The present disclosure relates to a flare cone for a mixer assembly of a combustor of a gas turbine engine.
Some conventional gas turbine engines are known to include rich-burn combustors that typically use a swirler integrated with a fuel nozzle to deliver a swirled fuel/air mixture to a combustor. A radial-radial swirler is one example of such a swirler and includes a primary radial swirler, a secondary radial swirler, and a flare cone connected to the secondary swirler. The primary swirler includes a primary swirler venturi in which a primary flow of swirled air from the primary swirler mixes with fuel injected into the primary swirler venturi by the fuel nozzle, thereby generating a swirled primary fuel-air mixture. The secondary swirler provides a secondary flow of swirled air downstream of the primary swirler, where the secondary flow of swirled air mixes with the swirled primary fuel-air mixture, thereby generating a swirled fuel-air mixture. The swirled fuel-air mixture then flows downstream to a flare cone connected to a downstream end of the secondary swirler. The flare cone has a conical inner surface that disperses the swirled secondary fuel-air mixture into the combustion chamber, where it is ignited and burned to generate combustion product gases.
The foregoing and other features and advantages will be apparent from the following, more particular, description of various exemplary embodiments, as illustrated in the accompanying drawings, wherein like reference numbers generally indicate identical, functionally similar, and/or structurally similar elements.
Features, advantages, and embodiments of the present disclosure are set forth or apparent from a consideration of the following detailed description, drawings, and claims. Moreover, it is to be understood that the following detailed description are exemplary and intended to provide further explanation without limiting the scope of the disclosure as claimed.
Various embodiments are discussed in detail below. While specific embodiments are discussed, this is done for illustration purposes only. A person skilled in the relevant art will recognize that other components and configurations may be used without departing from the spirit and scope of the present disclosure.
As used herein, the terms “first”, “second”, and “third” may be used interchangeably to distinguish one component from another and are not intended to signify location or importance of the individual components.
The terms “upstream” and “downstream” refer to the relative direction with respect to fluid flow in a fluid pathway. For example, “upstream” refers to the direction from which the fluid flows, and “downstream” refers to the direction to which the fluid flows.
In a rich-burn combustor that includes a radial-radial swirler, air is provided from a pressure plenum of a combustor to a primary swirler, where a swirl is induced in the air by swirl vanes in the primary swirler as it flows through the primary swirler. The primary swirler also includes a venturi, and a fuel nozzle injects fuel into the venturi, where it is mixed with the swirled air flow of the primary swirler to generate a swirled primary fuel-air mixture. A secondary swirler provides a secondary flow of swirled air downstream of the primary swirler, where the secondary flow of swirled air mixes with the swirled primary fuel-air mixture, thereby generating a swirled fuel-air mixture. The swirled fuel-air mixture then flows downstream of the secondary swirler to a flare cone connected to a downstream end of the secondary swirler.
The flare cone expands the swirled fuel-air mixture along a diverging conical-angled surface prior to entering the combustor, where it is ignited and burned to generate combustion product gases. Conventional flare cones utilize a fixed diverging conical-angled surface and include a sharp edge at an outlet end of the conical-angled surface. In addition, the conventional flare cone includes a backside cooling slot that has a fixed angle that generally matches with the angle of the conical-angled surface. Due to the fixed conical-angled surface and the sharp edge, a defined flow separation occurs from the sharp edge such that, the swirling flow expands at an angle equal to or less than the diverging conical-angled surface of the flare cone. The resulting flow is therefore susceptible to combustion instability, which is promoted by an unsteady interaction of the flame, a corner vortex formed in the flow at the sharp edge, and a cooling flow provided by the dome.
The present disclosure addresses the foregoing to reduce the unsteady interaction of the flame with the cooling flow of the dome by providing an aerodynamic turning of the flow over the flare cone and dome to minimize combustion dynamics. According to the present disclosure, in one aspect, an annular step with a defined width and height is provided on the flare cone outer end instead of the sharp edge. In another aspect, a contoured inner surface of the flare cone is provided so as to allow a steeper angled flow closer to the outlet end of the flare cone. Both the annular step and the contoured surface provide for a smoother transition of the flow of the fuel-air mixture exiting the flare cone at the outer edge, thereby, reducing the unsteady flame motion. In addition, the flare cone shape can influence the flame shape and make the flame more resistant to pressure fluctuations.
