1. Field of the Invention
The subject invention is directed to fuel injectors for gas turbine engines, and more particularly, to an alignment and positioning system for installing a fuel injector in a reception bore formed in the engine case of a gas turbine engine.
2. Background of the Related Art
The inlet end fittings of prior art fuel injectors used in gas turbine engines have employed alignment pins to guide the installation of the fuel injector into a reception bore formed in the engine case, and to subsequently maintain the fuel injector in a desired position within the engine case once it has been installed. Typically, such alignment pins have been permanently secured within the mounting flange of the fuel injector. For example, two stainless steel conical alignment pins are currently brazed into corresponding apertures formed in the mounting flange of the fuel injectors used in the GE T700 turbo shaft engine, which went into service in the 1970's. These brazed alignment pins have been employed for decades by injector manufacturers to facilitate the guided installation and proper positioning of fuel injectors in an engine case of a gas turbine engine.
Those skilled in the art will readily appreciate however, that the current alignment pin design is costly and inconvenient, in that it requires the procurement, inspection, installation and brazing of multiple components.
It would be beneficial therefore, to provide a less expensive and more convenient system for ensuring the proper alignment and positioning of a fuel injector in the engine case of a gas turbine engine.
The subject invention is directed to a nozzle alignment and positioning system for installing and subsequently securing a fuel injector in a reception bore formed in the engine case of a gas turbine engine. More particularly, the subject invention is directed to a fuel injector for a gas turbine engine that includes a fuel inlet fitting having an annular mounting flange defining opposed upper and lower end surfaces and a generally cylindrical body portion which depends axially from the lower end surface of the mounting flange. In accordance with a preferred embodiment of the subject invention, integrally formed alignment means are located beneath the lower end surface of the mounting flange for guiding the fuel injector into an installed position within a reception bore of the engine case. The integrally formed alignment means eliminates the need for furnace brazing separate alignment pins into corresponding apertures formed in the mounting flange of the fuel injector, as known and practiced in the prior art for many years.
More particularly, the fuel inlet fitting of the subject invention is provided with a pair of integrally formed alignment structures that depend from the lower end surface of the mounting flange and extend radially outwardly from the generally cylindrical body portion of the fuel inlet fitting. In accordance with the subject invention, the alignment structures are adapted and configured to guide the fuel injector into an installed position within the reception bore of the engine case. These alignment structures are positioned to align with corresponding reception notches defined within each reception bore of the engine case. Once engaged, the integrally formed alignment structures serve to maintain the fuel injector in its correctly seated position within the reception bore of the engine case.
The integrally formed alignment structures are diametrically opposed to one another relative to the central axis of the generally cylindrical body portion of the fuel inlet fitting, and they are dissimilar in axial height relative to the generally cylindrical body portion, which includes an upper cylindrical section and a lower inwardly tapered section. The integrally formed alignment structures include a leading alignment structure and a trailing alignment structure. The leading alignment structure has an axial height that is typically but not necessarily greater than the axial height of the trailing alignment structure, relative to the axial height of the generally cylindrical body portion of the fuel inlet fitting.
In one embodiment of the subject invention, the leading alignment structure has an axial height that is substantially equal to the axial height of the entire cylindrical body portion, and the trailing alignment structure has an axial height that is substantially equal to the axial height of the upper cylindrical section of the cylindrical body portion. In another embodiment of the subject invention, the leading alignment structure has an axial height that is substantially equal to the axial height of the upper cylindrical section of the cylindrical body portion, and the trailing alignment structure has an axial height that is less than the axial height of the upper cylindrical section of the cylindrical body portion.
Preferably, the shorter trailing alignment structure has a generally rectangular configuration that includes a convex outer surface. The longer leading alignment structure has a polygonal configuration that includes a truncated convex outer surface. In accordance with the subject invention, the truncation of the convex outer surface defines an inwardly tapered camming facet for interacting with the reception bore of the engine case during installation of the fuel injector, to effectively guide the fuel injector into a properly seated position.
These and other aspects of the fuel injector alignment and positioning system and the fuel injector of the subject invention will become more readily apparent to those having ordinary skill in the art from the following detailed description of the invention taken in conjunction with the drawings.
