The present invention generally relates to methods for modifying the cross-sectional area of a hole. More particularly, this invention relates to a coating process that can be controlled to selectively resize a hole, a nonlimiting example being a premix fuel supply hole of a fuel nozzle assembly of a gas turbine.
In gas turbines, a fuel nozzle typically comprises a subassembly of generally concentric tubes defining a central passage for supplying diffusion fuel gas and a pair of concentric passages for supplying premix fuel gas. Spaced from and surrounding the subassembly is an inlet flow conditioner for directing and confining a flow of inlet air past a plurality of circumferentially spaced vanes carried by the subassembly. The vanes are in communication with the concentric fuel gas supply passages. Particularly, the vanes include outer and inner premix fuel supply holes for supplying gas from the respective passages for mixing with the inlet air. The gas fuel mixture is swirled by the vanes downstream of the premix fuel supply holes for subsequent combustion.
As represented in
The gas fuel composition and Wobbe Index (an indicator of the interchangeability of fuel gases) at site locations determine the fuel gas nozzle exit velocity requirement, which in turn is dependent upon the premix fuel supply hole size. Where the premix fuel supply holes 24 are too large for a given gas composition and Wobbe Index, nozzle dynamics become a concern. This oversized orifice may be the result of wear or a mistake in original orifice dimension. Typically, as in the case of the fuel nozzle assembly 10, one or more of the premix fuel supply holes 24 being oversized may deem the part unusable for its intended purpose.
One method of repair for the fuel nozzle assembly 10 is to take it apart, replace the vane 22 with the oversized premix fuel supply holes 24, and re-assemble the nozzle assembly 10. This can be an expensive way to salvage an otherwise unusable part and can result in scrapping of the fuel nozzle assembly 10 under some situations. Another method involves inserting plugs into the premix fuel supply holes 24 and securing them to the vane 22, possibly using a braze technique. New holes are formed through at least three of the plugs to diameters less than the diameter of the original premix fuel supply holes 24. Thus, the original premix fuel supply holes 24 are resized to provide smaller holes with consequent desired tuning effects. Yet another method includes welding the premix fuel supply holes 24 shut and then trying to find the original locations so they can be re-drilled to a smaller size.
All of the above solutions can be expensive and time consuming, among other individual disadvantages. For example, solutions that involve techniques such as welding can be difficult to perform without damaging the vane 22 and braze joints that may have been used to fabricate the assembly 10.
In view of the above, it can be appreciated that there is a need for an improved method of resizing premix fuel supply holes of fuel nozzle assemblies for gas turbine engines, as well as other types of holes whose cross-sectional area must be controlled. It would be particularly advantageous if such a method were capable of requiring less effort and expense than techniques such as welding, which can damage components of a complex device.
The present invention provides methods suitable for modifying the cross-sectional areas of holes within complex devices, including but not limited to premix fuel supply holes of gas turbine fuel nozzle assemblies.
According to a first aspect of the invention, a method of reducing an initial cross-sectional area of a hole in a component to a predetermined cross-sectional area includes preparing a composition comprising at least an aluminum alloy with a melting temperature higher than aluminum, applying the composition to an interior surface of the hole, and then heating the component to cause a metal within the component to diffuse from the component into the composition and react with the aluminum alloy in the composition to form a coating on the interior surface of the hole. The heating step is performed to selectively modify the initial cross-sectional area of the hole and thereby directly attain the predetermined cross-sectional area thereof.
According to a second aspect of the invention, a method of tuning a fuel nozzle assembly for a gas turbine having a plurality of circumferentially spaced vanes with holes through walls of the vanes for flowing fuel for premixing with air within the nozzle assembly includes preparing a composition comprising at least an aluminum alloy with a melting temperature higher than aluminum, applying the composition to an interior surface of at least a first of the holes within an individual vane of the plurality of vanes, the first hole being in an oversized condition that causes fuel flowing therethrough to flow at a flow rate that is higher than a predetermined flow rate for the first hole, and then heating the vane to cause a metal within the vane to diffuse from the vane into the composition and react with the aluminum alloy in the composition to form a coating on the interior surface of the first hole. The heating step is performed to selectively modify a cross-sectional area of the first hole and thereby directly attain the predetermined flow rate thereof.
