Your search keyword '"self-inoculation method"' showing total 4 results

1. Solidification behavior and rheo-diecasting microstructure of A356 aluminum alloy prepared by self-inoculation method

Author

Ming Li, Ying Ma, Cao Chi, Xiaofeng Huang, and Yuandong Li

Subjects

010302 applied physics, Materials science, lcsh:T, Metallurgy, Alloy, Metals and Alloys, Nucleation, 02 engineering and technology, engineering.material, 021001 nanoscience & nanotechnology, Microstructure, 01 natural sciences, Die casting, lcsh:Technology, Isothermal process, Dendrite (crystal), semisolid, self-inoculation method, secondary solidification, dendrite fragments, primary particles, eutectic structure, lcsh:Manufactures, 0103 physical sciences, Materials Chemistry, engineering, Slurry, 0210 nano-technology, lcsh:TS1-2301, Eutectic system

Abstract

Semisolid slurry of A356 aluminum alloy was prepared by self-inoculation method, and the microstructure and solidification behavior during rheo-diecasting process were investigated. The results indicate that the semisolid slurry of A356 aluminum alloy can be prepared by self-inoculation method at 600 °C. Primary α-Al particles with fine and spherical morphologies are uniformly distributed when the isothermal holding time of slurry is 3 min. Liquid phase segregation occurs during rheo-diecasting process of semisolid slurry and the primary particles (α1) show obvious plastic deformation in the area of high stress and low cooling rate. A small amount of dendrites resulting from the relatively low temperature of the shot chamber at the initial stage of secondary solidification are fragmented as they pass through the in-gate during the mould filling process. The amount of dendrite fragments decreases with the increase of filling distance. During the solidification process of the remaining liquid, the nucleation rate of secondary particles (α2) increases with the increase of cooling rate, and the content of Si in secondary particles (α2) are larger than primary particles (α1). With the increase of cooling rate, the content of Si in secondary particles (α2) gradually increases. The morphologies of eutectic Si in different parts of die casting are noticeably different. The low cooling rate in the first filling positions leads to coarse eutectic structures, while the high cooling rate in the post filling positions promotes small and compact eutectic structures.

Published

2017

2. Effects of Forming Processes on Microstructures and Mechanical Properties of A356 Aluminum Alloy Prepared by Self-inoculation Method

Author

Li Ming, Li Yuan-dong, Wang Zong-gang, Yang Wen-long, and Zhang Yu

Subjects

Materials science, A356 aluminum alloy, Alloy, 02 engineering and technology, engineering.material, 01 natural sciences, Isothermal process, semisolid, 0103 physical sciences, General Materials Science, Lamellar structure, eutectic structure, Composite material, Materials of engineering and construction. Mechanics of materials, Eutectic system, 010302 applied physics, Mechanical Engineering, Forming processes, 021001 nanoscience & nanotechnology, Condensed Matter Physics, Microstructure, equipment and supplies, Mechanics of Materials, self-inoculation method, TA401-492, engineering, Slurry, Particle, 0210 nano-technology, solidification behavior

Abstract

Semisolid slurry of A356 aluminum alloy was prepared by Self-Inoculation Method (SIM), and the microstructures and solidification behavior of rheo-forming process in different forming processes were researched. The results indicate that semisolid slurry of A356 aluminum alloy can be prepared by Self-Inoculation Method at 600ºC. Primary α-Al particles with fine and spherical morphology are uniformly distributed when the isothermal holding time of slurry is 3 min. The different forming processes for semisolid rheo-forming can be regarded as the effect of cooling rate on rheo-forming. The primary particle sizes and shape factors are gradually increasing with the increase of cooling rate. The sizes of secondary particles are gradually increasing with the decrease of cooling rate, and the amount of secondary particles in the same areas are gradually decreasing with the decrease of cooling rate. The morphologies of eutectic Si are gradually coarsening from fibrous to needle-like in different forming processes, while the sizes and the lamellar spacing of the eutectic Si are gradually increasing with the decrease of cooling rate. The mechanical properties of the semisolid forming components are gradually increasing with the increase of cooling rate and forming pressure.

Published

2019

3. Secondary Solidification Behavior of A356 Aluminum Alloy Prepared by the Self-Inoculation Method

Author

Li Yuandong, Xiaofeng Huang, Ming Li, Renguo Guan, and Ying Ma

Subjects

lcsh:TN1-997, A356 aluminum alloy, Materials science, Alloy, Nucleation, 02 engineering and technology, engineering.material, 01 natural sciences, Isothermal process, semisolid, 0103 physical sciences, General Materials Science, eutectic structure, Supercooling, lcsh:Mining engineering. Metallurgy, Eutectic system, 010302 applied physics, self-inoculation method, secondary solidification behavior, Metallurgy, Metals and Alloys, 021001 nanoscience & nanotechnology, Die casting, Grain size, engineering, Particle, 0210 nano-technology

Abstract

Semisolid slurry of A356 aluminum alloy was prepared by Self-Inoculation Method, and the secondary solidification behavior during rheo-diecasting forming process was researched. The results indicate that the component with non-dendritic and uniformly distributed microstructures can be produced by Rheo-Diecasting (RDC) process (combining Self-inoculation Method (SIM) with High Pressure Die Casting (HPDC)). The isothermal holding time of the slurry has large effect on primary particles, but has little effect on secondary particles. Growth rate of the primary particles in the isothermal holding process conforms to the dynamic equation of Dt3 − D03 = Kt. The suitable holding time for rheo-diecasting of A356 aluminum alloy is 3 min. During filling process, the nucleation occurs throughout the entire remaining liquid, and nuclei grow stably into globular particles with the limited grain size of 6.5μm firstly, then both α1 and α2 particles appear unstable growth phenomenon due to the existence of constitutional undercooling. The average particle sizes and shape factors of both α1 and α2 are decreasing with the increase of filling distance due to different cooling rate in different positions. The growth rate of the eutectic in RDC is 4 times faster than HPDC, which is mainly due to the limitation of α2 particles in RDC process. The average eutectic spacings are decreasing with the increase of filling distance.

Published

2017

4. Effects of Pouring Temperature on Microstructure and Mechanical Properties of the A356 Aluminum Alloy Diecastings

Author

Ming Li, Yuandong Li, and Hongwei Zhou

Subjects

010302 applied physics, Materials science, Semisolid, Self-Inoculation Method, Mechanical Engineering, Mechanical Property, 02 engineering and technology, 021001 nanoscience & nanotechnology, Condensed Matter Physics, 01 natural sciences, Primary a-Al Grain, Mechanics of Materials, Secondary a-Al Grain, Eutectic Si, 0103 physical sciences, TA401-492, General Materials Science, 0210 nano-technology, Humanities, Materials of engineering and construction. Mechanics of materials

Abstract

Diecastings of the A356 aluminum alloy were produced by rheo-diecasting (RDC) and High pressure die casting (HPDC), the microstructures of primary solidification, secondary solidification and eutectic Si of diecastings with different pouring temperature were explored and the mechanical properties of different parameters were tested. The result shows that the primary α-Al grains in RDC with self-inoculation method (SIM) are smaller and rounder than the dendrite structure in HPDC. During the RDC process, the amount of primary α-Al grains, average grain size and the lamellar spacing of the eutectic Si increase with the decrease of the melt treatment temperature. While the average grain size and the shape factor are gradually increasing with the increase of melt treatment temperature. As a result, RDC can significantly improve the mechanical properties of the A356 aluminum alloy compared with HPDC, the mechanical properties are optimal at 600°Cwith the tensile strength and elongation are 268.67MPa and 6.8%, respectively.