Tytuł artykułu
Autorzy
Wybrane pełne teksty z tego czasopisma
Identyfikatory
Warianty tytułu
Języki publikacji
Abstrakty
Purpose: of this paper is to develop new aluminium matrix (intermetallic) composites reinforced with iron oxide (Fe3O4) that will be used in aeronautical engineering or in electronic industry. Different parameters such as sintering time and temperature, reinforcement, compact pressure were evaluated. The final purpose of this project is going on to improve conductivity and magnetic permeability of this new composite. Design/methodology/approach: In this paper, a new alternative materials “aluminium–iron oxide (Fe3O4, naturally as the mineral magnetite) powder composite” has been developed by using a microwave (in the laboratory scale) sintering programme with various aspect ratios, that iron oxide (Fe3O4) particle sizes and aluminium powders together were prepared. This paper contains partially preliminary results of our going-on research project. Findings: Green density increased regularly depending on the compact pressure and percentage of the iron oxide (Fe3O4). Micro and macro porosity was not found due to very clean microwave sintering. Density after microwave sintering was higher than that of traditional sintering in an electrical oven. Research limitations/implications: This project is going on and magnetic permeability and conductivity of this composite will be improved. Practical implications: This composite is new and clean and thanks to the new microwave sintering basically will be used in aeronautical engineering. Microwave heating results in lower energy costs and decreased processing times for many industrial processes. Originality/value: Originality of this paper is to use a new reinforcement in the aluminium matrix composite; Fe3O4-iron oxide. A new method - microwave sintering- has been carried out on this composite.
Wydawca
Rocznik
Tom
Strony
7--14
Opis fizyczny
Bibliogr. 36 poz., rys., tabl.
Twórcy
autor
autor
- Supmeca/LISMMA-Paris, School of Mechanical and Manufacturing Engineering, France, bayraktar@supmeca.fr
Bibliografia
- [1] R. Narayanasamy, K. S. Pandey, Some aspects of work hardening in sintered aluminium–iron composite preforms during cold axial forming, Journal of Materials Processing Technology 84 (1998) 136-142.
- [2] B. Ziębowicz, D. Szewieczek, L. A. Dobrzański, New possibilities of application of composite materials with soft magnetic properties, Journal of Achievements in Materials and Manufacturing Engineering 20 (2007) 207-210.
- [3] R. Narayanasamy, T. Ramesh, K. S. Pandey, Some aspects on strain hardening behaviour in three dimensions of aluminium–iron powder metallurgy composite during cold upsetting, Materials and Design 27 (2006) 640-650.
- [4] R. Narayanasamy, T. Ramesh, S. K. Pandey, K. S. Pandey, Effect of particle size on new constitutive relationship of aluminium–iron powder metallurgy composite during cold upsetting, Materials and Design 29 (2008) 1011-1026.
- [5] R. Narayanasamy, T. Ramesh, K. S. Pandey, Some aspects on cold forging of aluminium–iron powder metallurgy composite under triaxial stress state condition, Materials and Design 29 (2008) 891-903.
- [6] F. Tang, I. E. Anderson, T. Gnaupel –Herold, H. Prask, Pure Al matrix composites produced by vacuum hot pressing: tensile properties and strengthening mechanisms, Materials Science and Engineering A 383 (2004) 362-373.
- [7] A. Grabowski, B. Formanek, M. Sozanska, D. Janicki, M. Nowak, Laser remelting of Al-Fe-TiO powder composite on aluminium matrix, Journal of Achievements in Materials and Manufacturing Engineering 33/1 (2009) 78-85.
- [8] L. Duraes, B. F. O. Costa, R. Santos, A. Correia, J. Campos, A. Portugal, Fe2O3/aluminum thermite reaction intermediate and final products characterization, Materials Science and Engineering A 465 (2007) 199-210.
- [9] E. Bayraktar, J. Masounave, R. Caplain, C. Bathias, Manufacturing and damage mechanisms in metal matrix composites, Journal of Achievements in Materials and Manufacturing Engineering 31/2 (2008) 294-300.
- [10] J. Mei, R. D. Halldearn, P. Xiao, Mechanisms of the Al-iron oxide thermite reaction, Scripta Materialia 41/5 (1999) 541-548.
- [11] M. Adamiak, Mechanical alloying for fabrication of aluminium matrix composite powders with Ti-Al interme-tallics reinforcement, Journal of Achievements in Materials and Manufacturing Engineering 31/2 (2008) 191-196.
- [12] W. Hufenbach, M. Gude, A. Czulak, J. Sleziona, A. Dolata- Grosz, M. Dyzia, Development of textile-reinforced carbon fibre aluminium composites manufactured with gas pressure infiltration methods, Journal of Achievements in Materials and Manufacturing Engineering 35/2 (2009) 177-183.
- [13] A. Gokce, F. Findik, Mechanical and physical properties of sintered aluminium powders, Journal of Achievements in Materials and Manufacturing Engineering 30/2 (2008) 157-164.
