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Prillieux, Aurélien
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Publications (6/6 displayed)
- 2024Microstructural Modifications and Failure Mechanisms of an Aluminum‐Based Abradable Coating System During Isothermal and Cyclic Aging
- 2024Rheology of Ti-6Al-4V alloy under non equilibrium conditions during β forgingcitations
- 2024Surface reactivity during a hot isostatic pressing treatment of Ni-based superalloy René 77 specimens manufactured by laser powder bed fusion and metal inject moldingcitations
- 2023Protection of titanium alloys against high temperature oxidation during closed-die forging: Structural analysis of the boro-silicate glass coating/Ti-6Al-4V alloy interfacial region by correlative imagingcitations
- 2017Internal oxidation in dry and wet conditions for oxygen permeability of Fe–Ni alloys at 1150 and 1100 °Ccitations
- 2017Hydrogen and water vapour effects on oxygen solubility and diffusivity in high temperature Fe-Ni alloys
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article
Microstructural Modifications and Failure Mechanisms of an Aluminum‐Based Abradable Coating System During Isothermal and Cyclic Aging
Abstract
<jats:p>Abradable systems are used in the aeronautical industry to improve the efficiency of gas turbine. Those materials are exposed in service to temperature up to 450 °C. The increase in gas turbine efficiency requires to increase the operating temperature and therefore the service temperature of abradable coating. The present study focuses on the isothermal and cyclic thermal aging of the Al–Si abradable coating system in a laboratory air at high temperature up to 500 °C. The investigation encompasses the microstructural evolution, phase transformation, and the formation of cracks, along with their interrelated effects. During aging, silicon particles precipitate in the abradable top coat. In addition, coarsening of those particles is observed and the coarsening kinetics appears to be faster in cyclic thermal aging conditions compared to isothermal aging. During cyclic and isothermal aging, brittle aluminides develope at the abradable top–coat/bond–coat interface, due to the interdiffusion of Al and Ni species. During cyclic aging, thermal cycles create thermomechanical stress at the top‐coat/bont‐coat interface due to coefficient of thermal expansion mismatch between the Al‐Si deposit and intermetallic phases. The stress generated results in the formation of cracks and porosities at the top–coat/bond–coat interface resulting in a dramatic failure of the system.</jats:p><jats:p>This article is protected by copyright. All rights reserved.</jats:p>