• Title of article

    Calcium–magnesium–alumino-silicate (CMAS) degradation of EB-PVD thermal barrier coatings: Characterization of CMAS damage on ex-service high pressure blade TBCs

  • Author/Authors

    Vidal-Setif، نويسنده , , M.H. and Chellah، نويسنده , , N. and Rio، نويسنده , , C. and Sanchez، نويسنده , , C. and Lavigne، نويسنده , , O.، نويسنده ,

  • Issue Information
    روزنامه با شماره پیاپی سال 2012
  • Pages
    7
  • From page
    39
  • To page
    45
  • Abstract
    The use of thermal barrier coatings (TBCs) on turbine blades and vanes located in the hot sections of gas turbine engines has allowed higher engine operating temperatures leading to temperatures of the order of 1200 °C at the surface of the ceramic coating. At such temperatures, under service conditions, thermal barrier coatings are susceptible to corrosion by molten calcium–magnesium–alumino-silicates (CMAS) resulting from the ingestion of siliceous mineral debris (dust, sand, ash) by the engine. tudy consists in a microstructural analysis of CMAS induced degradation of standard 8YPSZ EB-PVD thermal barriers observed on high pressure turbine blades of military engines removed from service. The CMAS/TBC interactions are mainly observed in the hottest zones of the blade pressure side. CMAS infiltration in the TBC porous microstructure (inter-columnar gaps, pores, cracks) down to the thermally grown oxide TGO interfacial layer is observed as well as dissolution of the 8YPSZ into the CMAS melt, TBC transformation from tetragonal 8YPSZ to monoclinic Y-depleted zirconia and formation of a Zr-bearing phase at the interface between CMAS and TBC. CMAS not only turns out to be mainly constituted of CaO, MgO, Al2O3, and SiO2 but also contains a large amount of iron oxide Fe2O3. Comparison with previous published data shows that CMAS composition depends on the flight conditions to a large extent. A part from the loss of column integrity and the modification of the porous morphology resulting from the CMAS chemical attack, large vertical separations between highly sintered columns are observed in the CMAS infiltrated TBC as well as delamination cracks in the upper part of the top coat possibly leading to progressive TBC spallation. These results are discussed in the light of similar studies on CMAS/TBC interaction and of existing sintering and delamination mechanisms.
  • Keywords
    Thermal barrier coatings , CMAS , Delamination , turbine blade , 8YPSZ , EB-PVD
  • Journal title
    Surface and Coatings Technology
  • Serial Year
    2012
  • Journal title
    Surface and Coatings Technology
  • Record number

    1826521