Patent Grant
8240151
The present invention relates generally to injectors and nozzles for high temperature applications, and more particularly to fuel injectors and nozzles for gas turbine engines of aircraft.
Fuel injectors for gas turbine engines on an aircraft direct fuel from a manifold to a combustion chamber of a combustor. The fuel injector typically has an inlet fitting connected to the manifold for receiving the fuel, a fuel nozzle located within the combustor for spraying fuel into the combustion chamber, and a housing stem extending between and fluidly interconnecting the inlet fitting and the fuel nozzle. The housing stem typically has a mounting flange for attachment to the casing of the combustor.
Fuel injectors are usually heat-shielded because of a high operating temperatures arising from high temperature gas turbine compressor discharge air flowing around the housing stem and nozzle. The heat shielding prevents the fuel passing through the injector from breaking down into its constituent components (i.e., “coking”), which may occur when the wetted wall temperatures of a fuel passage exceed 400° F. The coke in the fuel passages of the fuel injector can build up to restrict fuel flow to the nozzle.
Heretofore, injector nozzles have included annular stagnant air gaps as insulation between external walls, such as those in thermal contact with high temperature ambient conditions, and internal walls in thermal contact with the fuel. In order to accommodate differential expansion of the internal and external walls while minimizing thermally induced stresses, the walls heretofore have been anchored at one end and free at the other end for relative movement. If the downstream tip ends of the walls are the ends left free for relative movement, even a close fitting sliding interface between the downstream tip ends can allow fuel to pass into the air gap formed between the walls. This can result in carbon being formed in the air gap, which carbon is not as good an insulator as air. In addition, the carbon may build up to a point where it blocks venting of the air gap to the air gap in the stem, which can lead to an accumulation of fuel in the air gap. This can lead to diminished nozzle service life.
The present invention provides, inter alia, a novel and unique fuel injector for a gas turbine engine of an aircraft, and more particularly a novel and unique heatshield structure for a fuel nozzle. In accordance with the invention, a bellows is uniquely assembled in the nozzle to isolate a portion of an insulating gap from an interface whereat fuel may enter the insulating gap. Although the invention is particularly applicable to fuel injectors and nozzles for gas turbine engines, principles of the invention also are more generally applicable to other applications, particularly high temperature applications where insulating gaps are provided in the nozzle and into which an ambient fluid may enter through an interface between relatively moving parts of the nozzle.
Accordingly, a nozzle comprises an inlet at an upstream end of the nozzle, a discharge outlet at a downstream end of the nozzle, and a fluid delivery passage extending between the inlet and the discharge outlet. An internal annular wall bounds one side of the fluid delivery passage along a length thereof, whereby such wall is in heat transfer relation with fluid passing through the fluid delivery passage. An exterior annular wall is interposed between the internal annular wall and ambient conditions surrounding the nozzle, and the exterior and interior walls have downstream tip ends that are relatively longitudinally movable at an interface, as may arise from relative thermal growth during use of the nozzle under high temperature conditions. Additionally, an internal insulating gap is interposed between the interior and exterior walls to insulate the internal wall from ambient temperature conditions exterior to the nozzle, and an annular bellows internal to the injector has an upstream end sealingly attached to an upstream portion of one of the internal and external walls, and a downstream end sealingly attached to a downstream portion of the other wall to fluidly separate a thereby isolated portion of the insulating gap from any ambient fluid entering into the insulating gap through the interface.
The nozzle may be further characterized by one or more of the following features:
a. the gap may be divided into radially inner and outer portions along a length of the bellows extending between its upstream and downstream ends;
b. the ends of the bellows may be sealingly attached to the internal and external walls by brazing;
c. the fluid delivery passage may include at least one vane configured to impart swirling to the fluid flowing to the discharge outlet;
d. the annular bellows may have circumferential convolutions;
e. the insulating gap may surround the internal wall and the external wall may surround the insulating gap;
f. the internal wall may surround the insulating gap, and the insulating gap may surround a central duct extending axially through the nozzle;
g. the central duct may include swirl vanes for imparting a rotary motion to an ambient fluid flowing through the central duct;
h. the insulating gap may contain air, another gas or an insulating material, or may be evacuated; and/or
i. the insulating gap may extend substantially the entire length of the fluid delivery passage.
