Your search keyword '"Wei, Qiuyun"' showing total 2 results

1. Effect of cooling rates and Fe contents on microstructure evolution of Al-Cu-Mn-Mg-Fe-Si alloys.

Author

He, Weixiang, Zhao, Yuliang, Wei, Qiuyun, Liu, Huan, Song, Dongfu, and Sun, Zhenzhong

Subjects

*COPPER, *RATE of nucleation, *ULTRASONIC effects, *X-ray imaging, *MECHANICAL alloying, *ALLOYS

Abstract

During the solidification process, the recycled Al-Cu alloys form coarse Fe-rich phases, which seriously deteriorate the mechanical properties of the alloy. The study employed optical microscope (OM), scanning electron microscopy (SEM) with energy dispersive spectroscopy (EDS), and synchrotron X-ray imaging to investigate the impact of cooling rate and Fe contents on the growth of Fe-rich phases, Al 2 Cu, and pores in recycled Al-Cu-Mn-Mg-Fe-Si alloys under synergistic effect ultrasonic melt processing (USMP) and Al-Ti-B. USMP can homogenize the distribution of TiB 2 particles and provides more nucleation sites for the formation of Fe-rich phases. Under the synergistic effect of USMP and Al-Ti-B, increasing the cooling rate,the volume fractions of Fe-rich phases in 0.7FeUB (0.7 wt%Fe + USMP + Al-Ti-B) and 1.2FeUB (1.2 wt%Fe + USMP + Al-Ti-B) alloys decreased from 8.92% and 16.52% to 8.03% and 14.73%, respectively. The volume fraction of Al 2 Cu increased from 4.06% and 3.13% to 4.37% and 3.54%, respectively. Furthermore, the three-dimensional (3D) morphology of Fe-rich phases and Al 2 Cu became more compact and uniform. The volume fraction of pores in the 1.2FeUB alloy decreased from 0.412% to 0.072%. In-situ synchrotron X-ray radiography revealed that increasing cooling rates led to increased nucleation undercooling of primary α-Al and Fe-rich phases. These phenomena can be attributed to the combined effects of ultrasonic cavitation, ultrasonic streaming, and an increased cooling rate. These factors serve to homogenize the alloy composition, ensure uniform distribution of TiB 2 particles, inhibit element diffusion, reduce solute segregation, and ultimately lead to the refinement of the grain size, α-Al, Fe-rich phases, and Al 2 Cu, while also inhibiting pore growth. • Increasing the cooling rate under the synergistic effect of USMP and Al-Ti-B, refine the grain size. • Under the synergistic effect of USMP and Al-Ti-B, increasing the cooling rate resulted in a more compact 3D morphology. • Increasing the cooling rate increases the nucleation undercooling and reduces the size of α-Al and Fe-rich phases. [ABSTRACT FROM AUTHOR]

Published

2024

2. Effect of Ultrasonic Treatment and Squeeze Casting on the Microstructural Refinement of Al–Cu–Mn Alloys.

Author

Zhao, Yuliang, He, Weixiang, Yang, Yang, Liu, Huan, Wei, Qiuyun, Lin, Bo, Song, Dongfu, Sun, Zhenzhong, and Zhang, Weiwen

Subjects

*SQUEEZE casting, *ULTRASONIC effects, *TRANSMISSION electron microscopes, *SCANNING electron microscopes, *DIFFERENTIAL scanning calorimetry, *ALLOYS

Abstract

Aluminum–copper-based alloy has a broad liquidus to solidus temperature range, making it susceptible to the formation defects such as pores and shrinkage pores during the process of solidification. Hence, ultrasonic vibration and squeeze casting can help to refine the microstructure and eliminate the formation of pores. In this paper, we used an optical microscope, scanning electron microscope, transmission electron microscope, differential scanning calorimetry, and thermal analysis to study the ultrasonic treatment (UT) and squeeze casting (SC) on the as-cast and heat-treated microstructure of Al–Cu–Mn alloys. The results show that a significant refinement can be obtained by the compound field compared with that of the individual field. The applied UT time is 30 s and 120 s, respectively. The smallest grain size and the finest Al2Cu particles are observed in the alloy with a treated time of 120 s. This is due to the ultrasonic field breaking the dendrites and promoting the flow of molten Al; squeeze casting increases the cooling rate and stimulates the nucleation temperature of α-Al. The size of the θ′ phase after compound field treatment is smaller because more Cu atoms are dissolved in the Al matrix, so the θ' strengthening phase is finely dispersed in the Al alloy matrix. It is concluded that the compound field of UT and SC is a potentially advantageous process to refine the microstructure of Al alloys. [ABSTRACT FROM AUTHOR]

Published

2024