Your search keyword '"Suwaree Chankitmunkong"' showing total 5 results

1. Microstructure Evolution of an Al–Fe–Ni Alloy with Zr and Sc Additions Upon Different Cooling Rates During Solidification for Improving the Mechanical and Electrical Conductivity Properties

Author

Suwaree Chankitmunkong, Dmitry G. Eskin, and Chaowalit Limmaneevichitr

Subjects

Al-Fe-Ni alloy, Materials science, electrical conductivity, Alloy, Metallurgy, Intermetallic, chemistry.chemical_element, engineering.material, Microstructure, Precipitation hardening, chemistry, Electrical resistivity and conductivity, Aluminium, Casting (metalworking), engineering, solidification, precipitation hardening, Eutectic system

Abstract

Al-Fe-Ni eutectic alloys has high potential for being alternative aluminum alloys for various electronic and electrical applications instead of conventional low-conductivity Al casting alloys. Furthermore, the addition of Zr and Sc up to 0.3-0.6 wt% improves the hardness for high temperature applications, which is a result of the finer Al-Fe-Ni eutectic structure, and precipitation hardening of Al3Zr and/or Al3Sc nanoprecipitates. Thus, the aim of the present contribution is to analyze the microstructure features changes in an Al-1.75Fe-1.25Ni eutectic alloy upon different cooling rates during solidification. The features of Al-Fe-Ni eutectics and intermetallics were studied quantitatively, and the mechanical properties and electrical conductivity were measured. Faculty of Engineering at KMUTT (Strong Research Initiative 2020); EPSRC (UK) project UltraMelt2 (EP/R011095/1).

Published

2021

2. Structure refinement, mechanical properties and feasibility of deformation of hypereutectic Al-Fe-Zr and Al-Ni-Zr alloys subjected to ultrasonic melt processing

Author

Suwaree Chankitmunkong, Dmitry G. Eskin, and Chaowalit Limmaneevichitr

Subjects

Materials science, Annealing (metallurgy), 020502 materials, Mechanical Engineering, Metallurgy, Al-Ni alloy, ultrasonic melt processing, Nucleation, Intermetallic, 02 engineering and technology, 021001 nanoscience & nanotechnology, Condensed Matter Physics, Precipitation hardening, 0205 materials engineering, Mechanics of Materials, Al-Fe alloy, Ultimate tensile strength, hypereutectic alloy, General Materials Science, 0210 nano-technology, Ductility, precipitation hardening, Solid solution, Eutectic system

Abstract

© 2020 The Author(s). Hypereutectic Al–Fe and Al–Ni alloys offer a potentially attractive combination of properties, e.g. high-temperature strength and stability, high elastic modulus and low coefficient of thermal expansion. This potential, however, cannot be reached unless the structure of these alloys is refined so that their processing becomes possible. In this study, we for the first time apply ultrasonic melt processing for refining the structure of hypereutectic Al-4% Fe and Al-8% Ni alloys with 0.3 wt% Zr addition. Both primary Al3Fe and Al3Ni particles as well as aluminum/eutectic grains are significantly refined. It is suggested that cavitation-induced fragmentation of primary Al3Zr crystals plays a significant role in the nucleation of intermetallics as well as aluminum. Furthermore, the hardness and tensile properties of the alloys substantially increase after ultrasonic treatment due to the refined structure, which also contributes to the considerably enhanced ductility of the alloys. As a result, the fracture mode changes from brittle fracture to ductile fracture. The increase in ductility makes the alloys suitable for hot deformation, which is demonstrated by lab-scale hot rolling. In addition, precipitation hardening of the alloys can be achieved by high-temperature annealing at 450 °C due to retained Zr in the Al solid solution upon solidification. The results are supported by the analysis of the composition of a supersaturated solid solution of Zr in Al and scanning and transmission electron microscopy that confirms the precipitation of coherent Al3Zr nanoparticles. It is demonstrated that a combination of ultrasonic melt processing and alloying with Zr makes it feasible to develop new class of hypereutectic casting and wrought alloys based on the Al–Fe and Al–Ni systems. King Mongkut’s University of Technology Thonburi (KMUTT 55th Anniversary Commemorative Fund); EPSRC (UK) under project UltraMelt2 (EP/R011001/1, EP/R011044/1 and EP/R011095/1).

