Durability Modeling Review of Thermal- and Environmental-Barrier-Coated Fiber-Reinforced Ceramic Matrix Composites Part I
Abstract
:1. Introduction
2. TBC and EBC Physical Characteristics
3. TBC and EBC Processing Methods
3.1. Plasma-Sprayed Coatings
3.2. The Electron-Beam Physical Vapor Deposition (EB-PVD) Process
3.3. Sputter-Deposited Thermal Barrier Coating
3.4. Processing of Plasma-Spray Physical Vapor Deposition (PS-PVD) TBC Coating
3.5. Slurry Deposition Technique
3.6. Chemical Deposition Process (CVD)
4. Testing of EBCs and TBCs
5. Failure Modes of TBCs and EBCs
- (1)
- Cracks spanning from the top coat through the thickness to the bond/intermediate coat interface and to the bond/substrate line with a formation and growth of horizontal crack alongside the interfaces. These cracks are linked and eventual spallation of the coating is imminent. Also, reactions at the interface and the formation of internal pores further accelerate the coating spallation. Figure 6 shows the inter-laminar failure of the coating and the stress contour due to combined thermal and mechanical load obtained from a finite element based analysis.
- (2)
- Moisture through the coating to the substrate/bond coat interface and oxygen diffusion followed by formation of pores and oxidation of the substrate, linkage of the pore and eventual spallation of the coating. This observation is noted when a mismatch of thermal expansion between the substrate and the coating co-exist. An example of this mechanism is shown in Figure 7, which shows pore formation at the substrate/coating interface leading to coating delamination.
6. Conclusions
- (1)
- The need to develop modeling methodologies to determine and assess the life of the EBC and its durability is very essential to its success. However, factors that affect or influence the EBC stability, mechanisms of degradation and failure modes are to be determined and included in the modeling process.
- (2)
- In order for the CMC to be successful in the use of making engine components, the coatings that are applied have to offer a reliant means of protection. This translates into the fact that the life of the coated CMC is highly dependent on the life of the coating and not the uncoated substrate life. It further means that if the coating fails under certain condition, then then the CMC life is considerably decreased.
- (3)
- Predicting the durability and the life of the EBC alone and the CMC after the coating failure is very crucial to introducing CMC engine components coated with EBC.
- (4)
- Finally, a detailed representation of TBC and EBC physical characteristics along with their processing methodologies, testing procedures/approach and failure modes has been summarized. The focus on their failure modes and in particular the EBC is an essential element of this review since it is quite complex and modeling such aspects of failure modes requires extensive analytical/experimental testing efforts to include the causing factors. However, this is outside the scope of this article.
Funding
Conflicts of Interest
Nomenclature
EB-PVD | Electron-beam physical vapor deposition |
TBC | Thermal barrier coating |
EBC | Environmental barrier coating |
CMC | Ceramic matrix composite |
CTE | Thermal expansion |
E | Young’s modulus |
v | Poisson’s ratio |
ST | Tensile strength |
SC | Compressive strength |
SS | Shear stress |
PS-PVD | Plasma-spray-assisted physical vapor deposition |
CVD | Chemical deposition process |
PECVD | Chemical vapor deposition |
LACVD | Laser-assisted chemical vapor deposition |
BSAS | Barium strontium aluminosilicate |
αc | Coefficient of thermal expansion of the coating |
αsubstrate | Coefficients of thermal expansion of the substrate, respectively |
Ec | Young’s modulus of the coating |
νc | Possion’s ratio of the coating |
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Thermal Barrier Coating (TBC) | Environmental Barrier Coating (EBC) |
---|---|
Applied and used in hot gas engine environment on metal, their role is to protect the engine components in the hot gas path from the effects of the operating temperature. | Used on ceramic matrix composites (CMCs) or for any high temperature application where oxygen is present, it is to help decreasing oxidation-induced recession in silicon-based ceramic composites, and a need to lessen the operating temperature to weaken creep in oxide-based composites. |