According to another aspect of the invention, a fuel injector for a gas turbine engine comprises a nozzle as above described for spraying fuel into a combustion chamber, and a housing stem for supporting the nozzle in the combustion chamber. The housing stem includes an internal fuel conduit for supplying fuel to the fluid inlet of the nozzle.
The fuel injector may be further characterized by one or more of the following features:
a. the housing stem may include an external wall surrounding the fuel conduit, and an insulating gap between the external wall and fuel conduit, which insulating gap is in fluid communication with the insulating gap of the nozzle;
b. the insulating gap may contain air, another gas or an insulating material, or may be evacuated;
c. the housing stem may extend from a fuel line fitting to the nozzle for connecting the nozzle to the fitting;
d. the housing stem and nozzle may be rigidly and fixedly connected together as a single component that can be inserted into and located within an opening in a combustor casing; and/or
e. the housing stem may include a flange extending outwardly away from the stem, the flange having an attachment device to allow the stem to be attached to the gas turbine engine.
According to a further aspect of the invention, a fuel injector for a gas turbine engine comprises a housing stem and a nozzle, the nozzle including an internal wall in heat transfer relation with fuel flowing through the nozzle, and an external wall in heat transfer relation with ambient air. The internal and external walls have downstream tip ends that are relatively moveable at an interface due to relative thermal growth during operation of the engine. An internal insulating gap is disposed between the internal and external walls to provide a heat shield for the internal wall, and a bellows internal to the injector has an upstream end sealingly attached to an upstream portion of one of the internal and external walls, and a downstream end sealingly attached to a downstream portion of the other wall to fluidly separate the insulating gap from any fuel entering into the nozzle through the interface.
Other features and advantages of the present invention will become further apparent upon reviewing the following detailed description and attached drawings.
In the annexed drawings:
As above indicated, the principles of the present invention have particular application to fuel injectors and nozzles for gas turbine engines and thus will be described below chiefly in this context. It will of course be appreciated, and also understood, that the principles of the invention may be useful in other applications including, in particular, other fuel nozzle applications and more generally applications where a fluid is injected by a nozzle especially under high temperature conditions.
Referring now in detail to the drawings and initially to
A fuel injector, indicated generally at 30, is received within an aperture 32 formed in the engine casing 12 and extends inwardly through an aperture 34 in the combustor liner 22. The fuel injector 30 includes a fitting 36 exterior of the engine casing for receiving fuel, as by connection to a fuel manifold or line; a fuel nozzle, indicated generally at 40, disposed within the combustor for dispensing fuel; and a housing stem 42 interconnecting and structurally supporting the nozzle 40 with respect to fitting 36. The fuel injector is suitably secured to the engine casing, as by means of an annular flange 41 that may be formed in one piece with the housing stem 42 proximate the fitting 36. The flange extends radially outward from the housing stem and includes appropriate means, such as apertures, to allow the flange to be easily and securely connected to, and disconnected from, the casing of the engine using, as by bolts or rivets.
As best seen in
The housing stem 42 may be formed integrally with fuel nozzle 40, and preferably in one piece with at least a portion of the nozzle. The lower end of the housing stem includes an annular outer shroud 94 circumscribing the longitudinal axis “A” of the nozzle 40. The outer shroud 94 is connected at its downstream end to an annular outer air swirler 96, such as by welding at 98. The outer air swirler 96 includes an annular wall 97 forming a continuation of the shroud 94 and from which swirler vanes 99 may project radially outwardly to an annular shroud 100. The shroud 100 is tapered inwardly at its downstream end 101 to direct air in a swirling manner toward the central axis “A” at the discharge end 102 of the nozzle.
