Embodiments of the disclosure relate generally to a gas turbine engine combustor, and more particularly to a combustor having a trapped vortex combustion zone and at least one secondary combustion zone.
In a conventional gas turbine engine, compressed air exiting from a compressor is mixed with fuel in a combustor. The mixture is combusted in the combustor to generate a high pressure, high temperature gas stream, referred to as a post combustion gas or product. The post combustion gas is expanded in a turbine, which converts thermal energy associated with the post combustion gas to mechanical energy that rotates a turbine shaft. The post combustion gas exits the turbine as an expanded combustion gas.
Among the challenges to improve combustor efficiency include efficient mixing of fuel and air and stabilization of the resulting flame. One of the means for addressing these challenges is inclusion of a trapped vortex (TV) cavity located upstream of the combustor, which forms a TV combustor and makes combustion or the flame more stable. Fuel is injected into the TV cavity from certain fixed points within the TV cavity. A portion of the air entering the combustor is diverted towards the TV cavity, which as the name suggests, traps the portion of the air into forming a vortex. However, the present TV combustor doesn't further comprise any downstream (or aft) fuel introduction stage downstream of the TV cavity.
The TV cavity is very stable over a large AFR (air fuel ratio) range for good ignition and low load operability, but it has a NOx penalty associated with the longer inherent residence time at full-load/throttle conditions. Furthermore, the TV cavity may be over-loaded in temperature and volumetric heat release as the engine (and combustor) goes up in load.
It is desirable to achieve lower NOx emission levels. The present disclosure aims to achieve lower NOx emission levels.
In accordance with one aspect of an exemplary embodiment, a trapped vortex combustor is provided. The combustor comprises a trapped vortex combustion zone and at least one secondary combustion zone. The trapped vortex combustion zone is operable to receive and combust a first fuel and a first air and produce a first combustion product flowing toroidally therein. The at least one secondary combustion zone is disposed downstream of the trapped vortex combustion zone, and operable to receive and combust the first combustion product and at least one second injection consisting of fuel and/or air and produce at least one second combustion product therein.
In accordance with one exemplary embodiment, a method for operating a trapped vortex combustor is provided. The method comprises: directing a first fuel and a first air into a trapped vortex combustion zone of the combustor; combusting the first fuel and the first air in the trapped vortex combustion zone and producing a first combustion product flowing toroidally therein; directing the first combustion product and at least one second injection consisting of fuel and/or air into at least one secondary combustion zone of the combustor disposed downstream of the trapped vortex combustion zone; combusting the first combustion product and the at least one second injection consisting of fuel and/or air in the at least one secondary combustion zone and producing at least one second combustion product therein; directing the at least one second combustion product towards a combustor exit of the combustor for discharging out of the combustor.
It should be understood that the brief description above is provided to introduce in simplified form a selection of concepts that are further described in the detailed description. It is not meant to identify key or essential features of the claimed subject matter, the scope of which is defined uniquely by the claims that follow the detailed description. Furthermore, the claimed subject matter is not limited to implementations that solve any disadvantages noted above or in any part of this disclosure.
Reference will now be made in detail to present embodiments of the disclosure, one or more examples of which are illustrated in the accompanying drawings. The detailed description uses numerical and letter designations to refer to features in the drawings. Like or similar designations in the drawings and description have been used to refer to like or similar parts of the disclosure.
As used herein, the terms “first”, “second”, “third” and “fourth” 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,” “downstream,” “radially,” and “axially” 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. Similarly, “radially” refers to the relative direction substantially perpendicular to the fluid flow, and “axially” refers to the relative direction substantially parallel to the fluid flow. The modifier “about” used in connection with a quantity is inclusive of the stated value and has the meaning dictated by the context (e.g., includes the degree of error associated with measurement of the particular quantity).
In order to simplify illustration and description, only the upper half portion of the combustor 1 in
In an exemplary embodiment, the combustor 1 comprises an annular combustor that is shaped as generally annular about the longitudinal axis A1 of the gas turbine, such that the TV combustion zone 12, the secondary combustion zone 14 and the tertiary combustion zone and the other downstream (or aft) combustion zone(s) may all be shaped as annular. The TV combustion zone 12 may be formed or shaped as a trapped vortex (TV) combustion cavity in various embodiments. A combustor casing 10 is positioned around the combustor for providing support or protection and the like.
