Stir Casting Routes for Processing Metal Matrix Syntactic Foams: A Scoping Review

Metal matrix syntactic foams (MMSFs) are advanced lightweight materials constituted by a metallic matrix and a dispersion of hollow/porous fillers. Physical and mechanical properties can be fitted regarding matrix and filler properties and processing parameters. Their properties make them potential...

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Bibliographic Details
Published inProcesses Vol. 10; no. 3; p. 478
Main Authors Sánchez de la Muela, Alejandro Miguel, Duarte, Joana, Santos Baptista, João, García Cambronero, Luis Enrique, Ruiz-Román, José Manuel, Elorza, Francisco Javier
Format Journal Article
LanguageEnglish
Published Basel MDPI AG 01.03.2022
Subjects
Aerospace engineering
Buoyancy
Comparative analysis
Composite materials
Constraining
Fillers
Foamed metals
Foams
Information processing
Liquid metals
Mechanical properties
Metallurgical analysis
Methods
Morphology
Oxidation
Physical properties
Porosity
Powder metallurgy
Process parameters
Solidification
Syntactic foams
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Summary:Metal matrix syntactic foams (MMSFs) are advanced lightweight materials constituted by a metallic matrix and a dispersion of hollow/porous fillers. Physical and mechanical properties can be fitted regarding matrix and filler properties and processing parameters. Their properties make them potential materials for sectors where density is a limiting parameter, such as transport, marine, defense, aerospace, and engineering applications. MMSFs are mainly manufactured by powder metallurgy, infiltration, and stir casting techniques. This study focuses on the current stir casting approaches and on the advances and deficiencies, providing processing parameters and comparative analyses on porosity and mechanical properties. PRISMA approaches were followed to favor traceability and reproducibility of the study. Stir casting techniques are low-cost, industrially scalable approaches, but they exhibit critical limitations: buoyancy of fillers, corrosion of processing equipment, premature solidification of molten metal during mixing, cracking of fillers, heterogeneous distribution, and limited incorporation of fillers. Six different approaches were identified; four focus on limiting buoyancy, cracking, heterogeneous distribution of fillers, and excessive oxidation of sensitive matrix alloys to oxygen. These improvements favor reaching the maximum porosity of 54%, increasing the fillers’ size from a few microns to 4–5 mm, reducing residual porosity by ±4%, synthesizing bimodal MMSFs, and reaching maximum incorporation of 74 vol%.
ISSN:2227-9717
2227-9717
DOI:10.3390/pr10030478