Improving the high temperature oxidation resistance of pure titanium by shot-peening treatments

Improving the high temperature oxidation resistance of pure titanium by shot-peening treatments

Shot-peening (SP) treatments have shown their capacity to improve the oxidation resistance of titanium and zirconium thanks to the large compressive stresses and the surface hardening induced by this mechanical process. However, shot-peening treatments can produce a surface chemical deposit, which c...

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Bibliographic Details
Published in:Surface & coatings technology Vol. 343; pp. 93 - 100
Main Authors: Kanjer, A., Optasanu, V., Marco de Lucas, M.C., Heintz, O., Geoffroy, N., François, M., Berger, P., Montesin, T., Lavisse, L.
Format: Journal Article
Language:English
Published: Lausanne Elsevier B.V 15-06-2018
Elsevier BV
Elsevier
Subjects:
Aluminum oxide
Chemical Sciences
Compressive properties
Finishing
Gravimetric analysis
Heat treating
High temperature oxidation
High temperature physics
Material chemistry
Nuclear reaction analysis
Organic chemistry
Oxidation resistance
Oxidation tests
Shot peening
Surface hardening
Surface modification
Surface roughness
Titanium
Titanium oxynitrides
Tungsten carbide
X ray photoelectron spectroscopy
Zirconium
Nuclear reaction analysis
Titanium
Surface modification
Titanium oxynitrides
Shot-peening
High temperature oxidation
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Summary:Shot-peening (SP) treatments have shown their capacity to improve the oxidation resistance of titanium and zirconium thanks to the large compressive stresses and the surface hardening induced by this mechanical process. However, shot-peening treatments can produce a surface chemical deposit, which can modify the high temperature oxidation resistance. Here, we study pure titanium samples shot-peened with different type of balls: tungsten carbide, alumina or glass. The oxidation behavior was studied at 700°C in dry air by thermo gravimetric analysis for short isotherm oxidation periods up to 100h. Also, long oxidation tests (3000h) at 700°C were performed with an intermittent monitoring of the samples mass. The oxidized samples were characterized by XRD, SEM/EDS, XPS and nuclear reaction analysis. After 100h of oxidation the alumina ball shot-peening treatment produced the most resistant samples. The smallest α-case area was found for the samples that received the most energetic mechanical treatment. The formation of a continuous nitride layer observed underneath the oxide layer can explain the oxidation resistance improvement. Shot-peening treatments with alumina balls produce an alumina deposit on the samples surface that participates to reduce the oxidation. The chemical and structural surface modifications brought by the mechanical treatment participate to the oxidation resistance improvement. For long oxidation periods (3000h), the shot-peening with WC balls followed by a stripping with glass balls was the only treatment that showed an oxidation resistance improvement. •Shot-peening improves high temperature (700°C) oxidation resistance of pure-Ti.•Surface chemical and structural modifications appear as a function of balls nature.•For short oxidation (<100h) treatment with alumina balls present lower mass gain.•The higher surface energy imposed by treatments enhances the nitrogen insertion.•Glass-stripped shot-peened samples, oxidized for 3000h show no spallation.
ISSN:0257-8972
1879-3347
DOI:10.1016/j.surfcoat.2017.10.065