A MIM Route for Producing Ti6Al4V-TiC Composites

Roger Pelletier; Louis Philippe Lefebvre; Eric Baril

doi:10.4028/www.scientific.net/KEM.704.139

Paper Titles

Sintering Powder Metal Injection Molded (MIM) Titanium Alloys: In Vacuum or Argon?
p.113

New Titanium Alloy Feedstock for High Performance Metal Injection Molding Parts
p.118

Titanium Metal Injection Molding, a Qualified Manufacturing Process
p.122

Development of PEG/PMMA Based Binders for Ti-Metal Injection Moulding
p.130

A MIM Route for Producing Ti6Al4V-TiC Composites
p.139

Two-Component Metal Injection Moulding of Ti-6Al-4V and Stainless Steel Bi-Material Parts
p.148

Metal Injection Moulding of Titanium Medical Components
p.155

Identification of Contamination Levels and the Microstructure of Metal Injection Moulded Titanium
p.161

Metal Injection Moulding of Superelastic TiNi Parts
p.173

HomeKey Engineering MaterialsKey Engineering Materials Vol. 704A MIM Route for Producing Ti6Al4V-TiC Composites

A MIM Route for Producing Ti6Al4V-TiC Composites

Abstract:

Discontinuous reinforced titanium matrix composites have generated significant interest due to their compelling properties such as their specific strength and wear resistance at room and elevated temperatures. For these reasons, these materials have been considered in various applications such as automotive (valve components), aerospace (engine components) and medical devices (implants). Metal injection molding (MIM) has proven to be an efficient near net-shape technology suitable for high volume manufacturing of parts having complex geometries. The MIM technology is particularly attractive for producing composites as the metallic matrix does not go through the liquid state. This helps minimizing the segregation of the hard particles. MIM also reduces the needs for machining. However, the production of titanium components with the MIM process has its own challenges and limitations, such as presence of porosities and coarser microstructures compared to wrought products. The present work introduces the results obtained during the development of a MIM route for producing Ti6Al4V-5wt%TiC composites. The feedstock developed is wax-based and incorporates a pre-alloyed metal powder. The microstructure, mechanical properties at room and elevated temperatures, the wear resistance and the thermal diffusivity of the composites have been characterised. Properties are compared with those of a Ti6Al4V MIM material produced with the same feedstock and process but without TiC as well as with those of wrought Ti6Al4V reported in the literature. The presence of a small amount of TiC promotes densification and grain size refinement and affects the surface finish of the sintered components. Tensile properties of the composites are comparable or better than those of wrought Ti6Al4V (ASTM F1472). Improved mechanical properties compared to unreinforced material are associated to the higher density, finer grain size as well as solution strengthening of the titanium matrix.

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Periodical:

Key Engineering Materials (Volume 704)

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139-147

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.704.139

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Online since:

August 2016

Authors:

Roger Pelletier*, Louis Philippe Lefebvre, Eric Baril

Keywords:

Metal Injection Moulding, Metal Matrix Composites, Titanium

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