The invention relates generally to thermally protective coatings for metal structures.
Gas turbine components are subjected to rigorous mechanical loading, thermal stress, oxidation, corrosion, and abrasion. Hot gas path components of such turbines are often made of nickel or cobalt based superalloys optimized for resistance to high temperature creep and thermal fatigue. Protective coatings are applied to increase durability and field performance at high temperatures. MCrAlY (where M represents a transition metal, and Y represents yttrium) is a material commonly used as a protective coating, especially as a bond coat for an overlying ceramic insulation as part of a thermal barrier coating (TBC) system. Such bond coats prevent the substrate from being deteriorated by oxygen, and they act as an intermediary to bridge the difference in the coefficients of thermal expansion (CTE) between the ceramic and metallic materials, thereby reducing stress levels.
MCrAlY materials have been optimized for thermal and chemical compatibility with the superalloys along with oxidation and corrosion resistance. In gas turbine components, the M in MCrAlY is normally nickel (Ni) and/or cobalt (Co). Nickel-based alloys provide superior oxidation resistance, and cobalt-based alloys provide superior corrosion resistance. The chromium (Cr) provides hot corrosion resistance, and aluminum (Al) aids in formation of a stable oxide barrier. Yttrium (Y) enhances adherence of the oxide layer. Elemental additions of cerium, silicon, lanthanum or hafnium to the bond coats are done to improve their performance in terms of the oxidation or thermo-mechanical behavior and ceramic coating adherence. Performance of a TBC often depends on the ability of the underlying MCrAlY bond coating to form a tenacious, protective, aluminum oxide scale that is thermodynamically stable, slow growing, adherent, and that inhibits interactions between the substrate surface and the outside corrosive environment.
The invention is explained in the following description in view of the drawings that show:
A thermally grown oxide (TGO) layer 38 such as aluminum oxide forms on the outer surface of the bond coat 22 due to exposure of the layer to oxygen at high temperatures. In a TBC system comprising a superalloy substrate, a bond coat, and a ceramic topcoat, this oxide layer, which forms between the ceramic insulation 26 and the bond coat 22, provides insulation from further oxidation, corrosion, and heat. The TGO layer 38 grows during high temperature operation by diffusion 28 of aluminum to the outer surface of the bond coat 22 in the presence of oxygen diffused through the TBC layer 26.
The formation of the outer β depletion zone 32 is primarily driven by the formation of the oxide layer 38 at the outer surface of the bond coat 22. This depletes the concentration of aluminum in the metal adjacent to the oxide. Thus, outer β depletion is proportional to the growth of the oxide scale. The inner β depletion 30 is a function of β-phase instability in the presence of changing matrix γ-phase compositions in the bond coat 22 caused by substrate/coating interdiffusion. For some superalloy compositions, the inward loss 30 of the β phase to the substrate 24 is more rapid at a given temperature than is the outward loss 28 of the β phase to the TGO 38. Since aluminum lost through inner β phase depletion is not utilized for TGO 38 growth, it is essentially wasted for the function it was applied to perform, i.e. availability for maintenance of the passive oxide scale 38. The present inventors have appreciated that any amount of inner β depletion contributes to a debit from the ideal coating oxidation resistance. Thus, it is proposed herein to control aluminum diffusion in the bond coat—particularly the inward diffusion of aluminum atoms into the substrate 24.
One way to reduce aluminum diffusion is to delay diffusion within the bond coat 22 itself, and/or slow its migration. This can be achieved by certain elemental additions to an MCrAlY bond coat material that modify the beta phase structure, or which catalyze and/or recombine with the diffusing aluminum to precipitate secondary aluminum-rich phases γ′ (with about 6 wt % Aluminum (Al)) and B2 (with about 7 wt % Aluminum (Al)) within the bond coat. These secondary phases recapture the aluminum temporarily, thus slowing its migration.
The new element(s) combine with diffusing elements in such a way as to promote and stabilize new aluminum rich phases in the region of the original coating/substrate interface. Thus, inner β-phase dissolution 30 is delayed, leading to prolonged life of the coating system. Creating one or more stable second aluminum-rich phases γ′, B2 requires addition of one or more element(s) that combine with the escaping aluminum in a diffusion interaction to form solid precipitant phases. The additional elements may be selected from strontium (Sr), ruthenium (Ru), lanthanum (La), praseodymium (Pr), neodymium (Nd), promethium (Pm), samarium (Sm), europium (Eu), gadolinium (Gd), terbium (Tb), dysprosium (Dy), holmium (Ho), erbium (Er), thulium (Tm), ytterbium (Yb), tantalum (Ta), rhenium (Re), and combinations thereof. The γ′ phase is typically NiAl3 and the B2 phase is typically complex precipitates (Aluminides of nickel, cobalt, chromium and one of the additional elements from above). These elements are called “seed elements” herein, and an MCrAlY layer modified with them in prescribed amounts is called a “seed layer”. Some examples of these additions are tabulated below, showing their mechanisms of improvement. Certain combinations of such additions have special synergies, as tabulated below. A seed layer 21 will maintain a high aluminum concentration or reservoir in and above the original coating/substrate interface in the form of metal precipitants.
