Your search keyword '"Zhu, Kai"' showing total 3 results

1. Disclosing the formation mechanisms of Ag-containing Laves phases at the atomic scale in an Al-Cu-Mg-Ag alloy.

Author

Liu, Qilong, Li, Xiwu, Xiao, Wei, Li, Zhihui, Zhu, Kai, Wen, Kai, Yan, Lizhen, Li, Yanan, Zhang, Yongan, Sui, Manling, and Xiong, Baiqing

Subjects

LAVES phases (Metallurgy), COPPER, FOCUSED ion beams, SILVER alloys, ALUMINUM alloys, TRANSMISSION electron microscopy, DENSITY functional theory, ALLOYS

Abstract

• The (Al x Cu y Ag 1-x-y) 2 Mg phases in Al-3.6Cu-1.0Mg-0.4Ag alloys are hexagonal C14-type. • Atom occupancy of (Al x Cu y Ag 1-x-y) 2 Mg in Al-3.6Cu-1.0Mg-0.4Ag alloy was identified. • (Al x Cu y Ag 1-x-y) 2 Mg is formed by the reaction L ⇌ Al 2 CuMg + (Al x Cu y Ag 1-x-y) 2 Mg. • The role of Ag in forming the Ag-containing Laves phases is deeply revealed. In addition to the three well-known Ag-related precipitates (Ω, X′ and Z) in the Al-Cu-Mg-Ag alloys, Ag can also be involved in the formation of the as-cast second phases. However, the effect of Ag addition in Al-Cu-Mg-Ag alloys has not been completely studied and even the structure of the as-cast Ag-containing phases is still controversial. By employing the focused ion beam (FIB) combined with transmission electron microscopy (TEM) techniques and density functional theory (DFT) calculations, the formation mechanisms of the Ag-containing phases in the as-cast Al-Cu-Mg-Ag alloys have been investigated. The Ag-containing phases are a series of hexagonal C14-type Laves phases with continuously varying Ag concentrations, described as (Al x Cu y Ag 1- x - y) 2 Mg. Moreover, the specific occupancy sites of the atoms in (Al x Cu y Ag 1- x - y) 2 Mg were determined. The formation of the (Al x Cu y Ag 1- x - y) 2 Mg can be attributed to the stronger Ag-induced aggregation of solute atoms in the initial stage and the establishment of strong Ag- X (X = Al, Mg and Ag) bonding in the Ag-containing phases. Furthermore, our experiments have revealed the solidification sequence of Al-Cu-Mg-Ag alloys, and pointed out that (Al x Cu y Ag 1- x - y) 2 Mg is formed at a lower temperature (493.9 °C) through the reaction L ⇌ Al 2 CuMg + (Al x Cu y Ag 1- x - y) 2 Mg. The study could have positive implications for refinement of the Al-Cu-Mg-Ag quaternary phase diagram and promote the composition-property design of novel aluminum alloys based on (Al x Cu y Ag 1- x - y) 2 Mg in the future. [Display omitted] [ABSTRACT FROM AUTHOR]

Published

2024

2. Influence of Material Removal Strategy on Machining Deformation of Aluminum Plates with Asymmetric Residual Stresses.

Author

Li, Yang, Li, Ya-Nan, Li, Xi-Wu, Zhu, Kai, Zhang, Yong-An, Li, Zhi-Hui, Yan, Hong-Wei, and Wen, Kai

Subjects

ALUMINUM plates, RESIDUAL stresses, ALUMINUM alloys, DEFORMATIONS (Mechanics), MACHINING

Abstract

In this paper, the effects of material removal strategies and initial stress states on the machining deformation of aluminum alloy plates were investigated through a combination of finite element simulation and experiments. We developed different machining strategies described by Tm+Bn, which removal m mm materials form top and n mm materials from the bottom of the plate. The results demonstrate that the maximum deformation of structural components with the T10+B0 machining strategy could reach 1.94 mm, whereas with the T3+B7 machining strategy was only 0.065 mm, decreasing by more than 95%. The asymmetric initial stress state had a significant impact on the machining deformation of the thick plate. The machined deformation of thick plates increased with the increase in the initial stress state. The concavity of the thick plates changed with the T3+B7 machining strategy due to the asymmetry of the stress level. The deformation of frame parts was smaller when the frame opening was facing the high-stress level surface during machining than when it was facing the low-stress level. Moreover, the modeling results for the stress state and machining deformation were accurate and in good accordance with the experimental findings. [ABSTRACT FROM AUTHOR]

Published

2023

3. Microstructural Characterization of the As-Cast and Homogenized Al-Cu-Mg-Ag Alloy.

Author

Lin, Haitao, Zhu, Kai, Liu, Qilong, Chen, Lifang, Wang, Zhengan, and Li, Xiwu

Subjects

*HYPEREUTECTIC alloys, *CRYSTAL grain boundaries, *ALUMINUM ingots, *ALUMINUM alloys, *HEAT resistant alloys, *DIFFERENTIAL scanning calorimetry, *EUTECTIC structure, *ALLOYS

Abstract

In this study, the as-cast microstructure and the evolution of the homogenized microstructure of large-scale industrialized Al-Cu-Mg-Ag heat-resistant aluminum alloy ingots were investigated by means of optical microscopy (OM), scanning electron microscopy (SEM), energy dispersive analysis (EDS), and differential scanning calorimetry (DSC). The results indicate that the dendritic segregation is evident in the ingot along the radial direction, and the grain boundaries are decorated with lots of net-shaped continuous eutectic structures. With the homogenization time extension and the homogenization temperature increase, the eutectic phases (i.e., the primary Al2Cu phase, the Al2CuMg phase, and the AlCuMgAg quaternary phase) at the grain boundaries gradually dissolve back into the matrix. Meanwhile, most of the dendritic grain boundaries gradually become sparse and thinner. Finally, it is found that the optimal homogenization regime of the Al-Cu-Mg-Ag alloy is 420 °C/5 h+480 °C/8 h+515 °C/24 h. [ABSTRACT FROM AUTHOR]

Published

2023