Published

2020

3. Structure modification upon ultrasonic processing of an AA4032 piston alloy: comparison of permanent mold and direct-chill casting

Author

Chaowalit Limmaneevichitr, Suwaree Chankitmunkong, and Dmitry G. Eskin

Subjects

поршневые сплавы, Materials science, структура сплавов, Alloy, Acoustic streaming, Nucleation, Intermetallic, Liquidus, engineering.material, Ultrasonic melt processing, law.invention, кремний, Piston, law, Al–Si piston alloy, Eutectic system, Cavitation, Sonotrode, Metallurgy, Metals and Alloys, Structure refinement, Condensed Matter Physics, Mechanics of Materials, Casting (metalworking), алюминий, ультразвуковая обработка, engineering, permanent mold, Direct chill casting

Abstract

© The Author(s) 2019. Piston Al-Si alloys have very complex compositions and multi-phase heterogeneous structure, so it is necessary to control the formation of primary and eutectic compounds. In this study, the ultrasonic melt processing (USP) of a eutectic Al-Si piston alloy (AA4032-type) was performed in a permanent mold and during direct-chill (DC) casting to study its effects on the structure refinement and modification. The principal difference between these two ways of casting is that in the permanent mold the solidification front progressively moves towards the ultrasound source, while in the DC casting the position of the solidification front is fixed in space. The results showed that the USP can successfully refine primary Si, Fe-containing intermetallics and aluminum grains. Refinement of primary Si was accompanied by the increase in its amount, which was attributed to both enhanced heterogeneous nucleation and fragmentation. The refinement of Fe-containing intermetallics and Al grains resulted from the fragmentation mechanism and were more pronounced when USP was applied below the liquidus temperature in the permanent mold. However, the eutectic phases coarsened upon USP, and this effect was most pronounced when USP was applied to the semi-solid material. This was related to the strong attenuation of acoustic waves, which effectively heats the semi-solid material and induces corresponding coarsening of the phases. Acoustic streaming induced by an oscillating sonotrode affected the depth of the sump while simultaneously decreasing the macrosegregation, which reflects the dominant role of the melt flow directed against natural convection. The results demonstrated the importance of the solidification stage at which the USP was applied and the specifics of the USP mechanisms acting at the different stages of solidification. King Mongkut’s University of Technology Thonburi (“KMUTT 55th Anniversary Commemorative Fund” postdoctoral fellowship); EPSRC (UK) Project UltraMelt2 (EP/R011001/1, EP/R011044/1, and EP/R011095/1).

Published

2019

4. Influence of Titanium Diboride Particle Size on Structure and Mechanical Properties of an Al-Mg Alloy

Author

Alexander Vorozhtsov, A. A. Kozulin, Ilya Zhukov, Anton P. Khrustalyov, Marina Khmeleva, Sergey V. Vasilyev, Vladimir V. Platov, Suwaree Chankitmunkong, and Dmitry G. Eskin

Subjects

lcsh:TN1-997, Materials science, Aluminum alloy, Annealing (metallurgy), Alloy, Intermetallic, titanium diboride, master alloy, Mechanical properties, 02 engineering and technology, mechanical properties, engineering.material, 01 natural sciences, chemistry.chemical_compound, 0103 physical sciences, Ultimate tensile strength, General Materials Science, structure, Master alloy, lcsh:Mining engineering. Metallurgy, 010302 applied physics, Titanium diboride, Metallurgy, Metals and Alloys, Recrystallization (metallurgy), Structure, 021001 nanoscience & nanotechnology, chemistry, Hardening (metallurgy), engineering, Particle size, aluminum alloy, 0210 nano-technology

