MODELING AND OPTIMIZATION OF ALUMINUM MATRIX COMPOSITE MATERIALS REINFORCED WITH CERAMIC PARTICLES

Authors

  • Bobur Saparov, Murodullo Rakhimov, Murod Nosirov, Gulam Shamanov Tashkent Institute of Chemical Technology

DOI:

https://doi.org/10.55640/

Keywords:

aluminum matrix composite, ceramic particles, modeling, optimization, mechanical properties

Abstract

 Aluminum matrix composite materials reinforced with ceramic particles have attracted significant attention due to their high strength-to-weight ratio, wear resistance, and thermal stability. This study investigates the mechanical behavior of aluminum matrix composites reinforced with ceramic particles through numerical modeling and optimization techniques. A mathematical model describing the relationship between particle volume fraction and mechanical properties was developed. Finite element modeling was applied to evaluate stress distribution and deformation behavior. The results show that increasing the ceramic particle fraction significantly improves hardness and wear resistance while maintaining acceptable ductility. Optimization analysis indicates that the optimal particle content lies between 8–12% for balanced mechanical performance. These findings provide useful insights for the design and development of advanced composite materials used in aerospace and mechanical engineering applications.

References

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Published

2026-03-26

Issue

Vol. 5 No. 03 (2026): International Journal of Political Sciences and Economics

Section

Articles

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How to Cite

MODELING AND OPTIMIZATION OF ALUMINUM MATRIX COMPOSITE MATERIALS REINFORCED WITH CERAMIC PARTICLES. (2026). International Journal of Political Sciences and Economics, 5(03), 409-413. https://doi.org/10.55640/

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