An aero TBC is a zirconia-yttria (or other zirconia based) ceramic on a metallic MCrAlY bond coat over a superalloy. MCrAlY coatings (where M = Co, Ni or Co/Ni) are widely applied to first and second stage turbine blades and nozzle guide vanes, where they may be used as corrosion resistant overlays or as bond-coats for use with thermal barrier coatings. | An EBC or EBC/TBC has a zirconia or hafnia TBC top coat for thermal insulation over a silicate-ceramic environmental coating to protect the substrate from water-vapor attack. |
Because of temperature, a buildup of a layer called thermally grown oxide (TGO) is generated between the ceramic layer and the bond coat. This is due to the oxidation effect of the bond coat during oxidation and thermal shock. The TGO is to hinder the process of oxidation of the bond coat. | A silicon bond coat is between the EBC and the substrate, which is a CMC. EBC are for ceramic and CMC substrates. EBC role is to provide protection from environmental assault. |
TBCs are for metallic substrates and provide thermal protection. The TBC top coat is in compression. | EBC top coat is in tension. Cracks are easy to form, but tension cracks in EBCs are not as damaging as compression cracks are in TBCs |
Compared to EBCs, TBCs have better strain tolerance. | Both TBCs and EBCs require a bond coat on top of their substrate followed by a top coat on the surface. Bond coats may be multilayered. |
The major trigger of failure in thermal barrier coating is the stresses, they generally initiated by bond coat oxidation, bond coat surface irregularities, yttria stabilized zirconia (YSZ) phase transformation, and YSZ sintering [5]. | Environmental barrier coating failure is generally triggered by chemical reactions not stresses. They further lead to degradation and spallation. Lead life-limiting reactions are water vapor volatility of the surface layer, chemical reactions between various EBC layers, including silica TGO, and the oxidation of silicon bond coat. Therefore, EBC design should take into account the latter effects and ensure that chemical reactions are limited to minimum [5]. |
Typical thickness: 1–1.5 mil bond coat, 3–4 mil top coats. | Typical Thickness: 15 mil for combustor (rough coating), 5–10 mil for vane (smooth), 5 mil goal for blade (smooth). |
Features | Evaporation | Sputtering Deposition | CVD | Electro Deposition | Thermal Spraying |
---|---|---|---|---|---|
Mechanism to produce deposition species | Thermal energy | Momentum transfer | Chemicals reaction | Solution | Flame or Plasma |
Deposition rate | Moderate up to 750,000 A/min | Low | Moderate | Low to High | Very high |
Deposition species | Atoms | Atoms/Ions | Atoms/ion | Ions | Droplets |
Complex Shape | Poor line of sight | Good but non uniform | Good | Good | Poor resolution |
Deposits in small, blind holes | Poor | Poor | Limited | Limited | Very Limited |
Metal/alloy deposition | Yes | Yes | Yes | Yes | Yes |
Refractory compounds and ceramics | Yes | Yes | Yes | Limited | Yes |
Energy of deposits species | Low | Can be high | Can be high | Can be high | Can be high |
Growth interface perturbation | Not normally | Yes | Yes | No | No |
Substrate heating | Yes normally | Not generally | Yes | No | Not normally |
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Abdul-Aziz, A. Durability Modeling Review of Thermal- and Environmental-Barrier-Coated Fiber-Reinforced Ceramic Matrix Composites Part I. Materials 2018, 11, 1251. https://doi.org/10.3390/ma11071251
Abdul-Aziz A. Durability Modeling Review of Thermal- and Environmental-Barrier-Coated Fiber-Reinforced Ceramic Matrix Composites Part I. Materials. 2018; 11(7):1251. https://doi.org/10.3390/ma11071251
Chicago/Turabian StyleAbdul-Aziz, Ali. 2018. "Durability Modeling Review of Thermal- and Environmental-Barrier-Coated Fiber-Reinforced Ceramic Matrix Composites Part I" Materials 11, no. 7: 1251. https://doi.org/10.3390/ma11071251
APA StyleAbdul-Aziz, A. (2018). Durability Modeling Review of Thermal- and Environmental-Barrier-Coated Fiber-Reinforced Ceramic Matrix Composites Part I. Materials, 11(7), 1251. https://doi.org/10.3390/ma11071251