Abstract

In the present study, aluminum alloys of the Al-Mg system with titanium diboride particles of different size distribution were obtained. The introduction of particles in the alloy was carried out using master alloys obtained through self-propagating high-temperature synthesis (SHS) process. The master alloys consisted of the intermetallic matrix Al-Ti with distributed TiB2 particles. The master alloys with TiB2 particles of different size distribution were introduced in the melt with simultaneous ultrasonic treatment, which allowed the grain refining of the aluminum alloy during subsequent solidification. It was found that the introduction of micro- and nanoparticles TiB2 increased the yield strength, tensile strength, and plasticity of as-cast aluminum alloys. After pass rolling the castings and subsequent annealing, the effect of the presence of particles on the increase of strength properties is much less felt, as compared with the initial alloy. The recrystallization of the structure after pass rolling and annealing was the major contributor to hardening that minimized the effect of dispersion hardening due to the low content of nanosized titanium diboride. Russian Science Foundation; The Research and Researchers for Industry (RRi) under the Thailand Research Fund

Published

2019

5. Constitutive behavior of an AA4032 piston alloy with Cu and Er additions upon high temperature compressive deformation

Author

Chaowalit Limmaneevichitr, Suwaree Chankitmunkong, and Dmitry G. Eskin

Subjects

поршневые сплавы, Materials science, Alloy, 02 engineering and technology, Activation energy, Flow stress, engineering.material, 01 natural sciences, hot deformation, aluminum piston alloy, конструктивное поведение, 0103 physical sciences, constitutive behavior, Softening, сжатие, Eutectic system, 010302 applied physics, Metallurgy, Metals and Alloys, Recrystallization (metallurgy), Strain rate, 021001 nanoscience & nanotechnology, Condensed Matter Physics, Microstructure, erbium, высокотемпературная деформация, activation energy, Mechanics of Materials, engineering, 0210 nano-technology

Abstract

Aluminum piston alloys of the AA4032 type are produced by direct-chill (DC) casting and subsequent forging; therefore, it is important to understand their thermomechanical behavior. In recent years, it was shown that additions of Cu and Er could improve mechanical properties of these alloys at room and high temperatures. In this work, we studied the constitutive behavior of AA4032-type alloys with and without Cu and Er additions. The experimental true stress–true strain curves were obtained by compression tests under various temperatures [683 K to 723 K (410 °C to 450 °C)] and strain rates (0.01 to 10 s−1) to determine constitutive parameters [strain-rate sensitivity, activation energy, and Zener–Hollomon (Z) parameter] for the hot deformation behavior of AA4032-type piston alloys with and without additions of Cu and Er. The flow stress decreased with increasing deformation temperature and decreasing strain rate. The results also showed that increasing the Cu content increased the flow stress over the applied range of deformation conditions due to solid-solution strengthening and the formation of primary Si particles, which led to an increase in the activation energy during hot deformation. Moreover, the main microstructural damage in the AA4032 alloy with 3.5 pct Cu was predominantly due to the cracking of primary Si particles. Additions of 0.4 pct Er and 3.5 pct Cu lower the activation energy of deformation, Q, as compared to the base alloy and the alloy with 3.5 pct Cu. The microstructures in the deformed specimens consisted of subgrains, recrystallized grains, and fine eutectic phases. The alloys containing Er demonstrated more polygonized grains at a low strain rate than the alloys without Er, indicating that Er hindered recrystallization development. The peak stress of the AA4032 alloy with 3.5 pct Cu alloy was higher than for the base AA4032 alloy and for the AA4032 alloy with 3.5 pct Cu and 0.4 pct Er additions, which was attributed to the prevalence of the work-hardening mechanism over the softening mechanism.

Published

2019