According to a third aspect of the invention, a method is provided for reducing an initial cross-sectional area of a flow path defined as a gap between at least two mating components to a predetermined cross-sectional area. The method includes preparing a composition comprising at least an aluminum alloy with a melting temperature higher than aluminum, applying the composition to an interior surface of a first component of the two mating components and/or an exterior surface of a second component of the two mating components to yield coated components, and then heating the coated components to cause a metal within the coated components to diffuse from the coated components into the composition and react with the aluminum alloy in the composition to form a coating on the interior surface of the first component and/or the exterior surface of the second component. The heating step is performed to selectively modify the initial cross-sectional area of the flow path and thereby directly attain the predetermined cross-sectional area thereof.
A technical effect of the invention is the ability to resize the cross-sectional area of one or more holes within a complex device, such as fuel nozzle assembly of a gas turbine engine, while avoiding techniques, such as welding, that can damage components of the complex devices.
Other aspects and advantages of this invention will be better appreciated from the following detailed description.
The present invention will be described in reference to a fuel nozzle assembly vane 22 that is represented in
As represented in
The supply holes 42 are represented as being the result of resizing pre-existing holes 24 in accordance with a preferred embodiment of the invention. As previously discussed, the pre-existing holes 24 may have become oversized due to wear or a mistake in original orifice dimensions which can leave the vane 22 unusable. In order to reduce the inner diameter of the pre-existing holes 24, an adherent diffusion aluminide coating 50 is represented as having been formed on the interior surfaces of the holes 24, as represented in
According to a preferred aspect of the invention, the coating 50 is an outward-type coating, that is, a coating that is formed under conditions that promote an outward diffusion of a metal from the substrate, for example, nickel, into a deposited aluminum-containing composition to form an additive layer, and also reduce the inward diffusion of aluminum from the deposited aluminum-containing composition into the substrate, resulting in a relatively thick additive layer above the original surface of the substrate.
More specifically, the aluminum-containing composition includes an aluminum alloy with a melting temperature that is higher than aluminum, so that the majority of the gaseous aluminum species forms at temperatures sufficiently high for metal constituents within the substrate of the vane 22 to be actively diffused outward. This produces an acceptable balance of inward and mostly outward diffused coating. At a temperature of 760° C. or more substantially pure aluminum (as most slurry coating compositions contain) would diffuse into the surfaces of the holes 24, prior to diffusion of metal constituents within the substrate out of the vane 22. If the vane 22 is nickel-based, the inward diffused aluminum would react with the nickel to form a diffusion area within near-surface substrate regions of the vane 22 that contains nickel aluminide intermetallic compounds. In contrast, with preferred aluminum-containing compositions used with the present invention, which intentionally contain one or more aluminum alloys with a melting temperature that is higher than aluminum, gaseous aluminum species form at temperatures (e.g., greater than or equal to 1065° C. (about 1940° F.)) that promote the majority of coating formation to be outward from the interior surfaces of the holes 24. The nickel moves into the precursor coating where it reacts and combines with the gaseous aluminum species to form an outward-type diffusion coating. Since the majority of the coating formation is outward from the interior surfaces of the holes 24, the properties of the underlying vane 22 remains relatively unchanged.
As previously stated, the aluminum-containing composition comprises an aluminum alloy with a higher melting temperature than aluminum (melting point of about 660° C.). Particularly suitable compositions include metallic aluminum alloyed with chromium, cobalt, iron, and/or another aluminum alloying agent with a sufficiently higher melting point so that the alloying agent does not deposit during the diffusion process, but instead serves as an inert carrier for the aluminum of the composition. The aluminum alloy (Al-M, wherein M is a metallic element such as chromium, cobalt, iron, etc.) of the aluminum-containing composition can have a concentration of about 20 wt % to about 70 wt % Al, preferably about 30 wt % to about 60 wt % Al, and more preferably about 35 wt % to about 50 wt % Al (the balance M and incidental impurities).
