ICMCTF2016 Session A2-1: Thermal and Environmental Barrier Coatings
Time Period TuA Sessions | Abstract Timeline | Topic A Sessions | Time Periods | Topics | ICMCTF2016 Schedule
Start | Invited? | Item |
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1:50 PM |
A2-1-2 Image-Based Modelling of TBC Thermal and Mechanical Properties using Sub-Micron Resolution X-ray Computed Tomography
Xun Zhang, James Carr, Etienne Bousser (The University of Manchester, UK); Allan Matthews (The University of Sheffield, UK); Ping Xiao, Philip Withers (The University of Manchester, UK) Thermal barrier coatings (TBCs) are widely used in modern turbine engines to provide thermal protection for metallic components in order to maximise engine efficiency through an increase in operating temperature. However, further improvements in TBC technologies require a better understanding of the correlation between microstructure and functional properties. In this study, we used non-destructive 3D X-ray Computed Tomography (XCT) with sub-micron resolution to investigate the microstructure of Air Plasma Sprayed (APS) Yttria-Stabilised Zirconia (YSZ) TBCs. Features including coating thickness, YSZ topcoat porosity and interface roughness were quantified in 3D. In particular, detailed information regarding the pore shape, spatial and size distribution and connectivity was obtained from real 3D microstructural images of the coatings. These images were then used to build Finite Element (FE) models in order to quantitatively correlate the microstructural features with the elastic modulus and effective thermal conductivity of the porous YSZ coatings. Modulus and thermal conductivity were also experimentally determined using depth-sensing indentation and laser flash thermal diffusivity. It was found that the APS TBC porosity is mainly in the form of inter-splat voids perpendicular to the spraying direction and also forms complex pore networks. Indeed, the intrinsic connectivity of pores in the YSZ coating dictates the low elastic modulus and thermal conductivity relative to its bulk counterpart. To gain more insight into these findings, a parametric study on artificial 3D microstructures was used to evaluate the effects of porosity volume fraction, shape and distribution on the coating's modulus and conductivity. It was found that for isolated pores, porosity volume fraction is almost linearly related to the effective modulus and conductivity. In addition, when a pore network is present, as in the case of APS TBCs, the effective properties are dominated by the minimum solid section area of the porous medium. In the case of coating elastic modulus, both modelling and experimental results showed a strong anisotropy. In fact, the FE models indicated that the modulus is a function of all porosity factors such as quantity, shape and distribution while thermal conductivity was found to be much less sensitive to porosity factors other than volume fraction. Keywords: Thermal barrier coatings, X-Ray Tomography, Thermal Conductivity, Elastic Modulus, Image-based Modelling |
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2:10 PM |
A2-1-3 The Effects of Temperature and Substrate Curvature on Residual Stress in Alumina Scales Beneath APS TBCs
Michael Lance, James Haynes, Bruce Pint (Oak Ridge National Laboratory, USA) In order to assess the role of temperature on the development of residual stresses in Al2O3 scales, two bond coating (BC) compositions, a vacuum plasma sprayed (VPS) NiCoCrAlYHf BC and a VPS NiCoCrAlYHfSi BC, deposited on Hf-rich directionally-solidified (DS) 247 substrates were thermally-cycled at temperatures ranging from 1075 to 1150 °C with 1-h cycles in 10% H2O. Photo-stimulated luminescence spectroscopy (PSLS) was used to map residual stresses in the Al2O3 scale at the YSZ/BC interface from the same region at regular cycling intervals. All samples exhibited similar stress distributions and rates of interfacial delamination with the exception of the YHfSi BC cycled at 1150 °C which had a lower average compressive stress with more delaminations. This BC composition also had the shortest TBC lifetime which shows that the PSLS measurements correlate well to interfacial damage accumulation in TBCs. The effect of sample curvature on the interfacial stress was assessed by comparing TBC-coated rod specimens to flat buttons. Research sponsored by the U. S. Department of Energy, Office of Fossil Energy, Coal and Power R&D. |
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2:30 PM |
A2-1-4 Thermal Behavior and Mechanical Properties of Y2SiO5 Coatings after Isothermal Heat Treatment
Byung-Koog Jang (National Institute for Materials Science, Japan); Fan-Jie Feng, Kee-Sung Lee (Kookmin University, Republic of Korea); Eugenio Garcia (Institute of Ceramics and Glass, Spain); Seongwon Kim, Yoon-Suk Oh (Korea Institute of Ceramic Engineering & Technology, Republic of Korea); Hyung-Tae Kim (Korea Institute of Ceramic Engineering and Technology, Republic of Korea) Y2SiO5 coatings have been deposited by flame spray technique as protection layer of SiC substrate from oxidation and steam corrosion. In this research, Y2SiO5 coatings are isothermal heat treated by different temperatures and different exposed times in laboratory environment condition. The thermal behaviors such as phase transformation, microstructure change and TGO deposition phenomena have been examined by XRD, SEM, and EDS analysis. The different TGO growth behaviors have been found at different temperature. In addition, the mechanical properties are evaluated by Martens hardness tester. The result shows that the change of microstructure and composition is not too critical, but high temperature and long exposed times are more easily to lead the phase transformation to Y2SiO5 crystalline phases and β-Y2O3 phase. It can improve the mechanical properties of Y2SiO5 coatings in terms of hardness and young’s modulus. |
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2:50 PM |
A2-1-5 Experimental Measurements of Thermal Barrier Coating Interfacial Fracture Toughness as a Function of Mode-Mix
