The present invention relates generally to fuel nozzles, and more particularly to fuel nozzle tips suitable for use in a gas turbine engine combustor.
Gas turbine engines include a combustor for generating combustion products to help power the engine. Typically, compressed air is provided to the combustor and is mixed with fuel injected into a combustion chamber. The fuel/air mixture is ignited to provide combustion. The combustion products then exit the combustor and pass through a turbine section that extracts rotational energy from the combustion products.
Fuel nozzles deliver fuel in particular patterns to help facilitate combustion. Parameters such as swirl, velocity, and pressure are tightly controlled by the fuel nozzle to help promote desired performance. During operation, fuel nozzles that inject fuel in the combustor are subjected to extreme thermal conditions as well as various other forces. Balancing these concerns in a working fuel nozzle can be difficult.
It is therefore desired to provide an alternative fuel nozzle tip.
A fuel injector nozzle assembly includes a body extending along an axis and a core swirl plug positioned at least partially within the body. The core swirl plug has a flow modifying structure configured to swirl fuel at a location upstream from a distal end of the nozzle assembly.
While the above-identified figures set forth embodiments of the present disclosure, other embodiments are also contemplated, as noted in the discussion. In all cases, this disclosure presents the invention by way of representation and not limitation. It should be understood that numerous other modifications and embodiments can be devised by those skilled in the art, which fall within the scope and spirit of the principles of the invention. The figures may not be drawn to scale, and applications and embodiments of the present invention may include features and components not specifically shown in the drawings.
In one embodiment, duplex, simplex or other types of fuel nozzles can be interspersed at different locations around the combustor section 20, as desired. Duplex fuel nozzles provide two fuel delivery paths to the combustion chamber 22 while simplex fuel nozzles provide one fuel delivery path to the combustion chamber 22. It is possible to provide fuel nozzles with nearly any number of desired fuel delivery paths, such as having three or more paths. Separate fuel delivery paths can allow separate and independent control of fuel flow through each path, and/or other benefits. For example, one fuel path can be used to provide a pilot while one or more additional fuel paths selectively provide fuel for other operating modes. Alternatively, all of the nozzles 40 in the combustor section 20 can be of the same configuration (e.g., simplex, duplex, etc.).
During operation, hot air flow is present at or near the swirlers 32 and at least portions of the nozzles 40 (e.g., the support 46 and/or nozzle tip 48). The nozzles 40 can use fuel passing through the nozzle tips 48 as a heat sink to help cool the nozzles 40, as explained further below.
It should be noted that the embodiment of the combustor section 20 shown in
The heat shield 60 may be positioned at least partially about or surrounding the body 64; and, the outer sleeve 62 may be positioned at least partially about or surrounding the heat shield 60. The body 64 may have a generally cylindrical shape forming an interior cavity. The core swirl plug 68 may be positioned at least partially within the body 64. The inner body 70 can also be positioned at least partially within the body 64. In the illustrated embodiment, the inner body 70 is positioned downstream of and directly adjacent to the core swirl plug 68. The swirl plug 72 can be positioned at least partially within the inner body 70. The heat shield sleeve 66 can be positioned in between the core swirl plug 68 and the body 64, such that the core swirl plug 68 is spaced from the body 64 and does not physically contact the body 64. The heat shield sleeve 66 can be made as a physically separate element from the body 64 (i.e., not monolithic and unitary). In the illustrated embodiment, the heat shield sleeve 66 is axially shorter than the core swirl plug 68, and has an upstream end that is generally axially aligned with an upstream end of the body 64.
The fuel flow path 74-1 (or secondary fuel path) can pass through a generally annular passage formed between the concentric tubes 46-1 and 46-2, and can continue along a periphery of the core swirl plug 68. The fuel flow path 74-1 can have a generally annular shape. Furthermore, the fuel flow path 74-1 can be arranged concentrically with the fuel flow path 74-2, at least in a location where those paths 74-1 and 74-2 enter the nozzle tip 48D. As shown in the illustrated embodiment, the core swirl plug 68 has a generally cylindrical shape and includes at least one rib 68-1 along an outer surface. The rib 68-1 can be arranged in a helical shape that wraps around the axis A, such that at least a portion of the fuel flow path 74-1 can follow a helical groove present between turns of the rib 68-1. In the illustrated embodiment, the rib 68-1 has a frustum or substantially triangular cross-sectional shape, with a relatively narrow radially inward base that adjoins a generally cylindrical body portion of the core swirl plug 68 and with a relatively wide radially outward surface opposite the radially inward base. The rib 68-1 can be formed integrally and monolithically with a remainder of the core swirl plug 68 in one embodiment. The relatively wide radially outward surface of the rib 68-1 can help provide desired contact with the heat shield sleeve 66.
