Tribological behavior of aluminum matrix composites containing complex metallic alloys AlCuFeB or AlCuFeCr particles

▶ Friction and wear behavior of aluminum matrix composites containing hard complex metallic alloys (CMA) as reinforcing particles. ▶ CMA-particles maintain their high hardness after sintering. ▶ Wear loss of aluminum under dry sliding is strongly reduced by the incorporation of CMA-particles. ▶ Pred...

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Bibliographic Details
Published in:Wear 2011-03, Vol.270 (7), p.528-534
Main Authors: Lu, Dong, Celis, J.P., Kenzari, S., Fournée, V., Zhou, D.B.
Format: Article
Language:English
Subjects:
Abrasion
Abrasion resistance
Alloys
Aluminum
Aluminum base alloys
Applied sciences
Chemical Sciences
Drying
Exact sciences and technology
Friction, wear, lubrication
Intermetallics
Machine components
Material chemistry
Mechanical engineering. Machine design
Metal matrix composites
Nanoindentation
Nanomaterials
Nanostructure
Sliding wear
Tribochemistry
Wear testing
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Summary:▶ Friction and wear behavior of aluminum matrix composites containing hard complex metallic alloys (CMA) as reinforcing particles. ▶ CMA-particles maintain their high hardness after sintering. ▶ Wear loss of aluminum under dry sliding is strongly reduced by the incorporation of CMA-particles. ▶ Predominant wear mechanisms are affected by CMA-particles. The tribological behavior of sintered aluminum metal matrix composites (MMCs) containing various volume fractions of particles made of complex metallic alloys (CMAs) was investigated in a reciprocating dry sliding tribo-tester operated in ambient air against 10 mm diameter Al 2O 3 balls. The Al-based MMCs tested contained either 15 μm size AlCuFeB or 25 μm size AlCuFeCr-particles. An improvement in the dry sliding wear resistance of aluminum was achieved by the incorporation of these CMA-particles acting as a second phase reinforcement. The wear resistance depends on the volume fraction of CMA-particles but not on their composition, nano-hardness or size. These Al-based MMCs containing CMA-particles exhibit however a higher coefficient of friction than pure aluminum under dry sliding against a ceramic counterbody. A clear correlation was not found between composition, nano-hardness, size or volume percent of CMA-particles, and coefficient of friction. The dominant wear mechanisms active on MMCs containing either AlCuFeB or AlCuFeCr-particles are abrasion and adhesion, but abrasion dominates in the case of Al-MMCs containing AlCuFeCr-particles.
ISSN:0043-1648
1873-2577
DOI:10.1016/j.wear.2011.01.007