Compositions 1-3 above are examples of a seed layer embodiment with additions of 1-4 wt % of one or more lanthanides, especially praseodymium (Pr), neodymium (Nd), promethium (Pm), samarium (Sm), europium (Eu), gadolinium (Gd), terbium (Tb), dysprosium (Dy), holmium (Ho), erbium (Er), thulium (Tm), ytterbium (Yb), lutetium (Lu), and combinations thereof. Composition 5 above reduces the average beta precipitant microstructure size by reducing the percentage of precipitants in the 7-10 micron range, and increasing their percentage in the 1-7 micron range. This has been found to slow aluminum diffusion. While this finer particle size provides higher surface area for oxidation, it also provides increased precipitant recombination opportunities.
Another way to reduce aluminum diffusion into the substrate is to apply an MCrAlY seed layer 21 modified with seed elements, and then apply a second layer 22 on the seed layer. The second layer may be a conventional MCrAlY bond coat 22, or it may be another seed layer composed according to the invention. In either case, aluminum that would diffuse from the second layer 22 into the substrate 24 is delayed and reserved in the first seed layer 21 by one or more of the mechanisms listed above.
The first layer 21 may have chemistry similar to that of the second layer 22, but may incorporate one or more of the above seed elements not found in the second layer. Thus, the first and second layers 21, 22 may be considered distinct for discussion and illustration purposes. In practice, the first layer 21 may be a subset of the overall thickness of the second layer 22 wherein specific elements have been added and are available for the formation of secondary metal precipitants desired as an aluminum reservoir. One or more seed elements may be added throughout a seed layer or only to a region of the coating that is remote from a surface where it is desired to form a protective alumina layer 38. For example, an MCrAlY layer with seed elements concentrated adjacent the substrate may be achieved by means of layered deposition using atmospheric/low pressure/vacuum plasma or high velocity oxy-fuel spraying. The first layer thickness may be 50-200 micrometers, with a preferred range of 75-125 micrometers. In a two-layer system, the combined thickness of the two layers may be in the range of 125 to 325 micrometers.
Multiple layers with the new elemental additions may be used. The presence of multiple seed layers forms multiple precipitated aluminum phases as diffusion progresses. When multiple seed layers are used, they may have the same or different compositions from each other.
MCrAlY bond coat compositions can be modified to improve oxidation and corrosion resistance and thermo-mechanical properties by additional alloying elements or by an oxide dispersion in the matrix. Additions of hafnium (Hf), platinum (Pt), titanium (Ti), tungsten (W), and/or tantalum (Ta) offer oxidation resistance. Addition of rhenium (Re) improves isothermal or cyclic oxidation resistance and thermal cycle fatigue. One or more of these elements may be incorporated in a first and/or second layer of the present invention to provide these improvements.
For example, the bond coat and/or the seed layer(s) may be composed of MCrAlY with 8-12 wt % aluminum and 1-2 wt % rhenium, and the seed layer(s) or the single bond/seed layer may further comprise one or more of the listed seed layer additions.
A seed layer may be 50 to 200 micrometers thick with a preferred range of 75-125 micrometers. Each elemental addition results in a given composition of precipitants and mechanism of performance improvement. The listed combination of 2-5 wt % tantalum and 1-3 wt % lanthanum has a dual mechanism—it both reduces the original beta phase grain size, and produces a Ta-rich secondary beta phase.
The conventional bond coat and/or the modified layer(s) may be deposited by known methods such as air plasma or vacuum plasma/low pressure plasma, wire-arc, flame combustion, high velocity oxy-fuel or a cold spray process, depending on the operational requirements. Also, any known method of forming powders for use in bond coat applications may be used. For example, not to be limiting, a bond coat powder may be prepared by gas atomization of the components to obtain relatively uniform chemistry of the powder particles, which then are deposited or otherwise applied onto a substrate.
Embodiments of the present invention may include components for turbines, such as gas turbine engines, as well as for any other device having a need for a component comprising a thermal barrier system having an advanced bond coat effective to provide increased protection and durability as described herein.
The present invention provides metallic coatings with elemental additions that form secondary and possibly tertiary and quaternary aluminum-rich phase precipitation events. The result of these precipitation events keeps an aluminum reservoir between the oxidizing outer surface of the coating and the substrate rather than allowing the aluminum to diffuse into the substrate base metal, and become unusable for passive oxide growth. This results in superior oxidation resistance and longer life at high temperatures.
While various embodiments of the present invention have been shown and described herein, it will be obvious that such embodiments are provided by way of example only. Numerous variations, changes and substitutions may be made without departing from the invention herein. Accordingly, it is intended that the invention be limited only by the spirit and scope of the appended claims.
This application claims the benefit of four U.S. provisional patent applications: 60/973,560, filed Sep. 19, 2007; 60/974,558, filed Sep. 24, 2007; 60/974,561, filed Sep. 24, 2007; and 60/974,564, filed Sep. 24, 2007. These provisional applications are incorporated by reference herein in their entirety.
Number | Date | Country | |
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60973560 | Sep 2007 | US | |
60974558 | Sep 2007 | US | |
60974561 | Sep 2007 | US | |
60974564 | Sep 2007 | US |