- [14] C. A. Aliravci, M. O. Pekguleryuz, Calculation of Phase Diagrams for the Metastable Al-Fe Phases Forming in Direct-Chill Cast Aluminium Alloy Ingots, Calphad 22/2 (1998) 147-l 55.
- [15] L. A. Dobrzański, M. Kremzer, A. J. Nowak, A. Nagel, Aluminium matrix composites fabricated by infiltration method, Archives of Materials Science and Engineering 36/1 (2009) 5-11.
- [16] E. Bayraktar, D. Katundi, Aeronautical Engineering, Internal Report/LISMMA-Paris, 2010, 25.
- [17] H. Shokrollahi, The magnetic and structural properties of the most important alloys of iron produced by mechanical alloying, Materials and Design 30 (2009) 3374-3387.
- [18] S. C. Tjong, Z. Y. Ma, Microstructural and mechanical characteristics of in situ metal matrix composites, Materials Science and Engineering: R: Reports 29/3-4 (2000) 49-113.
- [19] R-C. O’Handley, Modern magnetic materials (principles and applications), Wiley–Interscience, 2000, 367.
- [20] S. W. Du, R.-V. Ramanujan, Mechanical alloying of Fe–Ni based nanostructure magnetic materials, Journal of Magnetism and Magnetic Materials 292 (2005) 286-295.
- [21] M. Manivel Raja, K. Chattopadhyay, B. Majumdar, A. Narayanasamy, Structure and soft magnetic properties of Finemet alloys, Journal of Alloys and Compounds 297/1-2 (2000) 199-213.
- [22] R. V. Ramanujan, Y. R. Zhang, Microstructural observations of the crystallization of amorphous Fe–Si–B based magnetic alloys, Thin Solid Film 505 (2006) 97-118.
- [23] A. Makino, T. Bitoh, Magnetic properties of zero-magnetostrictive nanocrystalline Fe–Zr–Nb–B soft magnetic alloys with high magnetic induction, Journal of Magnetism and Magnetic Materials 215-216 (2000) 288-295.
- [24] A. Olszówka-Myalska, J. Szala, J. Cwajna, Characterization of iron aluminides formed in situ in an aluminium matrix composite, Materials Characterization 56 (2006) 379-383.
- [25] D. Kuc, G. Niewielski, I. Bednarczyk, The influence of ther-momechanical treatment on structure of FeAl intermetallic phase-based alloys, Journal of Achievements in Materials and Manufacturing Engineering 29/2 (2008) 123-130.
- [26] W. Pilarczyk, R. Nowosielski, M. Nowak, M. Kciuk, The structural changes of Al-Ti-Fe alloy during mechanical alloying process, Journal of Achievements in Materials and Manufacturing Engineering 29/2 (2008) 131-138.
- [27] L. A. Dobrzański, K. Labisz, A. Olsen, Microstructure and mechanical properties of the Al-Ti alloy with calcium addition, Journal of Achievements in Materials and Manufacturing Engineering 26/2 (2008) 183-186.
- [28] J. Szajnar, T. Wróbel, Inoculation of primary structure of pure aluminium, Journal of Achievements in Materials and Manufacturing Engineering 20 (2007) 283-286.
- [29] T. Lipinski, Improvement of mechanical properties of AlSi7Mg alloy with fast cooling homogenous modifier, Archives of Foundry Engineering 8 (2008) 85-88.
- [30] G. Mrowka-Nowotnik, J. Sieniawski, M. Wirzbinska, Intermetallic phase particles in 6082 aluminium alloy, Archives of Materials Science and Engineering 28/1 (2007) 69-76.
- [31] D. Kuc, G. Niewielski, M. Jablonska, I. Bednarczyk, Deformability and Recrystallisation of Fe-Al Intermetallic, Phase-Base Alloy, Journal of Achievements in Materials, and Manufacturing Engineering 17 (2006) 107-110.
- [32] R. Narayanasamy, T. Ramesh, K. S. Pandey, Some aspects on workability of aluminium–iron powder metallurgy composite during cold upsetting, Materials Science and Engineering A 391 (2005) 418-426.
- [33] P. Chakraborty, I. G. Sharma, A. K. Suri, D. K. Bose, Studies on preparation, characterisation and evaluation of properties of Fe3Al-based intermetallic alloy of composition Fe–16Al–5.44Cr–1Nb–0.5C,Journal of Materials Processing Technology 115 (2001) 413-422.
- [34] D. Kuc, I. Bednarczyk, G. Niewielski, The influence of deformation on the plasticity and structure of Fe3Al - 5Cr alloy, Journal of Achievements in Materials and Manufacturing Engineering 22/2 (2007) 27-30.
- [35] A. H. Taghvaei, H. Shokrollahi, K. Janghorban, Structural studies, magnetic properties and loss separation in iron – phenolicsilane soft magnetic composites, Materials and Design 31 (2010) 142-148.
- [36] R. P. Baron, C. Jones, F. E. Wawner, J. A. Wert, Mechanical properties of aluminium matrix composites reinforced with sintered ferrous compacts, Materials Science and Engineering A259 (1999) 308-313.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-article-BOS2-0022-0009