The aluminum-containing composition is preferably in the form of a slurry or gel. In this situation, the aluminum alloy can be in the form of a powder having various particle sizes. For example, all particles of the powder can have a size (as measured along a major axis) of less than or equal to about 125 micrometers, preferably about 30 micrometers to about 120 micrometers, more preferably about 40 micrometers to about 80 micrometers, and most preferably about 40 micrometers to about 60 micrometers.
The aluminum-containing composition contains one or more activators that facilitate the liberation of the aluminum, that is, the separation of the aluminum from the alloy and the formation of gaseous aluminum species therefrom, at a temperature greater than or equal to the temperature that facilitates the majority of the coating formation to be outward from the interior surfaces of the holes 24. Possible activators include halides such as aluminum chloride (NH4Cl), aluminum fluoride (NH4F), and ammonium bromide (NH4Br), which produce an aluminum halide as the gaseous aluminum species, though the use of other halide activators is also believed to be possible.
The activator may suitably serve as a binder capable of adhering the aluminum-containing composition to the interior surfaces of the holes 24. Alternatively or in addition, the aluminum-containing composition can further comprise one or more binders for this purpose. Suitable additional/alternative binders preferably consist essentially or entirely of alcohol-based or water-based organic polymers. A preferred aspect of the invention is that any additional binder present in the aluminum-containing composition is able to burn off entirely and cleanly at temperatures below that required to vaporize and react the halide activator, with the remaining residue being essentially in the form of an ash that can be easily removed.
Preferred slurry or gel compositions contain the aluminum alloy powder and the activator in an amount of about 10 to about 80 weight percent, with the balance being the additional binder. Particularly suitable slurry compositions for use with this invention contain, by weight, about 35 to about 65% aluminum alloy powder, about 25 to about 60% binder, and about 1 to about 25% activator. More preferred ranges are, by weight, about 35 to about 65% aluminum alloy powder, about 25 to about 50% binder, and about 5 to about 25% activator. These ranges allow the slurry to be applied to the interior surfaces of the holes 24 by a variety of methods.
In order to apply the slurry or gel to the hole 24, the vane 22 must first be removed from the fuel nozzle assembly. The slurry or gel may then be applied by any means known in the art. Suitable examples include, but are not limited to, manual application with a brush, spatula, eye dropper, swab, or needle, as well as application by submersion, air brush, or other spraying means. Once coated with the aluminum-containing composition, the vane 22 is heated and held at an elevated temperature until the coating 50 has achieved a desired thickness. A sufficient time and temperature for the diffusion process will depend on the aluminum-containing composition used; however, a temperature greater than or equal to about 1065° C. (about 1940° F.) is preferable for vanes 22 composed of materials such as nickel, cobalt, and/or iron. At about this temperature, the activator preferably reacts with the aluminum alloy of the aluminum-containing composition to form a gaseous aluminum species and the nickel, cobalt, and/or iron from the superalloy is sufficiently diffused outward. This environment at the surface then reacts to reform and deposit an aluminide on the interior surfaces of the holes 24.
By forming the coating 50 in the above described manner, the decrease in the inner diameter of the holes 24 can be tailored by adjusting the composition or thickness of the aluminum-containing composition and/or adjusting the time and/or temperature of the heating of the vane 22. For example,
According to an alternative embodiment of the present invention,
While the invention has been described in terms of specific embodiments, it is apparent that other forms could be adopted by one skilled in the art. For example, the physical configuration of the holes could differ from that shown, and materials and processes other than those noted could be used. In addition, the use of an outwardly grown aluminide coating can add thickness to the exterior surface of a superalloy component. By this means gaps or channels can also be tailored or repaired to meet flow requirements. Therefore, the scope of the invention is to be limited only by the following claims.
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Number | Date | Country |
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Entry |
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Copy of European Search Report and Written Opinion issued in connection with corresponding EP Application No. 13191650.4-1602 dated Feb. 11, 2014. |
Number | Date | Country | |
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20140124100 A1 | May 2014 | US |