As illustrated in
As described above, the TV combustion zone 12 may have a substantially circular longitudinal cross-sectional shape depicted in
The one or more pilot fuel nozzles 120 are operable to inject a first fuel (or reactant) into the TV combustion zone 12. The pilot fuel nozzle(s) 120 may be air-blast nozzle(s), pressure atomizer nozzle(s), plain jet orifice nozzle(s), or any other kinds of nozzles that one skilled in the art could conceive. The first fuel comprises a liquid fuel, a gaseous fuel and their combination, which can be selected from the usual fuels, such as jet fuel and any other kinds of fuel that any person skilled in the art could conceive. A first air 124 is a compressed air from a compressor (not shown) disposed upstream of the combustor 1, and the first air 124 is directed into the TV combustion zone or cavity 12 via a plurality of air apertures (not shown) formed through the wall W1 along a periphery of the TV combustion cavity 12, and flows toroidally and enhances the mixing effect with the first fuel.
The first fuel and the first air are received and mixed in the TV combustion zone 12, and combust onset by the spark of the igniter 122 and produce a first combustion product P1 flowing toroidally therein. In some embodiments, the TV combustion zone may be disposed substantially radially outside of the secondary combustion zone 14; as illustrated in
The secondary combustion zone 14 comprises at least one second fuel nozzle 140 for injecting the second fuel thereinto, and the secondary zone 14 is operable to receive and combust the first combustion product P1 and the second fuel and a second air also from the compressor and produce a second combustion product P2 therein. The second combustion product P2 is discharged out of the combustor 1 via the exit 18 if the combustor doesn't further comprise other combustion zone(s). The secondary combustion zone 14 may have a single second fuel nozzle 140. In an exemplary embodiment, the secondary combustion zone 14 may comprise a plurality of second fuel nozzles 140, such as two to thirty, which are symmetrically disposed circumferentially along an outside wall or liner of the secondary combustion zone 14. The second fuel nozzle(s) 140 may similarly be air-blast nozzle(s), pressure atomizer nozzle(s), plain jet orifice nozzle(s), or other suitable nozzles that one skilled in the art could conceive. In other embodiments, none of the second fuel nozzles 140 need to be provided or operated for injecting the second fuel, for example, when combusting in the TV combustion zone belongs to the rich fuel-air ratio combustion or under the other condition that the second fuel needn't be directly injected into the secondary combustion zone 14.
As illustrated in
The second air may be set passively between about 10% and about 60% by weight or by volume of a combustor air comprising the first air and the second air, and the second fuel varies between about 0.1% and about 90% by weight or by volume of a combustor fuel comprising the first fuel and the second fuel. If there are other downstream combustion zone(s) rather than the secondary combustion zone 14, the above percentage amounts of the second air and the second fuel may have taken the amounts of the other downstream combustion zone(s) into account. The amount (or the ratio) of the first air, the second air, the first fuel and the second fuel may be selected or adjusted based on the condition of the gas turbine, such as load, delivery power, etc., so that combusting in the TV combustion zone and combusting in the secondary combustion zone each belongs to one of a lean fuel-air ratio combustion, a stoichiometric combustion, or a rich fuel-air ratio combustion over a spectrum of loads/conditions. The second air and/or the second fuel can be called as a second injection and needn't be limited to being directly supplied into the second combustion zone, and the second air or the second fuel may correspond to or come from an unspent counterpart of the first combustion product or an entrained counterpart (such as air injected by the air jet partitions 15 in
In other embodiments, none of the third fuel nozzle 270 need to be provided or operated for injecting the third fuel, for example, when combusting in the secondary combustion zone 24 belongs to the rich fuel-air ratio combustion or under the other condition that the third fuel needn't be directly injected into the tertiary combustion zone 27. Similarly, the third air and/or the third fuel can be called as a third injection and needn't be limited to being directly supplied into the tertiary combustion zone, and the third air or the third fuel may correspond to or come from an unspent or entrained counterpart of the first combustion product and/or the second combustion product or any other bypassed counterpart(s). Similar aft/downstream injection(s) consisting of air and/or fuel are injected into respective aft/downstream combustion zone(s) or stage(s) if provided.
In the combustor 2 of
In operation, the combustor 1 or 2 or 3 utilizes the pilot fuel nozzle(s) 120 or 220 or 320 for introducing the first fuel in the TV combustion zone 12 or 22 or 32 to mix with the first air 124 or 224 or 324 from the compressor, the ignitor(s) (indicated by 122 in
The combustor 1 or 2 or 3 as depicted in
The combustor 1 or 2 or 3 can improve operational flexibility via optimized independent zones, such as the secondary combustion zone and/or the tertiary combustion zone. More compact overall combustor size can be achieved since main combustion or combusting can be occurred in the secondary combustion zone and the second fuel is burned in “hot” vitiated, the first combustion product.
