This study focuses on the fabrication, characterization, and evaluation of the effects of Silicon Carbide (SiC) and graphite in newly developed architectural aluminium 6063 (Al6063) metal matrix composites (AMMCs). The fabrication process involves incorporating SiC and graphite into the Al6063 matrix, aiming to enhance the material's mechanical and tribological properties for architectural applications. Stir-casting fabrication technique used to achieve an optimal balance of reinforcement distribution within the matrix. The characterization phase involves a detailed analysis of the microstructure, examining the dispersion of SiC and graphite in the Al6063 matrix. Mechanical testing, such as tensile, hardness, and impact tests, is conducted to quantify the improvements achieved through the addition of SiC and graphite. The evaluation of SiC and graphite's effects on the developed Al6063 MMCs considers their individual and combined contributions to the material's overall performance. The outcomes of this research contribute valuable insights into the potential applications of the newly developed Al6063-SiC-graphite AMMCs in architectural applications. By explicating fabrication methodologies, characterizing microstructural attributes, and evaluating performance impacts, this investigation seeks to furnish a holistic comprehension of tailored composites, consequently propelling advancements in architectural material solutions.

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Fabrication, Characterization, and Effect Evaluation of SiC and Graphite in Developed Architectural Al6063 Metal Matrix Composites (AMMCs)

  • Mukesh Kumar Nag,
  • Abhishek Shrivastava,
  • Vinesh Kumar

摘要

This study focuses on the fabrication, characterization, and evaluation of the effects of Silicon Carbide (SiC) and graphite in newly developed architectural aluminium 6063 (Al6063) metal matrix composites (AMMCs). The fabrication process involves incorporating SiC and graphite into the Al6063 matrix, aiming to enhance the material's mechanical and tribological properties for architectural applications. Stir-casting fabrication technique used to achieve an optimal balance of reinforcement distribution within the matrix. The characterization phase involves a detailed analysis of the microstructure, examining the dispersion of SiC and graphite in the Al6063 matrix. Mechanical testing, such as tensile, hardness, and impact tests, is conducted to quantify the improvements achieved through the addition of SiC and graphite. The evaluation of SiC and graphite's effects on the developed Al6063 MMCs considers their individual and combined contributions to the material's overall performance. The outcomes of this research contribute valuable insights into the potential applications of the newly developed Al6063-SiC-graphite AMMCs in architectural applications. By explicating fabrication methodologies, characterizing microstructural attributes, and evaluating performance impacts, this investigation seeks to furnish a holistic comprehension of tailored composites, consequently propelling advancements in architectural material solutions.