Simon Lockyer-Bratton, Jaafar El-Awady, Kevin Hemker (Johns Hopkins University, USA) Mechanism-based lifetime assessment models of thermal barrier coating (TBC) systems rely on accurate knowledge of the experimentally measured interfacial fracture toughness, Gc, over a range of mode mix and especially at mode-II. Utilizing conventional 4-point bend experiments, inverted 4-point bend tests, and a newly developed compression edge-delamination (CED) methodology, has allowed for direct measurement of coating interfacial toughness as a function of mode mix. Two different material systems are examined, both of which consist of an Electron-Beam Physical Vapor Deposited (EBPVD) 7% Yttria-Stabilized Zirconia (YSZ) top coat, which is deposited on either a 1) Pt-modified diffusion aluminide bond coat on a René N5 substrate or a 2) Low Pressure Plasma Spray (LPPS) NiCoCrAly bond coat on a PWA1484 substrate. Using the CED test, reductions in pure mode-II interfacial toughness during thermal cycling between the as-deposited state and at coating lifetime have been determined to be ΔGc≈250 J/m2. Specimen preparation and the use of starter cracks to assure proper delamination will be discussed. Crack face friction has shown to play a significant role on Gc and details regarding the characterization and implementation into the Finite Element model used to extract the interfacial toughness will be examined. Finally, microstructural observations, including morphological and chemical changes, linked to the degradation of the coating interfaces due to thermal cycling will be analyzed. |
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3:10 PM | Invited |
A2-1-6 Internal Stresses in Thermal and Environmental Barrier Coatings
Katherine Faber (California Institute of Technology, USA) Thermal and environmental barrier coatings are necessary in aerospace and power generation applications to ensure desired lifetimes of engine components. The use of thermal barriers can result in a drop of more than 170°C across a 150 µm coating from the combustion environment to the underlying superalloy, while environmental barriers prevent the diffusion of corrosive species to Si-based ceramics and their composites. In both cases, bilayer or multilayer coatings needed for protection suffer from thermal-mismatch induced internal stresses. Moreover, such stresses change with time due to coating sintering, phase transformations, and reactions with external matter, such as calcium-magnesium-aluminosilicate (CMAS) deposits. Here, the use of high-energy X-rays for the study of internal stresses in multilayer systems will be described. Examples of coating phase transformations and reactions with molten CMAS and their influence on internal stresses also will be reviewed. |
3:50 PM |
A2-1-8 Ytrria-rich TBCs as: Candidates for a CMAS Resistant Top Coat
Juan Gomez, Chintalapalle Ramana (The University of Texas at El Paso, USA); Ravisankar Naraparaju, Uwe Schulz (DLR Institute of Materials Research, Germany) State of the art thermal barrier coatings (TBC) commonly made of 7-8 wt. % Yttria Stabilized Zirconia (7YSZ) are used in modern gas turbines to generate a thermal protection to the underlying super alloy. TBCs allow higher operating temperatures for hot gas path components generating higher engine efficiency. The infiltration of molten deposits composed of CaO-MgO-Al2O3-SiO2 (CMAS) represents one of the major threat in reducing performance and service life in aero and land based gas turbine engines. The CMAS deposits are ingested into the engine in the form of sand or dust particles. The ingested particles melt on the engine’s hot gas path components infiltrating the porous TBC, this infiltration generates detrimental effects on the coating such as degradation and spallation. The present work studied in detail the resistance of CMAS infiltration in YSZ TBCs by using a protective EB-PVD –top-coating with higher amounts of yttria (Y2O3). Studies were made by varying the Y2O3 content in YSZ in the range of 35 wt. % to -100 wt. % (rest is zirconia). CMAS infiltration experiments were performed at temperature ranges between 1200 ºC –and 1250 ºC -at time intervals from 1 to 10 hours using 4 different synthetized CMAS compositions. The results demonstrate that a 65 wt. % yttria-zirconia TBC possesses a better CMAS infiltration resistance than pure yttria coating. Further investigations are presented for the interaction of CMAS with coatings having lower yttria compositions. The interaction between TBC and CMAS is not only governed by the top coat chemistry, but it also depends on the CMAS composition. |
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4:10 PM |
A2-1-9 The Behaviour of TBC System with Al2O3 Sol-Gel Intermediate Layer under Thermal Cycling
Hesham AbdelDaim (Ain Shams University, Egypt) Surface engineering plays the essential role in enhancing the performance of high pressure turbines which work under the most severe conditions of temperature and mechanical loading. In this study, an intermediate α-Al2O3 layer was deposited by sol-gel on the raw surface of APS-CoNiCrAlY Bond Coat, which was deposited on superalloy substrate. The YSZ ceramic Top Coat was deposited on the top of Al2O3 layer by APS. The new TBC system was compared with the standard TBC system concerning the behavior under thermal cycling. The samples were investigated by optical microscopy; Scanning Electron Microscopy (SEM) equipped by Energy Dispersive X-ray analysis (EDX), X-ray Diffraction (XRD) and Raman spectroscopy. The crack length within the ceramic layer and the average thickness of TGO were measured using image analysis tool. It was found that the Al2O3 layer has the potential to reduce the crack length and TGO thickness by suppressing the formation of detrimental oxides. The Al2O3 layer has a barrier effect on oxygen diffusion .This effect enhances the behavior of metallic Bond Coat while suffering oxidation, and hence increases the TBC life. The information generated from the study can be used to improve the performance of the TBC system under different operating conditions. |