Microstructures and Mechanical Properties of Al<sub>3</sub>Ti/Al Composites Produced In Situ by High Shearing Technology

Zeng, Yan; Himmler, David; Randelzhofer, P.; Körner, Carolin

doi:10.1002/adem.201800259

Cited by 19 publications

(5 citation statements)

References 53 publications

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“…Mechanical stirring was particularly important for this system due to the difference between the density of the used alloy (2685 kg/m 3 ) and that of the Al 3 Ti intermetallics (3368 kg/m 3 ) [ 19 ]. To examine the effect of holding time at the required temperature, mechanical stirring was continued until the liquid metal was poured into the graphite mold [ 20 ] as shown in Figure 4 .…”

Section: Methodsmentioning

confidence: 99%

A Comparative Study of Grain Refining of Al-(7–17%) Si Cast Alloys Using Al-10% Ti and Al-4% B Master Alloys

Samuel

Songmené

et al. 2023

Materials

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The present article addresses solidification parameters, and includes analyses of the macrostructure and microstructure in the light of the results obtained from the thermal analysis, from which it is possible to conclude that undercooling (TS) and recalescence (TR) temperatures increase with the initial increase in titanium (Ti) concentration. If the concentration reaches approximately 0.25%, a rapid decrease in these temperatures is observed. Thereafter, the temperatures increase again with the further increase in Ti concentration, and eventually become constant. These temperatures also vary depending on the superheating and casting temperature. The ∆T parameter (i.e., TS − TR) decreases with the Ti concentration and, from a concentration of around 0.20% Ti, this parameter becomes zero. The grain size decreases with the Ti concentration. If the concentration exceeds about 0.20%, the grain size becomes the minimum. Another parameter to be considered is the interaction between the grain refiner and the traces of other metals in the base Al alloy. For example, Al-4%B can react with traces of Ti that may exist in the base alloy, leading to the reaction between boron (B) and Ti to form TiB2. Grain refinement is achieved primarily with TiB2 rather than AlB2, or both, depending on the Ti content in the given alloy.

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Section: Methodsmentioning

confidence: 99%

A Comparative Study of Grain Refining of Al-(7–17%) Si Cast Alloys Using Al-10% Ti and Al-4% B Master Alloys

Samuel

Songmené

et al. 2023

Materials

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“…Before experiments also utilized K2TiF6 salt-metal reactions to produce 5 vol. % Al3Ti/A356 composites [15]. They also investigated the effects of T6 heat treatment and Sr modification on the microstructural and mechanical properties of the composites.…”

Section: Introductionmentioning

confidence: 99%

Effect of Waste Titanium Chips Addition Into the Aluminum Alloys on Their Microstructure

Özer

Acar

Kısasöz

et al. 2021

Gazi University Journal of Science

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“…However, microstructural features are mainly responsible for the resulted performances. Several investigations have studied the effect of TiAl 3 area fraction on wear and tensile properties without considering the effect of their morphology [3][4][5]. Since the results reported for the wear resistance of the Al-TiAl 3 composites were very scattered, authors believe that another parameter such as morphology of intermetallic particles can strongly affect the mechanical properties, in particular tensile behavior as well as wear resistance.…”

Section: Introductionmentioning

confidence: 99%

Spatial and microstructural dependence of mechanical properties and wear performance of functionally graded Al–TiAl3 in situ composite

Yousefi

Doostmohammadi

2019

SN Appl. Sci.

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Effect of morphology and spatial distribution of TiAl 3 particles on the hardness, the tensile behavior and the wear performance of functionally graded Al-TiAl 3 in situ composite (FGC) was investigated. Initially, FGC was produced by interaction between solid Ti and liquid Al. Based on the spatial distribution and morphology of TiAl 3 particles in the microstructure of FGC, three distinctive regions including blocky-particle region, mixed-particle region (blocky and short plate particles) and lengthy plate-particle region were studied. Results of this study showed that the blocky-particle region had promoted tensile strength as well as highly improved wear resistance. In addition, this region with higher density of blocky particles and low interparticle spacing showed a brittle fracture. The mixed-particle region with a lower density of blocky particles had a ductile fracture mechanism while the plate-particle region showed cleavage fracture. The dominant wear mechanism for regions including blocky particles was determined to be mild oxidation while it was delamination wear for regions containing plate particles. Finally, correlation between mechanical properties, wear resistance and microstructure of FGC was discussed.

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Microstructures and Mechanical Properties of Al₃Ti/Al Composites Produced In Situ by High Shearing Technology

Cited by 19 publications

References 53 publications

A Comparative Study of Grain Refining of Al-(7–17%) Si Cast Alloys Using Al-10% Ti and Al-4% B Master Alloys

A Comparative Study of Grain Refining of Al-(7–17%) Si Cast Alloys Using Al-10% Ti and Al-4% B Master Alloys

Effect of Waste Titanium Chips Addition Into the Aluminum Alloys on Their Microstructure

Spatial and microstructural dependence of mechanical properties and wear performance of functionally graded Al–TiAl3 in situ composite

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Microstructures and Mechanical Properties of Al3Ti/Al Composites Produced In Situ by High Shearing Technology

Cited by 19 publications

References 53 publications

A Comparative Study of Grain Refining of Al-(7–17%) Si Cast Alloys Using Al-10% Ti and Al-4% B Master Alloys

A Comparative Study of Grain Refining of Al-(7–17%) Si Cast Alloys Using Al-10% Ti and Al-4% B Master Alloys

Effect of Waste Titanium Chips Addition Into the Aluminum Alloys on Their Microstructure

Spatial and microstructural dependence of mechanical properties and wear performance of functionally graded Al–TiAl3 in situ composite

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Microstructures and Mechanical Properties of Al₃Ti/Al Composites Produced In Situ by High Shearing Technology