Referring now to the drawings,
The core engine 16 may generally include an outer casing 18 that defines an annular inlet 20. The outer casing 18 encases or at least partially forms, in serial flow relationship, a compressor section having a booster or low pressure (LP) compressor 22, a high pressure (HP) compressor 24, a combustion section 26, a turbine section including a high pressure (HP) turbine 28, a low pressure (LP) turbine 30, and a jet exhaust nozzle section 32. A high pressure (HP) rotor shaft 34 drivingly connects the HP turbine 28 to the HP compressor 24. A low pressure (LP) rotor shaft 36 drivingly connects the LP turbine 30 to the LP compressor 22. The LP rotor shaft 36 may also be connected to a fan shaft 38 of the fan assembly 14. In particular embodiments, as shown in
As shown in
The secondary swirler 72 similarly includes secondary swirler swirl vanes 102 that are circumferentially disposed in a row such that each of the secondary swirler swirl vanes 102 extends radially inward. The secondary swirler 72 is configured for swirling another corresponding portion of the pressurized air 82(a) from the pressure plenum 66 radially inward. The swirler assembly 51 further includes a flare cone 90 connected to the secondary swirler 72 downstream of the secondary swirler 72.
The fuel nozzle assembly 52 is seen to include the fuel nozzle 76 disposed within the swirler ferrule plate 74 of the swirler assembly 51. The fuel nozzle 76 injects a fuel 84 into the primary swirler venturi 88, where it is mixed with the air 82(a) from primary swirler 70. The fuel and air mixture in the primary swirler venturi 88 further mixes downstream in a conical opening 122 of the flare cone 90 with the air 82(a) from secondary swirler 72. The fuel and air mixture from the flare cone 90 is dispersed at a diverging angle from the flare cone 90 into the combustion chamber 62, where it is ignited and burned to generate the combustion product gases 86.
A deflector wall 92 extends radially outward from an annular axial wall outer surface 132 of the flare cone 90. The deflector wall is a generally annular wall that extends circumferentially about the mixer assembly centerline 69. The deflector wall 92 is also connected to support wall 94 of the dome assembly 54 at radially outward portions of the deflector wall 92 and the support wall 94. The support wall 94 is also seen to be connected to the annular axial wall outer surface 132 of the flare cone 90. A deflector wall cavity 96 is formed between the support wall 94, the deflector wall 92, and the annular axial wall outer surface 132 of the flare cone 90. The support wall 94 is seen to include a plurality of support wall cooling passages 108 therethrough, while deflector wall 92 is seen to include a plurality of deflector wall cooling passages 106 therethrough. A portion of the air 82(a) from the pressure plenum 66 flows through the support wall cooling passages 108 into the deflector wall cavity 96, and, then, through the deflector wall cooling passages 106 to provide film cooling of a deflector wall aft surface 138 of the deflector wall 92.
The flare cone 90 includes a flare cone cavity 104 formed therein. As will be described in more detail below with regard to
The annular inner axial wall 150 is connected to the annular conical wall 114 at an annular conical wall upstream end 118 of the annular conical wall 114, and extends in the longitudinal direction L upstream from the annular conical wall upstream end 118 of the annular conical wall 114. The annular inner axial wall 150 may extend to the upstream end 126 of the flare cone 90, or, as shown in
In the
The deflector wall 92 is connected to the annular axial wall 124 at a downstream end 130 of the annular axial wall outer surface 132. The deflector wall aft surface 138 of the deflector wall 92 is seen to be radially aligned with the aft surface 160 of the annular axial wall 124. The deflector wall 92, while being shown as a separate element, may instead be formed integral with the flare cone 90.
In this regard, the flare cone aspect of
With the implementation of the backside cooling passage 174, a flare cone flange 178 is defined. The flare cone flange 178 is defined between the continuously curved conical inner surface 143 and the aft surface 182 of the backside cooling passage 174. The flare cone flange 178 includes the sharp edge 166. The flare cone flange 178 also includes an annular step 180 that generally extends in the longitudinal direction and generally corresponds to the annular step 134 (see
The annular conical wall 114 of
While the foregoing description relates generally to a gas turbine engine, it can readily be understood that the gas turbine engine may be implemented in various environments. For example, the engine may be implemented in an aircraft, but may also be implemented in non-aircraft applications, such as power generating stations, marine applications, or oil and gas production applications. Thus, the present disclosure is not limited to use in aircraft.
Further aspects of the present disclosure are provided by the subject matter of the following clauses.
A mixer assembly of a combustor, the mixer assembly defining a mixer assembly centerline therethrough, the mixer assembly including a swirler assembly including a primary swirler and a secondary swirler disposed downstream of the primary swirler; and a flare cone disposed at a downstream end of the secondary swirler, the flare cone comprising: (a) an annular conical wall extending circumferentially about the mixer assembly centerline, the annular conical wall including a conical inner surface defining a conical opening of the annular conical wall, and (b) an annular axial wall extending in a longitudinal direction with respect to the mixer assembly centerline, the annular axial wall disposed at a radially outward portion of the annular conical wall and connected to the annular conical wall, wherein the annular conical wall and the annular axial wall define an annular step circumferentially about the mixer assembly centerline and extending upstream in the longitudinal direction between an aft end of the annular conical wall and an aft surface of the annular axial wall.