A second outer air swirler 103 may also be provided, in surrounding relation to the first air swirler 96. The second air swirler 103 also includes radially-outward projecting swirler vanes 104 and an annular shroud 105. The shroud 105 has a geometry at its downstream end 106 that also directs air in a swirling manner toward the central axis “A” at the discharge end 102 of the nozzle.
An annular prefilmer 110 and an annular fuel swirler 111 are disposed radially inwardly from the annular wall formed by the outer shroud 94 and air swirler 96. The prefilmer 110 closely surrounds the fuel swirler 111, and together the prefilmer and fuel swirler form internal walls of the nozzle that define therebetween a fuel passage 112, to direct fuel through the nozzle. The fuel swirler may be provided with vanes 118 that direct the fuel in a swirling manner as it flows past the vanes. The prefilmer 110 may have a fuel inlet opening 113 at its upstream end, that receives the downstream end of fuel conduit 58. The fuel conduit 58 may be fluidly sealed and rigidly and permanently attached within the opening in an appropriate manner, such as by welding or brazing. The prefilmer 110 may also be tapered inwardly at its downstream end 114 to direct fuel in a swirling manner toward the central axis “A” at the discharge end 102 of the nozzle. An air swirler 120 with radially-extending swirler blades 122 may also be provided in the air passage 117 bounded by the radially inner surface of the fuel swirler 111 as seen in
As best seen in
In use, the shroud wall 119 will be in thermal contact with ambient conditions external to the nozzle, such being high temperature gas turbine compressor discharge air that passes around the nozzle. Consequently, the shroud wall will usually expand longitudinally (along the axis A) more than the prefilmer that is in thermal contact with the fuel. To avoid high stresses from being induced in the nozzle, the external shroud wall 119 and prefilmer 110 may have the upstream ends thereof anchored, i.e. fixed, with respect to one another, while the downstream tip ends thereof may be free to move relative to one another in the longitudinal direction, i.e. along the axis A of the nozzle.
To minimize the passage of fuel into the insulating gap 115, the tip ends of the shroud wall 119 and prefilmer 110 may be provided with a close fitting sliding interface indicated at 130. Notwithstanding the close fit, fuel may still pass into the insulating gap formed between the walls. This can result in carbon being formed in the insulating gap, which carbon is not as good an insulator as air. In addition, the carbon may build up to a point where it blocks venting of the insulation gap 115 to the insulation gap 63 in the stem, which can lead to an accumulation of fuel in the insulation gap. This may possibly lead to diminished nozzle service life.
In accordance with the present invention, an annular bellows 140 internal to the injector is provided in the insulating gap 115 to fluidly separate a thereby isolated portion 115a of the insulating gap 115 from any fuel that may enter into a non-isolated portion 115b of the gap 115 through the interface 130. The bellows 140 has an upstream end 144 sealingly attached to an upstream portion of one of the shroud wall 119 and prefilmer 110, and a downstream end 142 sealingly attached to a downstream portion of the other, thereby fluidly separating the then isolated portion 115a of the insulating gap from any fuel entering into the gap through the interface 130. In the embodiment illustrated in
If desired, the connections may be made in the opposite manner as illustrated
Referring now to
In use, the inner heat shield 156 will be in thermal contact with ambient conditions external to the nozzle, such being high temperature high temperature gas turbine compressor discharge air that passes through the nozzle. Consequently, the inner heat shield will usually expand longitudinally (along the axis A) more than the fuel swirler 111 that is in thermal contact with the fuel. To avoid high stresses from being induced in the nozzle, the inner heat shield and fuel swirler may have the upstream ends thereof anchored, i.e. fixed, with respect to one another, while the downstream tip ends thereof may be free to move relative to one another in the longitudinal direction, i.e. along the axis A of the nozzle.
