The invention relates to a turbine part, such as a turbine blade or a nozzle vane for example, used in aeronautics.
In a turbojet engine, the exhaust gases generated by the combustion chamber can reach high temperatures, exceeding 1200° C. or even 1600° C. A turbojet engine part in contact with these exhaust gases, such as a turbine blade for example, must therefore be able to maintain its mechanical properties at such high temperatures. Moreover, corrosion and/or oxidation of the substrate of the part is promoted by such high temperatures.
To this end, it is known to protect the part against excessive temperatures, oxidation and/or corrosion, by covering it with an environmental barrier.
The environmental barrier 3 degrades particularly when exposed to sand particles (for example inorganic compounds such as silica) or more generally to calcium, magnesium, aluminum and/or silicon oxides, the acronym for which is CMAS. CMAS have lower melting temperatures than the materials of the environmental barrier 3, and thus can infiltrate in a molten state into the environmental barrier 3 during use of the part 1, particularly into the interstices of the environmental barrier 3. CMAS infiltration into the environmental barrier 3 leads to the stiffening of the environmental barrier 3, which can lead to mechanical failure of the environmental barrier 3 under the operating conditions of the turbine. CMAS infiltration also leads to dissolution of the thermal insulation layer 7 by chemical reaction between the CMAS and the thermal insulation layer 7.
With reference to
With reference to
Levi et al. (Levi, C. G., Hutchinson, J. W., Vidal-Sétif, M. H., & Johnson, C. A. (2012). Environmental degradation of thermal-barrier coatings by molten deposits. MRS bulletin, 37(10), 932-941) describes the use of a part 1 coated with rare-earth zirconate, such as Gd2Zr2O7 (GZO). On contact with CMAS, the rare-earth zirconate is dissolved and precipitates, on the one hand, into a fluorite phase Zr(Gd,Ca)Ox and, on the other, into a very stable apatite phase Ca2Gd8(SiO4)6O2. These precipitations lead to the filling of the interstices present between the different GZO columns and/or the thermal insulation layer 7 and to the formation of a diffusion barrier, thus slowing the dissolution rate of the GZO columns and/or the thermal insulation layer 7.
On the other hand, precipitation of molten CMAS, described by Levi et al., fills the interstices when the CMAS has entered the interstices of the GZO and/or the thermal insulation layer 7, leading to deterioration of the mechanical properties of the environmental layer 3.
For example, a reactive layer of lanthanum zirconate (La2Zr2O7) can also be deposited on a turbine part. Upon contact of the reactive layer with molten CMAS, a portion of the reactive layer is dissolved, and the reaction between the reactive layer and the CMAS produces an apatite phase of Ca2La8(SiO4)6O2. Cracks appear in the reactive layer, resulting in areas of the part that are not protected from CMAS.
US 2016/011589 describes a reactive layer comprising an anti-CMAS coating comprising an oxide having a weberite structure, to prevent infiltration of molten CMAS into the environmental barrier.
One aim of the invention is to increase the resistance of a turbine part to CMAS compounds.
Another aim of the invention is to propose a coating enabling a turbine part to resist CMAS compounds different from a known coating of the prior art.
Another aim of the invention is to propose a coating enabling a turbine part to resist CMAS compounds and having adjustable mechanical and/or chemical properties.
These aims are achieved in the context of the present invention by virtue of a turbine part, comprising:
characterized in that the material of the reactive layer comprises an oxide of formula A′A″BO5+δ, A′ being selected from a rare-earth element and yttrium, A″ being selected from a rare-earth element, yttrium and aluminum, B being selected from titanium, zirconium, hafnium, tantalum and niobium, δ being a real number comprised between 0 and 0.5.
The invention is advantageously supplemented by the following features, taken individually or in any technically possible combination thereof:
Fm
Pnma [Math. 2]
and
P63/mmc [Math. 3]
The invention also relates to a process for protecting a turbine part comprising a step of depositing on the part a reactive layer suitable for reacting with at least one CMAS compound selected from a calcium oxide, a magnesium oxide, an aluminum oxide and a silicon oxide, characterized in that the material of the reactive layer comprises an oxide of formula A′A″BO5+δ, A′ being selected from a rare-earth element and yttrium, A″ being selected from a rare-earth element, yttrium, scandium and aluminum, B being selected from titanium, zirconium, hafnium, tantalum and niobium, δ being a real number comprised between 0 and 0.5.
