The invention pertains to a heat-insulating protective layer for a component within the hot-gas section of a gas turbine with the features of the introductory clause of Claim 1.
In modern gas turbines, almost all of the surfaces in the hot-gas section are provided with coatings. Exceptions in many cases are still the turbine blades in the rear of an array. The heat-insulating layers serve to lower the material temperature of the cooled components. As a result, their service life can be extended, cooling air can be reduced, or the gas turbine can be operated at higher inlet temperatures. Heat-insulating layer systems in gas turbines always consist of a metallic bonding layer diffusion bonded to the base material, on top of which a ceramic layer with poor thermal conductivity is applied, which represents the actual barrier against the heat flow and which protects the base metal of the component against high-temperature corrosion and high-temperature erosion.
As the ceramic material for the heat-insulating layer, zirconium oxide (ZrO2, zirconia) has become widely accepted, which is almost always partially stabilized with approximately 7 wt. % of yttrium oxide (international abbreviation: “YPSZ” for “Yttria Partially Stabilized Zirconia”). The heat-insulating layers are divided into two basic classes, depending on how they are applied:
thermally sprayed layers (usually by the atmospheric plasma spray (APS) process), in which, depending on the desired layer thickness and stress distribution, a porosity of approximately 10-25 vol. % in the ceramic layer is produced. Binding to the (raw sprayed) bonding layer is accomplished by mechanical interlocking;
layers deposited by the EB-PVD (Electron Beam Plasma Vapor Diffusion) process, which, when certain deposition conditions are observed, have a columnar or a columnar elongation-tolerant structure. The layer is bound chemically by the formation of an Al/Zr-mixed oxide on a layer of pure aluminum oxide, which is formed by the bonding layer during the application process and then during actual operation (Thermally Grown Oxide, TGO). This imposes very strict requirements on the growth of the oxide on the bonding layer.
As bonding layers, either diffusion layers or cladding layers can, in principle, be used.
The list of requirements on the bonding layers is complex and includes the following points which must be taken into account:
low static and cyclic oxidation rates;
formation of the purest possible aluminum oxide layer as TGO (in the case of EB-PVD);
sufficient resistance to high-temperature corrosion;
low ductile-brittle transition temperature;
high creep resistance;
physical properties similar to those of the base material, good chemical compatibility;
good adhesion;
minimal long-term interdiffusion with the base material; and
low cost of deposition in reproducible quality.
For the special requirements in stationary gas turbines, bonding or cladding layers based on MCrAlY (M=Ni, Co) offer the best possibilities for fulfilling the chemical and mechanical conditions. MCrAlY layers contain the intermetallic β-phase NiCoAl as an aluminum reserve in a NiCoCr (“γ”) matrix. The β-phase NiCoAl, however, also has an embrittling effect, so that the Al content which can be realized in practice is ≦12 wt. %. To achieve a further increase in the oxidation resistance, it is possible to coat the MCrAlY layers with an Al diffusion layer. Because of the danger of embrittlement, this is limited in most cases to starting layers with a relatively low aluminum content (Al≦8%).
The structure of an alitized MCrAlY layer consists of the inner, extensively intact γ, β-mixed phase; a diffusion zone, in which the Al content rises to ˜20%; and an outer β-NiAl phase, with an Al content of about 30%. The NiAl phase represents the weak point of the layer system with respect to brittleness and crack sensitivity.
In addition to the oxidation properties and the mechanical properties, the (inter)diffusion phenomena between the base material and the MCrAlY layer—in specific cases also between the MCrAlY layer and the alitized layer—become increasingly more important with respect to service life as the service temperature increases. In the extreme case, the diffusion-based loss of aluminum in the MCrAlY layer can exceed the loss caused by oxide formation. Through asymmetric diffusion, in which the local losses are greater than the supply of fresh material, defects and pores can form and, in the extreme case, the layer can delaminate.
The invention is based on the task of avoiding the disadvantages described above and, in the case of a heat-insulating protective layer of the general type in question, of slowing down the diffusion without negatively influencing the oxidation properties of the alitized layer or the ductility and creep resistance of the layer system.
The task is accomplished according to the invention in the case of a heat-insulating protective layer of the type in question by the characterizing features of Claim 1. Advantageous embodiments of the invention are the objects of Claims 2 and 3.
It has been found that diffusion can be slowed down through the modification of the specially composed NiCoCrAlY bonding layer by the addition preferably of Re but also of W, Si, Hf, and/or Ta in the indicated concentration. The service life of the heat-insulating protective layer, especially of the layer deposited by EB-PVD, is significantly extended by the resistance to diffusion to the base material and to the built-up alitized layer. In the event of the premature failure of the heat-insulating protective layer as a result of, for example, impact by a foreign body or erosion, a relatively long period of “emergency operation” remains possible.
The heat-insulating protective layer is produced in the following way. Onto the base metal of a cooled component in the hot-gas section, such as a blade of a gas turbine, a bonding layer is applied by a process such as thermal spraying. For this purpose, an atomized prealloyed powder with the following chemical composition is used: Co 15-30 wt. %, Cr 15-25 wt. %, Al 6-13 wt. %, Y 0.2-0.7 wt. %, with the remainder consisting of Ni. In addition, the powder also contains one or more of the elements Re up to 5 wt. %, W up to 5 wt. %, Si up to 3 wt. %, Hf up to 3 wt, and Ta up to 5 wt. %. The powder used thus preferably has the following chemical composition: Co 25 wt. %, Cr 21 wt. %, Al 8 wt. %, Y 0.5 wt. %, Re 1.5 wt. %, with the remainder consisting of Ni. After application, the bonding layer has the chemical composition of the powder which was used.
After it has been applied, the bonding layer is coated or the surface is alitized to create an Al diffusion layer to increase the Al content. The coating is accomplished by alitizing the surface, that is, by means of a treatment in which, at elevated temperature, a reactive Al-containing gas, usually an Al halide (AlX2), brings about an inward-diffusion of Al in association with an outward-diffusion of Ni.
When the surface is alitized in this way, an inner diffusion zone is formed within the diffusion layer on the extensively intact bonding layer, and on top of that an outer built-up layer of a brittle β-NiAl phase is formed. According to a process described in the (as yet unpublished) German Patent Application 10 2004 045 049.8, this outer layer is removed down to the inner diffusion zone of the diffusion layer by blasting it with hard particles such as corundum, silicon carbide, metal wires, or other known grinding or polishing agents. The abrasive treatment is continued until the surface of the remaining diffusion layer has an Al content of more than 18% and less than 30%.
After one of the previously cited processes, the ceramic layer of yttrium oxide-stabilized zirconium oxide is applied as the final step.
Number | Date | Country | Kind |
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10 2005 053 531.3 | Nov 2005 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP2006/010655 | 11/7/2006 | WO | 00 | 7/3/2008 |