The mixer assembly according to any preceding clause, wherein the downstream end of the annular conical wall comprises an annular conical wall aft surface extending radially outward from a downstream end of the conical inner surface of the annular conical wall to the annular step.
The mixer assembly according to any preceding clause, wherein the conical inner surface of the annular conical wall comprises a continuously curved conical inner surface extending from an upstream end of the continuously curved conical inner surface to a downstream end of the continuously curved conical inner surface.
The mixer assembly according to according to any preceding clause, wherein (a) a beginning portion of the continuously curved conical inner surface at the upstream end of the continuously curved conical inner surface is arranged at a first conical wall angle with respect to the mixer assembly centerline, (b) an ending portion of the continuously curved conical inner surface at the downstream end of the continuously curved conical inner surface is arranged at a second conical wall angle with respect to the mixer assembly centerline, and (c) a middle portion of the continuously curved conical inner surface between the beginning portion and the ending portion transitions from the first conical wall angle to the second conical wall angle.
The mixer assembly according to any preceding clause, wherein the first conical wall angle is forty-five degrees and the second conical wall angle is sixty degrees.
The mixer assembly according to any preceding clause, wherein the flare cone further comprises an annular inner axial wall extending upstream in the longitudinal direction from an upstream end of the annular conical wall, wherein an annular cavity is defined between the annular axial wall and the annular inner axial wall.
The mixer assembly according to any preceding clause, wherein the flare cone includes a plurality of slotted cooling passages each having an inlet at the annular cavity and an outlet at a surface of the annular step.
The mixer assembly according to according to any preceding clause, wherein the surface of the annular step and the conical inner surface of the annular conical wall intersect at the downstream end of the annular conical wall and form an acute angle therebetween.
The mixer assembly according to any preceding clause, wherein the conical inner surface of the annular conical wall comprises a continuously curved conical inner surface extending from an upstream end of the continuously curved conical inner surface to a downstream end of the continuously curved conical inner surface.
The mixer assembly according to any preceding clause, wherein (a) a beginning portion of the continuously curved conical inner surface at the upstream end of the continuously curved conical inner surface is arranged at a first conical wall angle with respect to the mixer assembly centerline, (b) an ending portion of the continuously curved conical inner surface at the downstream end of the continuously curved conical inner surface is arranged at a second conical wall angle with respect to the mixer assembly centerline, and (c) a middle portion of the continuously curved conical inner surface between the beginning portion and the ending portion transitions from the first conical wall angle to the second conical wall angle.
The mixer assembly according to any preceding clause, wherein the first conical wall angle is forty-five degrees and the second conical wall angle is sixty degrees.
The mixer assembly according to any preceding clause, further comprising a deflector wall connected to the annular axial wall at a downstream end of the annular axial wall, and extending radially outward from an outer surface of the annular axial wall, wherein the deflector wall is formed integral with the flare cone.
The mixer assembly according to any preceding clause, wherein the deflector wall includes a plurality of cooling passages therethrough.
The mixer assembly according to any preceding clause, wherein the annular conical wall further comprises a backside cooling passage, wherein a flare cone flange is defined between the backside cooling passage and the conical inner surface of the annular conical wall, wherein the conical inner surface of the annular conical wall comprises a continuously curved conical inner surface extending from an upstream end of the continuously curved conical inner surface to a downstream end of the continuously curved conical inner surface, and wherein (a) a beginning portion of the continuously curved conical inner surface at the upstream end of the continuously curved conical inner surface is arranged at a first conical wall angle with respect to the mixer assembly centerline, (b) an ending portion of the continuously curved conical inner surface at the downstream end of the continuously curved conical inner surface is arranged at a second conical wall angle with respect to the mixer assembly centerline, and (c) a middle portion of the continuously curved conical inner surface between the beginning portion and the ending portion transitions from the first conical wall angle to the second conical wall angle.
The mixer assembly according to any preceding clause, wherein the first conical wall angle is forty-five degrees and the second conical wall angle is sixty degrees.
The mixer assembly according to any preceding clause, wherein the backside cooling passage includes a backside cooling passage aft surface that is a continuously curved surface that is congruent with the continuously curved conical inner surface.
A flare cone for a mixer assembly, the flare cone defining a flare cone centerline therethrough, the flare cone comprising: an annular conical wall extending circumferentially about the flare cone centerline, the annular conical wall including a conical inner surface defining a conical opening of the annular conical wall; and an annular axial wall extending in a longitudinal direction with respect to the flare cone centerline, the annular axial wall disposed at a radially outward portion of the annular conical wall and connected to the annular conical wall, wherein the annular conical wall and the annular axial wall define an annular step circumferentially about the flare cone centerline and extending upstream in the longitudinal direction between a downstream end of the annular conical wall and an aft surface of the annular axial wall.
