Zhao Yuliang, Lin Bo, Song Dongfu, Zheng Donghai, Sun Zhenzhong, Xie Chunxiao, Zhang Weiwen
Neutron Scattering Technical Engineering Research Center, School of Mechanical Engineering, Dongguan University of Technology, Dongguan 523808, China.
National Engineering Research Centre of Near-net-shape Forming for Metallic Materials, South China University of Technology, Guangzhou 510641, China.
Materials (Basel). 2019 Nov 26;12(23):3904. doi: 10.3390/ma12233904.
The effect of compound fields of ultrasonic vibration and applied pressure (UV+AP) on three-dimensional (3D) microstructure and tensile properties of recycled Al-Cu-Mn-Fe-Si alloys was systematically studied using conventional two-dimensional (2D) microscopy, synchrotron X-ray tomography, and tensile test. The properties of UV+AP treated alloys with the pouring temperature of 740, 710 and 680 °C were compared when those alloys achieved after gravity casting. After UV+AP treatment, the alloy with pouring temperature of 710 °C show the smallest grain size. Also, the sizes of Fe-rich phases and AlCu are greatly reduced and their 3D morphologies are compacted. The mechanical properties of UV+AP treated alloys are relatively higher than those measured for gravity cast equivalents. This improvement can be explained by the synergistic effect of acoustic cavitation, acoustic streaming, and force-feeding, which resulted in the dendrite fragmentation, uniform solute distribution, and microstructural refinement. The Orowan strengthening and solution strengthening were identified as the main strengthening mechanisms.
采用传统二维显微镜、同步辐射X射线断层扫描和拉伸试验,系统研究了超声振动和外加压力复合场(UV+AP)对再生Al-Cu-Mn-Fe-Si合金三维(3D)微观结构和拉伸性能的影响。比较了重力铸造后达到的740、710和680℃浇注温度的UV+AP处理合金的性能。经过UV+AP处理后,浇注温度为710℃的合金晶粒尺寸最小。此外,富铁相和AlCu的尺寸大幅减小,其三维形态更加致密。UV+AP处理合金的力学性能相对高于重力铸造同等合金的力学性能。这种改善可以通过声空化、声流和强制补缩的协同作用来解释,这些作用导致枝晶破碎、溶质分布均匀和微观结构细化。奥罗万强化和固溶强化被确定为主要强化机制。