The rib 68-1 of the core swirl plug 68 may cause a swirling movement of the fuel passing along the path 74-1, thereby increasing a velocity of the fuel. The rib 68-1 may extend radially across the entire pathway of the fuel flow path 74-1, for at least a portion of the flow path 74-1, to flow the passing fuel in a swirling direction before reaching the downstream or distal end of the nozzle tip 48D where it exits the nozzle 40 for combustion. In this respect, the core swirl plug 68, including the rib 68-1, can act as a flow-modifying member to alter flow of the fuel through the nozzle tip 48D. The core swirl plug 68 can be located well upstream from the downstream end of the nozzle tip 48D, such that the velocity of the fuel is modified proximate to the support 46 and prior to reaching the passages 64-1 in the body 64. The relatively high fuel velocity produced by the core swirl plug 68 helps scrub thermal energy from the fuel nozzle tip 48D, because the fuel acts like a heat sink. It should be noted that fuel swirling produced by the core swirl plug 68 may be entirely separate and independent from air swirling produced by the swirler 32 that may be spaced from the fuel nozzle tip 48D.
The fuel flow path 74-2 (or primary fuel path) can pass through an interior passage of the tube 46-2, and then through a passage (or bore) 68-2 defined by the core swirl plug 68 and another passage (or bore) 68-3 defined by the core swirl plug 68. The passage 68-3 can be defined at an interior or radially central portion of the core swirl plug 68 and the passage 68-2 can be arranged at or near a proximal or upstream end of the core swirl plug 68, with the passages 68-2 and 68-3 arranged to turn a direction of fuel flow in a desired manner. In the illustrated embodiment, the fuel flow path 74-2 is positioned radially inward of the fuel flow path 74-1 along the nozzle tip 48D. The fuel flow path 74-2 may have a generally cylindrical shape, in contrast to the generally annular shape of the flow path 74-1. The core swirl plug 68 can therefore provide swirling flow along its exterior, adjacent to the rib 68-1, and generally non-swirling flow along the internal passage 68-3. The passage 68-3 can be arranged parallel to and concentric with the axis A. The fuel flow path 74-2 can continue from the passage 68-3 to the inner body 70, where fuel can pass along grooves 72-1 defined in an outer portion of the swirl plug 72 and through the opening 70-1 defined by the inner body 70. The swirl plug 72 can impart swirl and tangential momentum to fuel passing to a conical weir defined as part of the opening 70-1 of the inner body 70. Due to conservation of momentum, a reduction of radius across the conical weir (opening 70-1) of the inner body 70 increases swirl velocity, such that fuel can leave exit orifice formed by the opening 70-1 as a thin sheet of fuel that then breaks into ligaments.
The heat shield sleeve 66 helps protect at least a portion of the fuel flow path 74-1 from relatively high heat conditions and hot surfaces, in order to help keep fuel passing along the path 74-1 below a fuel coking limit. Functionally, the heat shield sleeve 66 works to reduce or limit a surface temperature of components (e.g., core swirl plug 68) that come in contact with the fuel in order to help reduce or prevent fuel coking. Fuel coking is undesirable, and can result in the formation of solid carbonaceous materials that may deposit on surfaces and obstruct fuel flow, and may potentially obstruct the passages 64-1 and/or openings 60-1. It has presently been discovered that thermal energy present in the body 46-3 of the support 46 may travel through the body 64, because the body 46-3 abuts the body 64. Thermal contact resistance between surfaces of the body 64 and the heat shield sleeve 66 helps reduce conductive transfer of thermal energy to the fuel, such as to reduce thermal energy transfer from the body 46-3 of the support 46 through the body 64 to the fuel.
Generally radially angled openings 60-1 and a generally axially oriented opening 60-2 can be provided in the heat shield 60 to allow fuel to exit the nozzle tip 48D. Likewise, generally radially angled passages 64-1 can be provided in the body 64, and a generally axial opening 70-1 can be provided in the inner body 70. The radially angled passages 64-1 can be aligned with the radially angled openings 60-1, and the axial passage 70-1 can be aligned with the axial opening 60-2. However, it should be understood that operating conditions, including thermal gradients, can affect alignment of passages and openings. The radially angled openings 60-1 and the radially angled passages 64-1 can be oriented at any desired angle, but are generally oriented more radially than the opening 60-2 and the passage 70-1 that may be oriented along the central axis A of the nozzle tip 48D (which may or may not be parallel with the engine centerline axis CL). In one embodiment, the radially angled openings 60-1 and the radially angled passages 64-1 are each oriented at approximately 50° relative to the axis A, and the opening 60-2 and the passage 70-1 are each oriented parallel to and concentric with the axis A. Radial orientation of the openings 60-1 and the passages 64-1 allow for generally radial fuel jets to be formed by fuel passing through the fuel path 74-1, which provides a particular fuel injection pattern.
It has been discovered that the radial fuel jets formed by the fuel passing through the fuel path 74-1 affect the thermal characteristics of the nozzle tip 48D. For instance, in order to produce radial fuel jets, the fuel must pass along the path 74-1 relative close to the axis A before turning radially outward, which affects the ability of the fuel to act as a heat sink for thermal energy absorbed by the upstream portions of the nozzle tip 48D near the support 46. Increased velocity of the fuel and the swirling effect produced by the core swirl plug 68 help to reduce a risk of fuel coking due to fuel contact with relatively hot surfaced while still allowing the use of radial fuel jets.
