Manufacturing Technology 2019, 19(5):817-822 | DOI: 10.21062/ujep/378.2019/a/1213-2489/MT/19/5/817

Production of Porous Aluminium Using Sodium Chloride

Iva Nová1, Karel Fraňa2, Jiří Sobotka1, Pavel Solfronk1, David Koreček1, Iva Nováková1
1 Technical University of Liberec, Faculty of Mechanical Engineering, Department, Engineering Technology
2 Technical University of Liberec, Faculty of Mechanical Engineering, Department of Energy Facilities. Studentská 1402/2, Czech Republic

Our workplace, Technical University of Liberec, is currently engaged in research and production of cellular metal systems. Basically, cellular metal systems are materials with lower density. It is a research in the field of mechanical engineering that is focused on the development of new materials. In general, many methods have been developed for the production of cellular metal systems, e.g. by BANHART [2] or ASHBY [4]. At their production, the direct gassing of molten metals (mostly aluminium ones) or gassing by the powder agents (e.g. specially formulated aluminium powders) are mostly used. Depending on the manufacturing method, a cellular system with open or closed cells can be obtained. The most commonly used metal is aluminium and its alloys. We are currently focusing on the production of porous aluminium by using sodium chloride. Sodium chloride occupies regular sites in the aluminium material and thus contributes to the aluminium porosity. After solidification of the aluminium, sodium chloride is dissolved in water. Sodium chloride is relatively inert to the aluminium and together with it, has a favourable density (2160 kgm-3) compared to the aluminium density (2700 kgm-3). The values of these physical quantities were observed on the produced aluminium test specimens having  60 x 10 mm: relative density of porous system REL; porosity of metal system P; amount of solid phase system volume fraction VPM; density of porous metal system PM and porous material Young's modulus of elasticity EPM.

Keywords: Metal System, Porous Metal System, Sodium Chloride, Casting, Aluminium Alloy
Grants and funding:

Project “Hybrid materials for hierarchical structures”, re-search goal: Composite materials and structures, re-search program: Materials and structures on the metal basis, reg. no. CZ.02.1./0.0/0.0/16_019/0000843 provided by the European Union and the Czech government.

Published: October 1, 2019  Show citation

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Nová I, Fraňa K, Sobotka J, Solfronk P, Koreček D, Nováková I. Production of Porous Aluminium Using Sodium Chloride. Manufacturing Technology. 2019;19(5):817-822. doi: 10.21062/ujep/378.2019/a/1213-2489/MT/19/5/817.
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    References

    1. DE MELLER, M.A. (1926). Produit Métallique Pour L'obtention D'objets Laminés, Moulés Ou Autres, Et Procédés Pour Sa Fabrication. French Patent 615, 147.
    2. BANHART, J. (2000). Manufacturing Routes for Metallic Foams.Journalof Minerals, Metals and Material Society. Vol. 52, No. 12, pp. 22 - 27. Go to original source...
    3. BANHART, J. (2001). Manufacture, characterisation and application of cellular metals and metal foams. Progress in Materials Science 46, s. 559-632. Go to original source...
    4. ASHBY, M.F. et al. (2000). Metal Foams: A Design Guide. Ed. Betterwort-Heinemann.
    5. Cymat Corporation Canada. (1998). Product information sheets and foams (http://www.cymat.com).
    6. MIYOSHI, T. et al. (2000). ALPORAS Aluminium Foam: Production Process, Properties and Applications. [online]. Advanced Engineering Materials,, 2, No. 4, s. 179-183. Go to original source...
    7. BAÉZ-PIMIETO, S. et al. (2015). Processing and characterization of open-cell aluminium foams obtained through infiltration process. Procedia Materials Science 9, pp. 54-61. Go to original source...
    8. SURACE, L. DE PHILIPS, L.A.C. LUDOVICO, A.D. BOGHETISCH, G. (2009). Influence of processing an aluminium foam produced by space holder technique. Materials and Design 30 pp. 1878-1885. Go to original source...
    9. VOHLÍDAL, J. ©TULÍK, K. JULÁK, A. (1999). Chemické a analytické tabulky. (Chemical and analytical tables). 1. vyd. Praha: Grada Publishing, ISBN 80-7169-855-5 (in Czech).
    10. Underlying materials of the Exxentis - porous materials Swiss company (2018).
    11. JERZ, J. (1995). Foamed Aluminium and Aluminium Alloys Prepared by Powder Metallurgy. Ph.D thesis, TU Vienna.
    12. HANUS, A. LICHÝ, P and V. BEDNÁŘOVÁ. (2012). Production and properties of cast metal with porous. METAL, Brno Czech Republic, EU.
    13. LUNA, E.M.E. at al. (2014). Casting Protocols for the production of open cell aluminium foams by the replication Technique and the Effect on porosity. Journal of Visualized Experiments. (94), e52568. www.jove.com.
    14. LUNA, E.M.E. (2016). Investigation of Porous Metals as Improved Efficing Regeneration. [Doctoral thesis], The University of Sheffield - Faculty of Engineering, March.
    15. MORENO, F.G. (2016) Commercial Application of metal Foams: Their properties and production. Materials, 9. 85, pp. 1 - 27. Go to original source...
    16. NANSAARNG, S. and S. SOPHA. (2008) A Synthesis of Aluminium Foams from Ingot by Compessing Meth Method. In. Progresing of the 1st WSEAS International Conference on Materials science (MATERIALS' 08). ISSN 1790-2769, pp. 130-133.
    17. Technical materials of the company Alumeco Group, Denmark. (www.alumeco.com).
    18. LIPIŇSKI, T. (2017). Analysis of Mechanical Properties of AlSi9Mg Alloy with Al, Ti and B. Manufacturing Technology Vol. 17, No. 5, pp. 761-766, ISSN 1213-2489. Go to original source...
    19. HODINÁŘ, L., SVOBODOVÁ, J., HREN, I., CAIS, J., MICHNA, ©. (2019) The Manganese Influence on the Alloy Al final Bath mechanical Properties Change. Manufacturing Technology Vol. 19, No. 1, pp. 54-63, ISSN 1213-2489. Go to original source...

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