Metal-ceramic composite coatings obtained by new thermal spray technologies: Cold Gas Spray (CGS) and its wear resistance

Authors

  • J. M. Miguel Centro de Proyección Térmica (CPT), Universidad de Barcelona
  • S. Vizcaíno Centro de Proyección Térmica (CPT), Universidad de Barcelona
  • S. Dosta Centro de Proyección Térmica (CPT), Universidad de Barcelona
  • N. Cinca Centro de Proyección Térmica (CPT), Universidad de Barcelona
  • C. Lorenzana Centro de Proyección Térmica (CPT), Universidad de Barcelona
  • J. M. Guilemany Centro de Proyección Térmica (CPT), Universidad de Barcelona

DOI:

https://doi.org/10.3989/revmetalm.1045

Keywords:

Cold spray, Solid state joining, Tribology, Composite, Bronze, Alumina, Reinforcement, Wear

Abstract


In this paper, composite coatings composed by an aluminum bronze metal matrix and a hard ceramic alumina phase obtained by cold spray technique were obtained in order to increase the tribological properties of the pure bronze coatings. The different processes that occur during the coating formation (hardening of the metal particles, fragmentation of the ceramic particles, shot peening on the metal substrate, etc) are described and their effects on the coating properties are studied. Wear tests consisting on Ball-on-Disk tests, abrasion Rubber Wheel tests and erosion tests as well as microhardness and adhesion tests are carried out and the results are correlated with the ceramic phase content of the coatings. It can be concluded that the hard ceramic phase increases the tribological properties with relation of the initial bronze coating. Finally, main wear mechanisms during the tribological tests are described. Keywords

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Published

2011-10-30

How to Cite

Miguel, J. M., Vizcaíno, S., Dosta, S., Cinca, N., Lorenzana, C., & Guilemany, J. M. (2011). Metal-ceramic composite coatings obtained by new thermal spray technologies: Cold Gas Spray (CGS) and its wear resistance. Revista De Metalurgia, 47(5), 390–401. https://doi.org/10.3989/revmetalm.1045

Issue

Vol. 47 No. 5 (2011)

Section

Articles

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