To minimize the passage of fuel into the insulating gaps, the tip ends of the tip ends of the fuel swirler 111 and inner heat shield 156 may be provided with a close fitting sliding interface indicated at 164. Notwithstanding the close fit, fuel may still pass into the insulating gap 158 formed between the walls. This can result in carbon being formed in the insulating gap, which carbon is not as good an insulator as air. In addition, the carbon may build up to a point where it blocks venting of the insulation gap 156 to the insulation gap 63 in the stem, if provided, and this can lead to an accumulation of fuel in the insulation gap. This may possibly lead to diminished nozzle service life.
In a manner similar to the bellows 140, an annular bellows 168 internal to the injector may be provided in the insulating gap 158 to fluidly separate a thereby isolated portion 158a of the insulating gap from any fuel that may enter into a non-isolated portion 158b of the gap 124 through the interface 164. The bellows may have an upstream end 170 sealingly attached to an upstream portion of one of the inner heat shield 156, and a downstream end 172 sealingly attached to a downstream or tip portion of the fuel swirler, thereby fluidly separating the then isolated portion 158a of the insulating gap from the non-isolated portion 158b. More particularly, the downstream end of the bellows may be sealingly attached by suitable means, such as brazing, to a downstream or tip end of the fuel swirler, and the upstream end of the bellows may be sealingly attached by suitable means to the inner heat shield.
If desired, the connections may be made in the opposite manner as illustrated
In any of the various embodiments of a fuel nozzle according to the invention, the insulating gap 115, 158 may be divided into radially inner and outer portions along a length of the bellows 140, 168. The annular bellows may have circumferential convolutions as shown, and the peaks of the convolutions may be spaced from the relatively adjacent internal and external walls of the nozzle to minimize conduction of heat radially through the bellows.
In any of the various embodiments of a fuel nozzle according to the invention, the insulating gap may contain stagnant air, or another gas, or even an insulating material, or the gap may be evacuated.
The nozzle described above may be formed from an appropriate heat-resistant and corrosion resistant material, such as those known to those skilled in the art. The nozzle may be formed and assembled using conventional manufacturing techniques.
Any suitable means may be used to manufacture and assemble the nozzle. By way of example and in relation to the nozzle embodiment shown in
The skilled person will also appreciate that a nozzle may be provided with both a radially outer insulating gap 115 and a radially inner insulating gap 158, and either one or both may be provided with a bellows as shown in the several figures.
The skilled person will also appreciate that the bellows in the several embodiments may be sealingly attached to the walls of the nozzle by any suitable means, such as the above-described brazing, or even welding or by use of a high temperature adhesive. Other exemplary sealed attachment mechanisms include a metal-to-metal contact seal. For instance, the bellows ends may have a press-fit connection that will continue to effect a seal over the operating temperature range of the nozzle. It is noted that the bellows can be more resilient than the walls to which it is attached and thus accommodate differential radial expansion, as well as differential longitudinal expansion, to a greater extent. Moreover, the use of sealingly attached is not intended to necessarily mean a fixed or rigid non-moving connection. It is possible that a sealed connection can be effected between the bellows and adjacent wall while still allowing for relative movement, in particular relative longitudinal movement. If a telescopic union is provided and effectively sealed, the bellows itself need not necessarily be longitudinally expandable and contractible to accommodate the relative expansion of the walls to which its opposite ends are attached.
While several embodiments of a nozzle have been described above, it should be apparent to those skilled in the art that other nozzle (and stem) designs can be configured in accordance with the present invention. The invention is not limited to any particular nozzle design, but rather is appropriate for a wide variety of commercially-available nozzles, including nozzles for other applications where the nozzle is subjected to ambient high temperature conditions.
The principles, preferred embodiments and modes of operation of the present invention have been described in the foregoing specification. The invention which is intended to be protected herein should not, however, be construed as limited to the particular form described as it is to be regarded as illustrative rather than restrictive. Variations and changes may be made by those skilled in the art without departing from the scope and spirit of the invention.
This application claims the benefit of the filing date of U.S. Provisional Application No. 60/761,023 filed Jan. 20, 2006, which is hereby incorporated herein by reference.
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| Number | Date | Country | |
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| Number | Date | Country | |
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| 60761023 | Jan 2006 | US |
