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In-situ Ti-6Al-4V/TiC composites synthesized by reactive spark plasma sintering: processing, microstructure, and dry sliding wear behaviour

In-situ Ti-6Al-4V/TiC composites synthesized by reactive spark plasma sintering: processing, microstructure, and dry sliding wear behaviour
In-situ Ti-6Al-4V/TiC composites synthesized by reactive spark plasma sintering: processing, microstructure, and dry sliding wear behaviour
Titanium carbide (TiC) reinforced Titanium Matrix Composites (TMCs) have been synthesized via an in-situ reactive spark plasma sintering (SPS) process using commercial Ti-6Al-4V spherical powders pre-coated with 1 wt% carbon nanoparticles by low-energy ball milling. Graphite flakes are used as carbon source, which aids powder flow during mixing as lubricant. Graphite transforms to nano-crystallite carbon during mixing which is favourable for the rapid formation of TiC second phase in the following SPS process. The composites exhibited a novel honeycomb-like cellular microstructure with the formation of 5–6 vol% fine TiC submicron grains interconnected in the titanium α/β matrix. In addition, the reinforcement of the TiC phase with a nano-hardness of 12.4 GPa, improves the wear resistance of the parent alloy matrix (5.1 GPa), with a reduction of 26–28% in wear rate during dry reciprocating sliding tests against Si3N4 balls. During sliding, the wear debris (predominantly anatase TiO2) builds up on the raised TiC hard phase forming a barrier layer of adhered oxide that can protect the alloy matrix underneath from abrasion and oxidation, leading to a reduced wear rate.
Titanium matrix composites, Powder processing, SPS, Graphite, TiC, Wear
0043-1648
Bai, Mingwen
c5d2c6e5-4eaf-4f2d-80ed-a87493abcf10
Namus, Righdan
080fd40e-b7c0-4624-99a7-22a0cca0c8ee
Xu, Yidong
e65bc33d-6707-452d-afd8-b9b18edb352d
Guan, Dikai
d20c4acc-342a-43fa-a204-7283f0cc33bf
Rainforth, Mark W.
7226983c-4ca1-4f0a-8191-02e3424dc98f
Inkson, Beverley J.
e4a7412c-4547-4c29-9500-219d58ac689f
Bai, Mingwen
c5d2c6e5-4eaf-4f2d-80ed-a87493abcf10
Namus, Righdan
080fd40e-b7c0-4624-99a7-22a0cca0c8ee
Xu, Yidong
e65bc33d-6707-452d-afd8-b9b18edb352d
Guan, Dikai
d20c4acc-342a-43fa-a204-7283f0cc33bf
Rainforth, Mark W.
7226983c-4ca1-4f0a-8191-02e3424dc98f
Inkson, Beverley J.
e4a7412c-4547-4c29-9500-219d58ac689f

Bai, Mingwen, Namus, Righdan, Xu, Yidong, Guan, Dikai, Rainforth, Mark W. and Inkson, Beverley J. (2019) In-situ Ti-6Al-4V/TiC composites synthesized by reactive spark plasma sintering: processing, microstructure, and dry sliding wear behaviour. Wear, 432. (doi:10.1016/j.wear.2019.202944).

Record type: Article

Abstract

Titanium carbide (TiC) reinforced Titanium Matrix Composites (TMCs) have been synthesized via an in-situ reactive spark plasma sintering (SPS) process using commercial Ti-6Al-4V spherical powders pre-coated with 1 wt% carbon nanoparticles by low-energy ball milling. Graphite flakes are used as carbon source, which aids powder flow during mixing as lubricant. Graphite transforms to nano-crystallite carbon during mixing which is favourable for the rapid formation of TiC second phase in the following SPS process. The composites exhibited a novel honeycomb-like cellular microstructure with the formation of 5–6 vol% fine TiC submicron grains interconnected in the titanium α/β matrix. In addition, the reinforcement of the TiC phase with a nano-hardness of 12.4 GPa, improves the wear resistance of the parent alloy matrix (5.1 GPa), with a reduction of 26–28% in wear rate during dry reciprocating sliding tests against Si3N4 balls. During sliding, the wear debris (predominantly anatase TiO2) builds up on the raised TiC hard phase forming a barrier layer of adhered oxide that can protect the alloy matrix underneath from abrasion and oxidation, leading to a reduced wear rate.

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More information

Published date: 15 August 2019
Keywords: Titanium matrix composites, Powder processing, SPS, Graphite, TiC, Wear

Identifiers

Local EPrints ID: 475017
URI: http://eprints.soton.ac.uk/id/eprint/475017
DOI: doi:10.1016/j.wear.2019.202944
ISSN: 0043-1648
PURE UUID: 88dd9e8d-4de9-4bcd-bf88-10a3cdf4fbf2
ORCID for Dikai Guan: ORCID iD orcid.org/0000-0002-3953-2878

Catalogue record

Date deposited: 08 Mar 2023 17:55
Last modified: 17 Mar 2024 04:17

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Contributors

Author: Mingwen Bai
Author: Righdan Namus
Author: Yidong Xu
Author: Dikai Guan ORCID iD
Author: Mark W. Rainforth
Author: Beverley J. Inkson

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