Thermal Analysis of Calcium–Magnesium–Alumino–Silicate Infiltration Dynamics in Thermal Barrier Coatings

Molten calcium–magnesium–alumino–silicate (CMAS) infiltration into thermal barrier coatings (TBCs) of gas turbines causes loss of strain tolerance and delamination of the ceramic topcoat. To develop efficient mitigation strategies, it is crucial to understand CMAS infiltration dynamics into the poro...

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Bibliographic Details
Published in:Journal of thermophysics and heat transfer 2021-07, Vol.35 (3), p.611-622
Main Authors: Munuhe, Timothy W, Zhu, Liang, Ma, Ronghui
Format: Article
Language:English
Subjects:
Bilayers
Calcium magnesium silicates
Capillary pressure
Chemical bonds
Coatings
Columns (structural)
Computational fluid dynamics
Contact angle
Corrosion
Electron beams
Electron-beam physical vapor deposition
Gas turbines
Heat conductivity
Heat transfer
High temperature
Infiltration rate
Liquid flow
Mechanical engineering
Multilayers
Nonlinear dynamics
Oxidation
Physical vapor deposition
Pressure gradients
Temperature dependence
Temperature distribution
Thermal analysis
Thermal barrier coatings
Thermal cycling
Thickness
Turbines
Unsaturated flow
Viscosity
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Summary:Molten calcium–magnesium–alumino–silicate (CMAS) infiltration into thermal barrier coatings (TBCs) of gas turbines causes loss of strain tolerance and delamination of the ceramic topcoat. To develop efficient mitigation strategies, it is crucial to understand CMAS infiltration dynamics into the porous topcoat. This study introduces an integrated model, incorporating liquid flow in unsaturated porous structures, heat transfer, and temperature-dependent viscosities, to study CMAS infiltration through TBCs grown by the electron beam physical vapor deposition (EB-PVD) method. The effects of different CMAS compositions, temperature gradients across the topcoat, and coating microstructures are investigated. Our simulation shows that CMAS infiltration exhibits significantly nonlinear dynamics with a fast infiltration rate at the early stage due to high temperature, high pressure gradients, and low viscosity. Neglecting heat transfer enhancement from CMAS by approximating the temperature distribution as linear underestimates the infiltration rate. Fine porous microstructures slow infiltration, and bilayer or multilayer structures, consisting of variable column and pore sizes, combine the advantages of an increased hydraulic resistance to infiltration and lower capillary pressures. Such heterogeneous structures can delay early-stage infiltration by manipulating the layer thickness and arrangement. It is anticipated that the quantitative information and advanced understanding obtained would benefit the development of CMAS-resistant EB-PVD TBC topcoats.
ISSN:1533-6808
0887-8722
1533-6808
DOI:10.2514/1.T6171