Abstract
Calcium-magnesium-alumino-silicate (CMAS) corrosion is a critical factor which causes the failure of thermal barrier coating (TBC). CMAS attack significantly alters the temperature and stress fields in TBC, resulting in their delamination or spallation. In this work, the evolution process of TBC prepared by suspension plasma spraying (SPS) under CMAS attack is investigated. The CMAS corrosion leads to the formation of the reaction layer and subsequent bending of TBC. Based on the observations, a corrosion model is proposed to describe the generation and evolution of the reaction layer and bending of TBC. Then, numerical simulations are performed to investigate the corrosion process of free-standing TBC and the complete TBC system under CMAS attack. The corrosion model constructs a bridge for connecting two numerical models. The results show that the CMAS corrosion has a significant influence on the stress field, such as the peak stress, whereas it has little influence on the steady-state temperature field. The peak of stress increases with holding time, which increases the risk of the rupture of TBC. The Mises stress increases nonlinearly along the thick direction of the reaction layer. Furthermore, in the traditional failure zone, such as the interface of the top coat and bond coat, the stress obviously changes during CMAS corrosion.
Highlights
Thermal barrier coating (TBC) is widely used in gas turbines and aircraft engines to protect the metallicJ Adv Ceram 2021, 10(3): 551–564 deposited by air plasma spray (APS) or electron-beam physical vapor deposition (EB-PVD)
The infiltration of CMAS caused a mismatch of thermal expansion coefficients between infiltrated and noninfiltrated layers, which further caused the curvature of the coating to change during cooling
The temperature and stress fields of suspension plasma spraying (SPS) TBC under CMAS corrosion are investigated by combining experiments with numerical simulations
Summary
Thermal barrier coating (TBC) is widely used in gas turbines and aircraft engines to protect the metallic. APS is a lowcost process depositing the YSZ coating with a parallel layered architecture, and EB-PVD deposits the YSZ coating with a microstructure of vertical columnar grains that increases the strain tolerance due to the intercolumnar porosity [6,7]. Both techniques show two drawbacks: EB-PVD is rather expensive for wide-scale application, and APS TBC typically has a shorter thermal lifetime. A novel thermal spray technique has been developed, suspension plasma spraying (SPS), which might be a process combining the advantages of APS and EB-PVD [8] This low-cost process can lead to the formation of columnar structures or vertical cracks in the TC layer, which improve strain tolerance of the TBC. A new method has been developed to describe the mechanical behaviors of SPS TBCs under CMAS attack, by combining experiments with numerical simulations
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