Patent Grant
9022743
Components that are exposed to high temperatures, such as turbine engine hardware, typically include protective coatings. For example, components such as turbine blades, turbine vanes, blade outer air seals, combustor liners and compressor components typically include one or more coating layers that serve to protect the component from erosion, oxidation, corrosion or the like and thereby enhance component durability and maintain efficient engine operation.
Internal stresses can develop in the protective coating over time with continued exposure to high temperature environments in an engine. The internal stresses can lead to erosion, spalling and loss of the coating. The component is then replaced or refurbished.
Disclosed is a turbine engine article that includes a substrate and a thermally insulating topcoat on a surface of the substrate. The surface of the substrate includes a surface pattern that defines first surface regions and second surface regions. The first surface regions include incubation sites that are favorable for deposition of the thermally insulating topcoat and the second surface regions are less favorable for deposition of the thermally insulating topcoat. The thermally insulating topcoat includes segmented portions that are separated by faults extending through the thermally insulating topcoat from the second regions.
Also disclosed is a method of fabricating a turbine engine article. The method includes providing a substrate that has a surface pattern defining first surface regions and second surface regions. The first surface regions include incubation sites that are favorable for deposition of a thermally insulating topcoat and the second surface regions are less favorable for deposition of the thermally insulating topcoat. The thermally insulating topcoat is deposited onto the surface pattern such that the thermally insulating topcoat forms with faults that extend through the topcoat from the second regions to separate segmented portions of the topcoat.
The various features and advantages of the disclosed examples will become apparent to those skilled in the art from the following detailed description. The drawings that accompany the detailed description can be briefly described as follows.
In the illustrated example, the turbine engine 10 is suspended from an engine pylon 12 of an aircraft, as is typical of an aircraft designed for subsonic operation. The turbine engine 10 is circumferentially disposed about an engine centerline, or axial centerline axis A. The turbine engine 10 includes a fan 14, a compressor 16 having a low pressure compressor section 16a and a high pressure compressor section 16b, a combustion section 18, and a turbine 20 having a high pressure turbine section 20b and a low pressure turbine section 20a.
As is known, air compressed in the compressors 16a, 16b is mixed with fuel that is burned in the combustion section 18 and expanded in the turbines 20a and 20b. The turbines 20a and 20b are coupled to drive, respectively, rotors 22a and 22b (e.g., spools) to rotationally drive the compressors 16a, 16b and the fan 14 in response to the expansion. In this example, the rotor 22a drives the fan 14 through a gear train 24.
In the example shown, the turbine engine 10 is a high bypass, geared turbofan arrangement, although the examples herein can also be applied in other engine configurations. In one example, the bypass ratio of bypass airflow (D) to core airflow (C) is greater than 10:1, the fan 14 diameter is substantially larger than the diameter of the low pressure compressor 16a and the low pressure turbine 20a has a pressure ratio that is greater than 5:1. The gear train 24 can be any known suitable gear system, such as a planetary gear system with orbiting planet gears, planetary system with non-orbiting planet gears, or other type of gear system. In the disclosed example, the gear train 24 has a constant gear ratio. It is to be appreciated that the illustrated engine configuration and parameters are only exemplary and that the examples disclosed herein are applicable to other turbine engine configurations, including ground-based turbines that do not have fans.
As can be appreciated, the low pressure compressor section 16a, the high pressure compressor section 16b, the high pressure turbine section 20b, the low pressure turbine section 20a and the combustor 18 include turbine engine components, generally designated as components 30, that are subjected to relatively high temperatures during engine operation. The components 30 include one or more of rotatable blades, stationary vanes, outer air seals, combustors and liners, heat shields, exhaust cases and turbine frames, as well as any component that utilizes a thermal barrier coating, for example.
In one embodiment, the first surface regions 38 have a first surface roughness and the second surface regions 40 have a second surface roughness that is less than the first surface roughness. The first surface roughness and the second surface roughness are defined by the parameter Ra, for example. In one example, the surface roughness is provided by masking off the areas of the second surface regions 40 and peening the remaining areas of the first surface regions 38 to a predetermined roughness. In another example, the surface roughness is provided by grit blasting the entire surface of the substrate 32, masking off the areas of the first surface regions 38 and chemically milling the remaining areas to form the second surface regions 40 to smooth the roughness created by the milling. Alternatively, the roughness is provided during formation of the substrate 32, in a casting process, for example. In other alternatives, the roughness is provided by laser or chemical etching, or selectively depositing fine grit particles on the areas of the first surface regions 38. The fine grit particles are of the same or similar composition as the substrate 32 and/or thermally insulating topcoat 34.
The relative roughness of the first surface regions 38 versus the roughness of the second surface regions 40 serves as the incubation sites 42 that are favorable for deposition of the thermally insulating topcoat 34. For example, the roughness defines random peaks and valleys in the first surface regions 38. The peaks and valleys provide surface discontinuities that are favorable for the deposition of the thermally insulating topcoat 34. In one embodiment, the surface discontinuities have a maximum dimension of 5 to 10 micrometers with regard to an average distance between the peaks and valleys. If fine grit particles are used, the particles are 5 to 10 micrometers in average diameter. In further examples, the maximum dimension (e.g., height) of the surface discontinuities is less than 100 micrometers. In a further alternative, the maximum dimension of the surface discontinuities is less than 25 micrometers.
The thermally insulating topcoat 34 includes segmented portions 34a and 34b that are separated by faults 44 (one shown) that extend through the thermally insulating topcoat 34 from the second region 40. It is to be understood that the component 30 includes multiple segmented portions separated by multiple faults 44. The faults 44 facilitate reducing internal stresses within the thermally insulating topcoat 34 that may occur from sintering of the topcoat material at relatively high surface temperatures within the turbine engine 10 during operation.