So that those having ordinary skill in the art to which the present invention pertains will more readily understand how to make and use the fuel injector alignment and positioning system of the present invention, embodiments thereof will be described in detail hereinbelow with reference to the drawings, wherein:
a is an enlarged localized perspective view of a first (trailing) alignment structure integrally formed beneath the mounting flange of the fuel inlet fitting of the fuel injector of
b is an enlarged localized perspective view of a second (leading) alignment structure integrally formed beneath the mounting flange of the fuel inlet fitting of the fuel injector of
a through 7d illustrate the guided installation of the fuel injector of
Referring now to the drawings wherein like reference numerals identify similar features or structures of the subject invention, there is illustrated in
In connection with manufacturing the prior art fuel injector 10, it was necessary for the nozzle manufacturer to procure, inspect and inventory the alignments pins 14 and 16, for subsequent installation within the mounting flange 18 of the inlet fitting 12. This added unnecessarily to the manufacturing cost of the prior art fuel injector 10.
Referring to
Fuel injector 100 includes a one-piece fuel inlet fitting 112, which has an annular mounting flange 118 defining substantially planar upper and lower end surfaces 118a and 118b. Diametrically opposed, integral alignment structures 114 and 116 are formed beneath or otherwise depend from the lower end surface 118b of mounting flange 118. The integral alignment structures 114 and 116 are machined as part of the mounting flange and/or main body section 115 of the fuel inlet fitting 112, using numerically controlled machining technology. The integrally formed alignment structures 114 and 116 extend radially outwardly from the main body section 115 of fuel inlet fitting 112. The main body section 115 of fuel inlet fitting 112 includes an upper cylindrical portion 115a and a lower inwardly tapered portion 115b.
As best seen in
In accordance with the subject invention, alignment structure 116 is the leading alignment structure because it serves to lead or otherwise guide the fuel inlet fitting 112 of fuel injector 100 into an installed position within the reception bore of the engine case. Alignment structure 114 is the trailing alignment structure because it follows the leading alignment structure 116 into position within the reception bore of the engine case, as shown for example, in
Referring to
During the installation of fuel injector 100 in engine case 122, the leading alignment structure 116 is mechanically guided into corresponding reception notch 126. At such a time, the truncated surface or inwardly tapered lower facet 116b of alignment structure 116 acts as a camming surface against the forward edge of reception notch 126. This mechanical interaction between the truncated camming facet 116b of the leading alignment structure 116 and the forward edge of reception notch 126 serves to facilitate the rotational or pivotal movement of the fuel inlet fitting 112 of fuel injector 100 into the installed position shown in
While not shown in the accompanying drawings, the interior surface of reception bore 120 is threaded, and an externally threaded locking nut (also not shown) is used to secure the fuel inlet fitting 112 of injector 100 within bore 120 by applying an axially directed retaining force against the upper end surface 118a of mounting flange 118. In addition, a sealing ring or gasket may be interposed between the locking nut and the fuel inlet fitting to ensure the integrity of the fit.
Referring now to
However, fuel injector 200 differs from fuel injector 100 in that the leading alignment structure 216 is relatively longer than the leading alignment structure 116 of fuel injector 100, as shown in
The configuration of the leading alignment structure 216 is generally more effective during installation, as compared to alignment structure 116. This is because alignment structure 216 cooperatively guides the fuel injector 200 into the reception bore 120 of the engine case 122 for a greater distance, as shown in
During installation, the geometric relationship between the angled feed arm 225 of fuel injector 200 and the interior walls of engine case 120 are such that it is necessary to initially introduce the inlet fitting 212 into the reception bore 122 of engine case 120 at an angle relative to the axis of the reception bore 122, as shown for example in
In accordance with the subject invention, the inwardly tapered facet 216b of the truncated convex outer surface 216a of leading alignment structure 216, which is best seen in
Continued counter-clockwise rotation of the inlet fitting 212 brings the lower end surface 218a of mounting flange 218 into a seated position within reception bore 120, as shown in
It is envisioned and well within the scope of the subject disclosure that additional alignment and positioning features or means can be formed with or otherwise provided on the fuel inlet fitting of the subject invention. Such structural features may be located on or near the mounting flange of the fuel inlet fitting, and may be employed in conjunction with, supplemental to or in addition to the alignment and positioning structures described hereinabove.
Although the fuel injector alignment and positioning system of the subject invention has been described with respect to preferred embodiments, those skilled in the art will readily appreciate that changes and modifications may be made thereto without departing from the spirit and scope of the subject invention as defined by the appended claims.
The subject application claims the benefit of priority from U.S. Provisional Patent Application Ser. No. 60/561,116, which was filed on Apr. 9, 2004, the disclosure of which is herein incorporated by reference in its entirety.
Number | Date | Country | |
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60561116 | Apr 2004 | US |