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Arabian Journal for Science and Engineering

, Volume 44, Issue 2, pp 1543–1552 | Cite as

Porosity Study of Developed Al–Mg–Si/Bauxite Residue Metal Matrix Composite Using Advanced Stir Casting Process

  • Ajay Singh VermaEmail author
  • Manjot Singh Cheema
  • Suman Kant
  • Narendra Mohan Suri
Research Article - Mechanical Engineering
  • 58 Downloads

Abstract

Bauxite residue (BR) is the waste generated from alumina processing industries, which is considered as an environmental problem throughout world. Hence, utilization of BR is the need of the hour. In the present investigation, vacuum type bottom pouring mechanism is introduced in stir casting process to fabricate a low-cost particulate metal matrix composite (PMMC) using Al–Mg–Si alloy with BR as reinforcement. Controlled process parameters in terms of stirring speed and particle percentage were chosen in development of Al–Mg–Si/BR PMMC. The result of the microstructural study reveals uniform distribution of particles with 350 and 450 rpm of stirring speed. In this study, it was observed that increased BR weight fraction resulted in increased porosity content of the developed PMMC. Porosity content was found to have major impact on the microhardness of developed Al–Mg–Si/BR PMMC. The microhardness behavior of the developed PMMC was also predicted at different indentation loads. Microstructure was examined at both stirring speeds at different cross sections of the cylindrical samples. The reinforcement content was varied in a percentage range of 2–8% by weight. Beyond the limit of 8-wt% reinforcement concentration, defects like voids, local clustering, and agglomeration of particles were seen in the developed Al–Mg–Si/BR PMMC.

Keywords

Bauxite residue Bottom pouring Homogeneity Microhardness Porosity Stir casting 

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Copyright information

© King Fahd University of Petroleum & Minerals 2018

Authors and Affiliations

  • Ajay Singh Verma
    • 1
    Email author
  • Manjot Singh Cheema
    • 1
  • Suman Kant
    • 1
  • Narendra Mohan Suri
    • 1
  1. 1.Production and Industrial Engineering DepartmentPunjab Engineering College (Deemed to be university), PEC University of TechnologyChandigarhIndia

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