The flare cone according to any preceding clause, wherein the downstream end of the annular conical wall comprises an annular conical wall aft surface extending radially outward from a downstream end of the conical inner surface of the annular conical wall to the annular step.
The flare cone according to any preceding clause, wherein the conical inner surface of the annular conical wall comprises a continuously curved conical inner surface extending from an upstream end of the continuously curved conical inner surface to a downstream end of the continuously curved conical inner surface.
The flare cone according to any preceding clause, wherein (a) a beginning portion of the continuously curved conical inner surface at the upstream end of the continuously curved conical inner surface is arranged at a first conical wall angle with respect to the flare cone centerline, (b) an ending portion of the continuously curved conical inner surface at the downstream end of the continuously curved conical inner surface is arranged at a second conical wall angle with respect to the flare cone centerline, and (c) a middle portion of the continuously curved conical inner surface between the beginning portion and the ending portion transitions from the first conical wall angle to the second conical wall angle.
The flare cone according to any preceding clause, wherein the first conical wall angle is forty-five degrees and the second conical wall angle is sixty degrees.
The flare cone according to any preceding clause, wherein the flare cone further comprises an annular inner axial wall extending in the longitudinal direction upstream from an upstream end of the annular conical wall, wherein an annular cavity is defined between the annular axial wall and the annular inner axial wall.
The flare cone according to any preceding clause, wherein the flare cone includes a plurality of slotted cooling passages each having an inlet at the annular cavity and an outlet at a surface of the annular step.
The flare cone according to any preceding clause, wherein the surface of the annular step and the conical inner surface of the annular conical wall intersect at the downstream end of the annular conical wall and form an acute angle therebetween.
The flare cone according to any preceding clause, wherein the conical inner surface of the annular conical wall comprises a continuously curved conical inner surface extending from an upstream end of the conical inner surface to a downstream end of the conical inner surface.
The flare cone according to any preceding clause, wherein (a) a beginning portion of the continuously curved conical inner surface at the upstream end of the continuously curved conical inner surface is arranged at a first conical wall angle with respect to the flare cone centerline, (b) an ending portion of the continuously curved conical inner surface at the downstream end of the continuously curved conical inner surface is arranged at a second conical wall angle with respect to the flare cone centerline, and (c) a middle portion of the continuously curved conical inner surface between the beginning portion and the ending portion transitions from the first conical wall angle to the second conical wall angle.
The flare cone according to any preceding clause, wherein the first conical wall angle is forty-five degrees and the second conical wall angle is sixty degrees.
The flare cone according to any preceding clause, further comprising a deflector wall connected to the annular axial wall at a downstream end of the annular axial wall, and extending radially outward from an outer surface of the annular axial wall, wherein the deflector wall is formed integral with the flare cone.
The flare cone according to any preceding clause, wherein the deflector wall includes a plurality of cooling passages therethrough.
The flare cone according to any preceding clause, wherein the annular conical wall further comprises a backside cooling passage, wherein a flare cone flange is defined between the backside cooling passage and the conical inner surface of the annular conical wall, wherein the conical inner surface of the annular conical wall comprises a continuously curved conical inner surface extending from an upstream end of the continuously curved conical inner surface to a downstream end of the continuously curved conical inner surface, and wherein (a) a beginning portion of the continuously curved conical inner surface at the upstream end of the continuously curved conical inner surface is arranged at a first conical wall angle with respect to the flare cone centerline, (b) an ending portion of the continuously curved conical inner surface at the downstream end of the continuously curved conical inner surface is arranged at a second conical wall angle with respect to the flare cone centerline, and (c) a middle portion of the continuously curved conical inner surface between the beginning portion and the ending portion transitions from the first conical wall angle to the second conical wall angle.
The flare cone according to any preceding clause, wherein the first conical wall angle is forty-five degrees and the second conical wall angle is sixty degrees.
The flare cone according to any preceding clause, wherein the backside cooling passage includes a backside cooling passage aft surface that is a continuously curved surface that is congruent with the continuously curved conical inner surface.
Although the foregoing description is directed to some exemplary embodiments of the present disclosure, other variations and modifications will be apparent to those skilled in the art, and may be made without departing from the spirit or scope of the disclosure. Moreover, features described in connection with one embodiment of the present disclosure may be used in conjunction with other embodiments, even if not explicitly stated above.
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Number | Date | Country | |
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20230296245 A1 | Sep 2023 | US |