Advantageously, the process is supplemented by the following features, taken individually or in any technically possible combination thereof:
Other features, aims and advantages of the invention will emerge from the following description, which is purely illustrative and non-limiting, and which should be read in conjunction with the appended drawings in which:
Throughout the figures, similar elements bear identical reference marks.
The term “superalloy” refers to an alloy which, at high temperature and high pressure, has very good resistance to oxidation, corrosion, creep and cyclic stresses (particularly mechanical or thermal stresses). Superalloys have a particular application in the manufacture of parts used in aeronautics, for example turbine blades, because they constitute a family of high-strength alloys that can work at temperatures relatively close to their melting points (typically 0.7 to 0.8 times their melting temperatures).
A superalloy can have a two-phase microstructure comprising a first phase (called “γ phase”) forming a matrix, and a second phase (called “γ′ phase”) forming precipitates hardening in the matrix. The coexistence of these two phases is referred to as the γ-γ′ phase.
The “base” of the superalloy refers to the main metal component of the matrix. In most cases, superalloys comprise an iron, cobalt, or nickel base, but sometimes also a titanium or aluminum base. The base of the superalloy is preferentially a nickel base.
“Nickel-base superalloys” have the advantage of providing a good compromise between oxidation resistance, high-temperature fracture resistance and weight, which justifies their use in the hottest parts of turbojet engines.
Nickel-base superalloys are made up of a γ phase (or matrix) of the γ-Ni face-centered cubic austenitic type, possibly containing additives in a (Co, Cr, W, Mo)-substituted solid solution, and a γ′ phase (or precipitates) of the γ′-Ni3X type, with X=Al, Ti or Ta. The γ′ phase has an ordered L12 structure, derived from the face-centered cubic structure, coherent with the matrix, i.e., having an atomic lattice very close thereto.
The term “volume fraction” refers to the ratio of the volume of an element or a group of elements to the total volume.
A “space group” of a crystal refers to the set of symmetries of a crystal structure, that is to say the set of affine isometries leaving the structure invariant. It is a group in the mathematical sense of the term. Preferentially, a crystal is organized, in the invention, according to a space group of the type
Fm
, a space group of the type
Pnma [Math. 5]
and/or a space group of the type
P63/mmc [Math. 6]
With reference to
The part 1 also comprises a reactive layer 9 suitable for reacting with at least one CMAS compound 8. The CMAS compound 8 may be selected from a calcium oxide, a magnesium oxide, an aluminum oxide and/or a silicon oxide and combinations thereof. The reactive layer 9 at least partially covers the environmental barrier 3. It can directly cover at least one of the layers of the environmental barrier 3, selected from the protective layer 5 and the thermal insulation layer 7. Different reactive layers 9 may also cover different layers of the environmental barrier 3. The embodiment illustrated in
The material of the reactive layer 9 comprises an oxide of formula A′A″BO5+δ, A′ being selected from a rare-earth element and yttrium, A″ being selected from a rare-earth element, yttrium, scandium and aluminum, B being selected from titanium, zirconium, hafnium, tantalum and niobium, δ being a real number comprised between 0 and 0.5. This formula allows the oxide of the reactive layer 9 (hereinafter “the oxide”) to have a volume fraction of rare-earth elements and/or yttrium high enough to allow rapid precipitation of the molten CMAS compound(s), and avoid their introduction into interstices presented in the environmental barrier 3. This formula can also advantageously allow the oxide of the reactive layer 9 to have a cubic lattice. Table 1 comprises the various elements A′, A″ and B that can be selected for the oxide.
