Effects of Solidification Thermal Variables on the Microstructure and Hardness of the Silicon Aluminum Bronze Alloy CuAl6Si2

The properties of the final product obtained by solidification directly result from the thermal variables during solidification. This study aims to analyze the influence of thermal solidification variables on the hardness, microstructure, and phases of the CuAl6Si2 alloy. The material was solidified...

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Bibliographic Details
Published in:Metals (Basel ) 2024-10, Vol.14 (10), p.1134
Main Authors: Nascimento, Paulo Henrique Tedardi do, Santos, Vinicius Torres dos, Luca, Ricardo de, Silva, Marcio Rodrigues da, Lobo, Flavia Goncalves, Teram, Rogerio, Nascimento, Mauricio Silva, Cozza, Ronaldo Camara, Couto, Antonio Augusto, Santos, Givanildo Alves dos, Filho, Anibal de Andrade Mendes
Format: Article
Language:English
Subjects:
Alloys
Aluminum
Aluminum bronzes
Brinell hardness
Bronze
Cooling
Cooling rate
Copper
Corrosion resistance
Data acquisition
Decomposition
Design
Directional solidification
Grain boundaries
Heat transfer
Heat transmission
Heat treatment
Impact strength
Intermetallic compounds
Mechanical properties
Metastable phases
Microstructure
Optical microscopes
Permeability
Scanning electron microscopy
Silicon
silicon aluminum bronze
Solidification
Temperature
thermal variables
unidirectional solidification
X-ray diffraction
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Summary:The properties of the final product obtained by solidification directly result from the thermal variables during solidification. This study aims to analyze the influence of thermal solidification variables on the hardness, microstructure, and phases of the CuAl6Si2 alloy. The material was solidified using unidirectional solidification equipment under non-stationary heat flow conditions, where heat extraction is conducted through a water-cooled graphite base. The thermal solidification variables were extracted using a data acquisition system, and temperature was monitored at six different positions, with cooling rates ranging from 217 to 3 °C/min from the nearest to the farthest position from the heat extraction point. An optical microscope, scanning electron microscope (SEM), and X-ray diffraction (XRD) were used to verify the fusion structure and determine the volumetric fraction of the formed phases. The XRD results showed the presence of β phases, α phases, and possible Fe3Si2 and Fe5Si3 intermetallics with different morphologies and volumetric fractions. Positions with lower cooling rates showed an increased volume fraction of the α phase and possible intermetallics compared to positions with faster cooling. High cooling rates increased the Brinell hardness of the alloy due to the refined and equiaxed β metastable phase, varying from 143 HB to 126 HB for the highest and lowest rates, respectively.
ISSN:2075-4701
2075-4701
DOI:10.3390/met14101134