The method 900 begins at step 910 by directing a first fuel and a first air into a trapped vortex (TV) combustion zone of the combustor. As illustrated in above description and embodiments, the TV combustor is configurable to be an annular combustor, and the TV combustion zone may be shaped as a TV combustion cavity and configured as arcuate in longitudinal cross-section (as illustrated in
As descried above, the first air may be a compressed air from a compressor disposed upstream of the combustor, and the first air is directed into the cavity from a plurality of primary air apertures (not shown) formed along a periphery or on opposite sides of the TV combustion cavity and flows toroidally and enhances the mixing effect with the first fuel.
The method 900 further comprises combusting the first fuel and the first air in the TV combustion zone and producing a first combustion product flowing toroidally therein at step 920; the combusting in the TV combustion zone may belong to one of a lean fuel-air ratio combustion, a stoichiometric combustion, or a rich fuel-air ratio combustion, and the specific combustion mode or type depends on the above-mentioned loads and other conditions and emission regulations, etc.
The method 900 further comprises directing the first combustion product and a second fuel and/or a second air into a secondary combustion zone disposed downstream of the TV combustion zone at step 930. The second air may be introduced into the secondary combustion zone by bypassing the TV combustion zone as illustrated in
The second air is set passively between about 10% and about 60% by weight or by volume of a combustor air comprising the first air and the second air, and the second fuel varies between about 0.1% and about 90% by weight or by volume of a combustor fuel comprising the first fuel and the second fuel. If there are other downstream combustion zone(s) rather than the secondary combustion zone 14, the above percentage amounts the second air and the second fuel may have taken the amounts of the other downstream combustion zone(s) into account. As described above the specific amount or ratio or percent of the second air and the second fuel depend on the operation conditions, loads, other parameters, etc. The second fuel or the first fuel may be a liquid fuel and a gaseous fuel, or any other suitable fuel. The TV combustion zone is disposed radially outside of the secondary combustion zone (by referring to
The method 900 further comprises combusting the first combustion product and the second fuel and/or the second air in the secondary combustion zone and producing a second combustion product therein at step 940. At step 940 combusting in the secondary combustion zone may belong to one of a lean fuel-air ratio combustion, a stoichiometric combustion, or a rich fuel-air ratio combustion. The specific combustion mode or type also depends on the above-mentioned loads, other operation conditions and emission regulations, etc.
The method 900 further comprises discharging the second combustion product via a combustor exit at step 950, if the combustor merely has single secondary combustion zone; namely the combustor comprises only the TV combustor and the secondary combustion zone without a tertiary combustion zone. If the combustor has more than one secondary combustion zone, such as the combustor further comprising a tertiary combustion zone disposed downstream of the secondary combustion zone as illustrated in
Similarly, the third air and/or the third fuel can be called as a third injection and needn't be limited to being directly supplied into the tertiary combustion zone, and the third air or the third fuel may correspond to or come from an unspent or entrained counterpart of the first combustion product and/or the second combustion product or any other bypassed counterpart(s).
The method 900 further comprises combusting the second combustion product and the third fuel and/or the third air in the tertiary combustion zone and producing at least one third combustion product therein at step 970, subsequent to step 960, namely a sum of the combustion product and the fuel and/or the air before or upstream of the tertiary combustion zone enter into the tertiary combustion zone and mix with the third fuel and/or the third air and conduct combusting together.
The method 900 further comprises discharging the third combustion product out of the combustor via the exit at step 980.
If the combustor further comprises more other combustion zone(s), the method 900 could proceed or repeat steps 960-970 to complete all stage(s) of combusting prior to proceed step 980 and discharging the last combustion product out of the combustor.
Various embodiments allow the relatively downstream combustion zones to combust or fire at a higher temperature than the relatively upstream combustion zones when in near-full-load operation. This also allows the highest temperature combustion products to have the shortest stay in the combustor, consequently, producing less NOx for the total combustor.
In one embodiment, a trapped vortex combustor comprises: a trapped vortex combustion zone operable to receive and combust a first fuel and a first air and produce a first combustion product flowing toroidally therein; and at least one secondary combustion zone disposed downstream of the trapped vortex combustion zone, and operable to receive and combust the first combustion product and at least one second injection consisting of fuel and/or air and produce at least one second combustion product therein.
In one example, the combustor further comprises a combustor exit, wherein the at least one secondary combustion zone is located nearer to the combustor exit than the trapped vortex combustion zone.