In one embodiment, the fuel path 74-2 may provide constant fuel supply for a pilot, while the fuel path 74-1 can provide controllable fuel flows that vary as desired (e.g., as a function of throttle control). In alternate embodiments, other configurations and fuel control schemes can be used.
The simplex and duplex nozzles 40S and 40D can be modular in the sense that most components can be common between the different configurations, with certain components omitted or simplified in the simplex embodiment, as discussed above. Modular construction helps simplify and streamline manufacturing and assembly and reduces a total number of unique parts.
Discussion of Possible Embodiments
The following are non-exclusive descriptions of possible embodiments of the present invention.
A fuel injector nozzle assembly can include a body extending along an axis; and a core swirl plug positioned at least partially within the body, the core swirl plug having a flow modifying structure configured to swirl fuel at a location upstream from a distal end of the nozzle assembly.
The assembly of the preceding paragraph can optionally include, additionally and/or alternatively, any one or more of the following features, configurations and/or additional components:
the flow modifying structure can comprise a helical rib extending radially outward;
the helical rib can have a substantially frustum cross-sectional shape;
a heat shield sleeve positioned between the body and the core swirl plug;
the core swirl plug and the body can be spaced from each other;
a passage in the core swirl plug, wherein a fuel flow path passes along an outer surface of the core swirl plug and another fuel flow path passes through the core swirl plug along the passage;
a fuel outlet passage that extends through the body at an angle relative to the axis to permit fuel injection in a generally radial direction; and/or
the passage can be arranged concentrically with the axis.
A combustor assembly for a gas turbine engine combustor can include a combustion chamber; a first fuel injector nozzle configured to inject fuel into the combustion chamber, the fuel injector nozzle including: a body extending along an axis; a core swirl plug positioned at least partially within the body, the core swirl plug having a flow modifying structure.
The assembly of the preceding paragraph can optionally include, additionally and/or alternatively, any one or more of the following features, configurations and/or additional components:
the flow modifying structure can comprise a helical rib extending radially outward;
the helical rib can have a substantially frustum cross-sectional shape;
the core swirl plug and the body can be spaced from each other;
a passage in the core swirl plug, wherein a fuel flow path passes along an outer surface of the core swirl plug and another fuel flow path passes through the core swirl plug along the passage;
the first fuel injector nozzle can have a simplex configuration, the assembly further including a second fuel injector nozzle configured to inject fuel into the combustion chamber, the fuel injector nozzle having a duplex configuration and including: a body extending along an axis; and a core swirl plug positioned at least partially within the body, the core swirl plug having a flow modifying structure and a passage, wherein a fuel flow path passes along an outer surface of the core swirl plug adjacent to the flow modifying structure and another fuel flow path passes through the core swirl plug along the passage;
the second fuel injector nozzle can further include a heat shield sleeve positioned between the body and the core swirl plug;
the passage can be arranged concentrically with the axis;
the flow modifying structure can be configured to swirl fuel at a location upstream from the distal end of the nozzle assembly; and/or
a support having a support body and a tube configured to carry fuel, wherein the support body abuts the body; and a heat shield sleeve positioned between the body and the core swirl plug of the first fuel injector nozzle.
A method for injecting fuel into a gas turbine engine combustor can include moving fuel along an at least partially annular fuel path; ejecting fuel from the at least partially annular fuel path, wherein the fuel is ejected at a downstream end of a nozzle tip; and swirling the fuel moving along the at least partially annular fuel path upstream from the downstream end of the nozzle tip.
The method of the preceding paragraph can optionally include, additionally and/or alternatively, any one or more of the following features and/or additional steps:
reducing thermal energy transfer to the fuel in the nozzle tip at a location adjacent to a support that adjoins the nozzle tip;
moving fuel along another fuel path radially inward from the at least partially annual fuel path;
wherein the fuel is swirled while in contact with relatively hot surfaces to reduce fuel coking; and/or
ejecting fuel moving along the radially inward fuel path from the downstream end of the nozzle tip along the axis.
Any relative terms or terms of degree used herein, such as “substantially”, “essentially”, “generally” and the like, should be interpreted in accordance with and subject to any applicable definitions or limits expressly stated herein. In all instances, any relative terms or terms of degree used herein should be interpreted to broadly encompass any relevant disclosed embodiments as well as such ranges or variations as would be understood by a person of ordinary skill in the art in view of the entirety of the present disclosure, such as to encompass ordinary manufacturing tolerance variations, incidental alignment variations, alignment or shape variations induced by thermal or vibrational operational conditions, and the like.
While the disclosure is described with reference to an exemplary embodiment(s), it will be understood by those skilled in the art that various changes may be made and equivalents may be substituted for elements thereof without departing from the scope of the disclosure. In addition, many modifications may be made to adapt a particular situation or material to the teachings of the invention without departing from the essential scope thereof. Therefore, it is intended that the invention not be limited to the particular embodiment(s) disclosed, but that the invention will include all embodiments falling within the scope of the appended claims. For example, components illustrated or described as being separate structures can be integrally and monolithically formed in further embodiments, such as using direct metal laser sintering (DMLS) processes.
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