Effect of pouring temperature on fluidity, porosity, density, and microstructure of Al-Si alloy in gravity die casting

Authors

  • Sudarsono Department of Mechanical Engineering, Halu Oleo University, Indonesia
  • Amir Arifin Department of Mechanical Engineering, Sriwijaya University, Indonesia
  • Hidayat Department of Mechanical Engineering, Politeknik Negeri Samarinda, Indonesia
  • La Ode Ahmad Barata Department of Mechanical Engineering, Halu Oleo University, Indonesia
  • Aminur Department of Mechanical Engineering, Halu Oleo University, Indonesia
  • Alain Kusmoko School of Mechanical, Materials, Mechatronic and Biomedical Engineering Wollongong University, Australia

DOI:

https://doi.org/10.47540/ijias.v6i2.2677

Keywords:

Aluminium–silicon Alloy, Gravity Die Casting, Microstructure, Pouring Temperature, Porosity

Abstract

The growing demand for lightweight aluminium components necessitates improved quality control in casting, particularly for aluminium–silicon (Al–Si) alloys produced via gravity die casting. This study systematically investigates the effect of pouring temperature on the fluidity, porosity, density, and microstructure of an Al–Si alloy using a gravity iron die mold with varying section thicknesses. Casting experiments were conducted at pouring temperatures of 600°C, 650°C, and 700°C to simulate thin-wall casting conditions. Fluidity was evaluated by measuring flow length, while density and porosity were determined using Archimedes’ principle. Microstructural evolution was characterized via optical microscopy. The results demonstrate that increasing the pouring temperature significantly enhances fluidity, enabling the complete filling of progressively thinner sections. However, higher temperatures also lead to increased porosity and reduced density, particularly in thicker sections, due to prolonged solidification times and reduced cooling rates. Microstructural analysis reveals that higher pouring temperatures and larger section thicknesses promote coarser α-Al dendrites, larger β-Si particles, and increased intermetallic phase aggregation; conversely, lower pouring temperatures and thinner sections result in finer, more homogeneous microstructures. These findings highlight the critical trade-off between mold-filling capability and internal casting quality, emphasizing the importance of optimizing pouring temperature in the gravity die casting of Al–Si alloys.

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Published

2026-06-30

How to Cite

Sudarsono, Arifin, A., Hidayat, Barata, L. O. A., Aminur, & Kusmoko, A. (2026). Effect of pouring temperature on fluidity, porosity, density, and microstructure of Al-Si alloy in gravity die casting. Indonesian Journal of Innovation and Applied Sciences (IJIAS), 6(2), 170–183. https://doi.org/10.47540/ijias.v6i2.2677