Depending on the location in the turbine engine 10, the thermally insulating topcoat 34 can be exposed to temperatures of 2500° F. (1370° C.) or higher, which may cause sintering of the thermally insulating topcoat 34. The sintering may result in partial melting, densification, and diffusional shrinkage of the thermally insulating topcoat 34 and thereby induce internal stresses. The faults 44 provide pre-existing locations for releasing energy associated with the internal stresses (e.g., reducing shear and radial stresses). That is, the energy associated with the internal stresses may be dissipated in the faults 44 such that there is less energy available for causing delamination cracking between the thermally insulating topcoat 34 and the underlying substrate 32. The faults 44 may also serve as expansion gaps for thermal expansion of the topcoat 34.
The structure of the faults 44 can vary depending upon the process used to deposit the thermally insulating topcoat 34 and the surface pattern 36, for instance. In one example, the faults 44 are gaps between neighboring segmented portions 34a and 34b. Alternatively, or in addition to gaps, the faults 44 are microstructural discontinuities between neighboring segmented portions 34a and 34b. For instance, the segmented portions 34a and 34b have a columnar grain microstructure 46 and the faults 44 are microstructural discontinuities between neighboring clusters or “cells” of grains. Thus, the faults 44 may be considered to be planes of weakness in the thermally insulating topcoat 34 such that the segmented portions 34a and 34b can thermally expand and contract without producing a significant amount of stress from restriction of a neighboring segmented portion 34a or 34b and/or any cracking that does occur in the thermally insulating topcoat 34 from internal stresses is dissipated through propagation of the crack along the faults 44. Thus, the faults 44 facilitate dissipation of internal stress energy within the thermally insulating topcoat 34.
Referring to
The geometry of the grid with regard to shape and dimensions of the surface pattern 36 controls the deposition of the thermally insulating topcoat 34 and formation of the faults 44. For example, each of the first surface regions 38 defines a maximum dimension (D1) and the borders define a minimum dimension (D2) of the second surface regions 40. The dimensions D1 and D2 are predefined to provide a desired fault density and degree of thermal protection. For example, if dimension D2 is too large relative to dimension D1, the faults 44 form as relatively large gaps in the thermally insulating topcoat 34 and debit thermal protection. On the other hand, if dimension D2 is too small relative to dimension D1, the thermally insulating topcoat 34 can bridge over or onto the second surface regions 40 and thus avoid proper formation of the faults 44. Thus, a predetermined ratio of D1/D2 (D1 divided by D2) is selected to provide a balance of thermal protection and fault formation. In one example, the ratio is from 6 to 50. In a further example, the ratio is from 7.5 to 25.
In a further example, the geometry of the incubation sites 42 with regard to dimensions is also controlled. In one embodiment, the incubation sites 42, such as the surface discontinuities, have a maximum dimension of D3, and D2 is greater than D3. Controlling D2 to be greater than D3 ensures that the second surface regions 40 are discernible from the first surface regions 38 to form the segmented portions 34a and 34b.
In a further embodiment, the selected maximum dimension (D1) of the first surface regions 38 is smaller than a spacing of cracks that would occur naturally, without the faults 44, which makes the thermally insulating topcoat 34 more resistant to spalling and delamination.
In the illustrated example, the substrate 32 optionally includes a metallic alloy, a metallic bond coat or both. In embodiments, the metallic alloy is a superalloy material, such as a nickel-based or cobalt-based alloy. For example, the topcoat 34 is deposited directly on to the superalloy substrate. In another embodiment, the superalloy includes a bond coat thereon to enhance bonding with the topcoat 34. In some embodiments, the bond coat includes a nickel alloy, platinum, gold, silver, or MCrAlY where the M includes at least one of nickel, cobalt, iron, or combination thereof, Cr is chromium, Al is aluminum and Y is yttrium.
In the disclosed example, the thermally insulating topcoat 34 is a ceramic material that is selected to provide a desired thermal resistance for the given end use application. As an example, the thermally insulating topcoat 34 is or includes yttria stabilized zirconia, hafnia, gadolinia, gadolinia zirconate, molybdate, alumina or combinations thereof and can be graded or ungraded. Given this description, one of ordinary skill in the art will recognize other types of ceramic materials to meet their particular needs.
The faults 44 form during the deposition of the thermally insulating topcoat 34. In one example, the deposition process includes a thermal spray technique. One example thermal spray technique that is capable of producing the desired columnar grain microstructure 46 is a suspension or solution plasma spray process in which particles of the coating material are suspended in a mixture with a liquid or semi-liquid carrier. The mixture is sprayed into a plasma discharge that volatilizes the carrier and melts or partially melts the coating material. The melted or partially melted coating material then kinetically deposits onto the first surface regions 38 of the surface pattern 36 of the substrate 32.
As shown in
Although a combination of features is shown in the illustrated examples, not all of them need to be combined to realize the benefits of various embodiments of this disclosure. In other words, a system designed according to an embodiment of this disclosure will not necessarily include all of the features shown in any one of the Figures or all of the portions schematically shown in the Figures. Moreover, selected features of one example embodiment may be combined with selected features of other example embodiments.
The preceding description is exemplary rather than limiting in nature. Variations and modifications to the disclosed examples may become apparent to those skilled in the art that do not necessarily depart from the essence of this disclosure. The scope of legal protection given to this disclosure can only be determined by studying the following claims.
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