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Purpose: the work presents an innovative approach for the production of cellular metallic materials as well as low density metal matrix composites, by using thixoforming techniques; thixotropic semisolid metal is infiltrated into removable and non-removable space holder preforms. Different kinds of preforms are tested to obtain open cell material (sponges), syntactic foams and low density composites. Products are evaluated concerning relative density and mechanical behavior under compressive stresses. Design/methodology/approach: Al alloy AA2011 was infiltrated in the semisolid state into preforms of sintered NaCl particles, sintered glass spheres, vermicular ceramic particles and porous ceramic granulates. After solidification, preforms were either removed by leaching (NaCl) resulting in open cell cellular product, or not (all others), resulting in composites of low density. Tomography tests were used to observe internal quality, and semi-static and dynamic compression tests were performed to evaluate the deformation ability of the material. Findings: results show that thixoinfiltration is a simple and low cost technique to produce different types of low density, porous material. Open cell material as well as syntactic foams and low density composites can be produced with reliable internal quality and dispersion of cells and reinforcement. Composites containing porous reinforcements can present some mechanical characteristics of the conventional cellular metals. Research limitations/implications: as all new developments, the complete understanding of the influence of processing variables upon the final quality of the product, as well as its consistency, must be provided before the technology can be widely used commercially. Practical implications: the technique can represent an alternative, low cost processing route for the fabrication of sponges, foams and low density composites, which can avoid restrictions and operational difficulties of presently available manufacturing processes based in liquid manipulation or powder sintering methods. Originality/value: infiltration of appropriate preforms by thixotropic metallic alloys to produce low density composites and cellular material is a new technique under development by the proposing group at FEM/UNICAMP.
Wydawca
Rocznik
Tom
Strony
180--187
Opis fizyczny
Bibliogr. 16 poz., rys., tabl.
Twórcy
autor
autor
autor
autor
- Faculty of Mechanical Engineering, State University of Campinas, SP, Brazil, helena@fem.unicamp.br
Bibliografia
- [1] S. Hoda, , Metalfoam: New material that mimics bone may create better biomedical implants, Orthopedics Journals Review 02 (2010) 202-208.
- [2] P. K. Pinnoji, P. Mahajan, N. Bourdet, C. Deck, R. Willinger, Impact dynamics of metal foam shells for motorcycle helmets: Experiments & numerical modelling, International Journal of Impact Engineering 37 (2010) 274-284.
- [3] J. Banhart, Al foams: on the road for real application, MRS Bulletin (2003) 290-293.
- [4] J. A. Reglero, E. Solorzano, M. A. Rodriguez-Perez, J. A. de Saja, Design and testing of an energy absorber prototype based on aluminum foams, Materials & Design (2010) 1-6.
- [5] A. Ejlali, A. Ejlali, K. Hooman, H. Gurgenci, Application of high porosity metal foams as air-cooled heat exchangers to high heat load removal systems, International Communications in Heat and Mass Transfer 36 (2009) 674-679.
- [6] W. Azzi, W. L. Roberts, A. Rabiei, A study on pressure drop and heat transfer in open cell metal foams for jet engine applications, Materials & Design 28 (2007) 569-574.
- [7] R. Nowosielski, A. Kania, M. Spilka, Development of ecomaterials and materials technology, Journal of Achievements in Materials and Manufacturing Engineering 21/1 (2007) 27-30.
- [8] J. Adamus, Forming of the titanium implants and medical tools by metal working, Journal of Achievements in Materials and Manufacturing Engineering 28/2 (2008) 313-316.
- [9] F. Gatamorta, Manufacture of syntactic foams of the alloy AA2011 from the metal in the semi-solid state and metallurgical characterization of the product, Mechanical Engineering Faculty, University of Campinas, Thesis, 2009 (in Portuguese).
- [10] J. Banhart, Manufacturing routes for metallic foams, JOM (2000) 22-27.
- [11] R. Goodall, A. Marmottant, L. Salvo, A. Mortensen, Spherical pore replicated microcellular aluminium: Processing and influence on properties, Materials Science and Engineering 465 (2007) 124-135.
- [12] A. Dalota-Grosz, M. Dyzia, J. Śleziona, Solidification analysis of AMMCs with ceramic particles, Journal of Achievements in Materials and Manufacturing Engineering 28/2 (2008) 401-404.
- [13] M. H. Robert, D. Delbin, Manufacturing of cellular A2011 alloy from semi-solid state, Journal of Achievements in Materials and Manufacturing Engineering 24/1 (2007) 115-122.
- [14] R. R. Silva, M. H. Robert, Mechanical and structural characterization of open-cell Al alloys produced by thixoforming into removable space holders pre-forms, Proceedings of the 6th International conference on Porous Metals and Metallic Foams, Bratislava, 2009.
- [15] M. H. Robert, R. Cristofolini, Analysis of the thixoability of A536 ductile iron, Journal of Achievements in Materials and Manufacturing Engineering 28/2 (2008) 115-122.
- [16] M. F. Ashby, A. G. Evans, N. A. Fleck, L. J. Gibson, J. W. Hutchinson, H. N. G. Wadley, Metal Foams: A Design Guide. Butterworth-Heinemann, Boston, 2000.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-article-BOS2-0022-0072