high strain rate (>450 degrees C, >1.0 s(-1)), there are less cracks and no axial splitting on the surface of 2024Al/Al(18)B(4)O(33)w composite. Test results show lower flow stresses and incipient melting at higher temperatures enable better tolerance of whisker matrix strain mismatch at the interface during hot compression resulting in increased stabilization of flow stresses. While higher strain rates contribute to increased strain rate hardening, whisker rotation and void closure. It is interesting to note that the unreinforced AA2024 alloy experiences flow localization, surface cracking and plastic instability at temperatures higher than 450 degrees C but the presence of Al(18)B(4)O(33)in the composite seems to better resist these failure mechanisms resulting in higher forgeability. (C) 2017 Elsevier B.V. All rights reserved.