Tribological behavior of composites fabricated by reactive SPS sintering in Ti-Si-C system |
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| Authors: | Youcef Hadji Abdessabour Benamor Nabil Chiker Adel Haddad Nacer Tala-Ighil Jean-Pierre Erauw Vedi Dupont Arnaud Tricoteaux Christelle Nivot Anthony Thuault Mohamed Hadji |
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| Affiliation: | 1. Laboratoire d'Etudes et Recherche en Technologie Industrielle LERTI, University of Blida 1, Blida, Algeria;2. Research Center in Industrial Technologies (CRTI), Algiers, Algeria;3. Belgian Ceramic Research Center (BCRC), Mons, Belgium;4. LMCPA, Université Polytechnique Hauts-de-France, Maubeuge, France |
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| Abstract: | In this study, wear and friction behavior of two based-composites from the Ti-Si-C system, (40 wt% TiC; 28 wt% Ti5Si3; 17 wt% Ti3SiC2) and (18 wt% TiC; 26 wt% Ti5Si3; 41 wt% Ti3SiC2) reinforced by 15 wt% of large size SiC (100-150 µm) particles were investigated. The four-phase composites exhibited approximatively the same friction coefficient (µ ~ 0.9) under high loads (10 N and 7 N). The composite with high Ti3SiC2 showed higher wear rate values by one order of magnitude. However, under 1 N, the composite with high TiC content showed a higher running-in period and a lower steady state µ value (0.37 after 1000 m sliding distance). Scanning electron microscopy, Energy Dispersive X-Ray and Raman spectroscopy analysis of the worn surfaces of the two composites revealed that oxidation was the dominant wear mechanism. The oxidation process and the removal kinetics of the oxides during sliding controlled the tribological behavior of the composites. The influence of processing variables on microstructures development and wear mechanisms of the composites is discussed. |
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| Keywords: | ceramic–matrix composites friction SPS sintering tribo-oxidation wear |
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