Thus, the oxide material can have an atomic fraction of rare-earth elements and/or yttrium, aluminum and scandium comprised between 10% and 25%, and preferentially between 18% and 25% when A′ and A″ are rare-earth elements and/or yttrium. This range of atomic fractions of rare-earth elements and/or yttrium, comprising higher atomic fractions than those of Gd2Zr2O7 for example, allows the reactive layer 9 material to exhibit faster reaction kinetics with CMAS compound(s) 8 than materials described in the prior art (for example Gd2Zr2O7). Thus, the molten CMAS compound(s) 8 in contact with the reactive layer 9 are immobilized faster or are slowed by a production of an apatite phase, thickening and/or solidifying the reactive CMAS compound 8 at the interface with the environmental barrier 3, and avoiding contact between the CMAS compound(s) 8 and other parts of the environmental barrier 3.
By its composition, the oxide may also have a crystal lattice with a cubic crystal structure, preferentially having a space group of the type
Fm
, and/or a hexagonal type crystal structure, preferentially with a space group
Pnma [Math. 8]
, and/or a hexagonal type structure, preferentially with a space group
P63/mmc [Math. 9]
Advantageously, the elements A′ and A″ may be different. Thus, the reactivity of the oxide with respect to a/the CMAS(s) 8 can be increased by the formation of different phases, comprising at least one apatite phase, for example of formula Ca2RE8(SiO4)6O2, RE being a rare-earth element or yttrium. One or more secondary oxides may also be produced by the reaction between the oxide and the CMAS compound(s) 8.
Advantageously, the elements A′, A″, B are selected so as to allow the formation of a secondary oxide, resulting from the reaction between the oxide and the CMAS compound(s) 8. The secondary oxide formed may be reactive to secondary products of the reaction between the oxide and the CMAS compound(s) 8. The secondary oxide formed may also be directly reactive with the CMAS compound 8. The secondary oxides produced may be, for example:
These different secondary oxides can be suitable for forming an apatite phase upon reaction with the CMAS compound(s) 8.
The elements A′ and A″ may be the same element A: the oxide of the reactive layer 9 may be described by the formula A2BO5+δ, δ being a real number comprised between 0 and 0.5. The elements of the oxide are selected from the elements described in Table 2.
Thus, the atomic fraction of rare-earth element or aluminum or scandium or yttrium can be increased compared with the known oxides, due to the oxide structure. The production of the reactive layer 9 can also be simplified in this way.
Advantageously, the reactive layer 9 may comprise other anti-CMAS oxides. The reactive layer 9 may comprise between 5% and 80% by volume of said oxide and further comprises at least 10% by volume of an element selected from YSZ, Al2O3, Y2O3—ZrO2—Ta2O5, RE2Zr2O7 and RE2Si2O7 and combinations thereof, where RE denotes an element selected from yttrium and a lanthanide.
Another aspect of the invention is a process for protecting a part against molten sand(s). The process comprises a step of depositing the reactive layer 9 as described above, on a part 1, or a portion of the part 1. “Portion of the part 1” means a portion of the surface and/or an inner portion of the part 1 (in which case one or more layers of the part 1 may cover the reactive layer 9 once the part 1 is manufactured). After deposition, the part 1 comprises the reactive layer 9. The reactive layer 9 may be deposited directly on the substrate 2 of the part 1, for example a superalloy substrate 2, or on one or more layers of an environmental barrier 3. The deposition of the reactive layer 9 can be performed on at least one of the layers forming the environmental barrier 3, and preferentially on the thermal insulation layer 7. Thus, and unlike known parts, the part 1 comprising the reactive layer 9 deposited on the thermal insulation layer 7 has sufficient reactivity with CMAS compound(s) 8 to produce at least one apatite phase before the insertion of the molten CMAS compound(s) 8 into the interstices of the thermal insulation layer 7, and thus avoid or limit this insertion. In this way, the CMAS compound(s) 8 can have greater difficultly accessing the surface of the environmental barrier 3, and their effect on the breakdown of the environmental barrier 3 is limited.
Reaction between a liquid CMAS 8 and a reactive layer of Gd2TiO5
With reference to
With reference to
Number | Date | Country | Kind |
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1873666 | Dec 2018 | FR | national |
Filing Document | Filing Date | Country | Kind |
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PCT/FR2019/053269 | 12/20/2019 | WO | 00 |