In one example, the trapped vortex combustion zone is disposed radially outside of the at least one secondary combustion zone.
In one example, the trapped vortex combustion zone is disposed radially inside of the at least one secondary combustion zone.
In one example, the at least one secondary combustion zone comprises a secondary combustion zone and at least one tertiary combustion zone disposed downstream of the secondary combustion zone, and the at least one tertiary combustion zone is operable to receive and combust the at least one second combustion product and at least one third injection consisting of fuel and/or air and produce at least one third combustion product therein.
In one example, the trapped vortex combustor comprises an annular combustor, and the trapped vortex combustion zone is configured as arcuate or rectangular or circular in cross-section.
In one example, an air jet partition is disposed between the trapped vortex combustion zone and the at least one secondary combustion zone, and the air jet partition is operable to jet air for separating combusting in the trapped vortex combustion zone from combusting in the at least one secondary combustion zone.
In one example, a structural partition is disposed between the trapped vortex combustion zone and the at least one secondary combustion zone, and the structural partition is utilized for separating combusting in the trapped vortex combustion zone from combusting in the at least one secondary combustion zone.
In one example, the trapped vortex combustion zone is configured as a trapped vortex combustion cavity, and the first air is directed into the trapped vortex combustor along a periphery of the trapped vortex combustion cavity.
In another example, at least one of the first air and the first combustion product in the trapped vortex combustion cavity is operable to flow in a clockwise direction or in a counterclockwise direction or a combination thereof.
In another embodiment, a method for operating a trapped vortex combustor, the method comprises: directing a first fuel and a first air into a trapped vortex combustion zone of the combustor; combusting the first fuel and the first air in the trapped vortex combustion zone and producing a first combustion product flowing toroidally therein; directing the first combustion product and at least one second injection consisting of fuel and/or air into at least one secondary combustion zone of the combustor disposed downstream of the trapped vortex combustion zone; combusting the first combustion product and the at least one second injection consisting of fuel and/or air in the at least one secondary combustion zone and producing at least one second combustion product therein; and directing the at least one second combustion product towards a combustor exit of the combustor for discharging out of the combustor.
In one example, wherein the trapped vortex combustion zone is disposed radially outside of the at least one secondary combustion zone or disposed radially inside of the at least one secondary combustion zone.
In one example, the trapped vortex combustor comprises an annular combustor, and the trapped vortex combustion zone is configured as arcuate or rectangular or circular in cross-section.
In one example, the method further comprises separating combusting in the trapped vortex combustion zone from combusting in the at least one secondary combustion zone via a structural partition or an air jet partition disposed between the trapped vortex combustion zone and the at least one secondary combustion zone, wherein the air jet partition is operable to jet air for separating combusting in the trapped vortex combustion zone from combusting in the at least one secondary combustion zone.
In one example, the trapped vortex combustion zone is configured as a trapped vortex combustion cavity, and the first air is directed into the trapped vortex combustor along a periphery of the trapped vortex combustion cavity.
In another example, at least one of the first air and the first combustion product in the trapped vortex combustion cavity is operable to flow in a clockwise direction or in a counterclockwise direction or a combination thereof.
In one example, the method further comprises: directing the at least one second combustion product and at least one third injection consisting of fuel and/or air into at least one tertiary combustion zone of the combustor disposed downstream of the secondary combustion zone; combusting the at least one second combustion product and the at least one third injection consisting of fuel and/or air in the at least one tertiary combustion zone and producing at least one third combustion product therein; and directing the at least one third combustion product towards the exit for discharging out of the combustor.
In one example, the at least one second injection comprises at least one second air and/or at least one second fuel, and the at least one second air bypasses the trapped vortex combustion zone, and the at least one secondary combustion zone is provided with at least one second fuel nozzle for injecting the at least one second fuel at an angle of from about 30 to 90 degrees relative to the at least one second air or the first combustion product directed into the at least one secondary combustion zone, and wherein the at least one second fuel comprises a liquid fuel and a gaseous fuel.
In one example, the at least one second injection comprises at least one second air and/or at least one second fuel, and the at least one second air is set between about 10% and about 60% by weight or by volume of a combustor air comprising the first air and the at least one second air, and the second fuel varies between about 0.1% and about 90% by weight or by volume of a combustor fuel comprising the first fuel and the at least one second fuel.
In one example, wherein combusting in the trapped vortex combustion zone and combusting in the at least one secondary combustion zone each belongs to one of a lean fuel-air ratio combustion, a stoichiometric combustion, or a rich fuel-air ratio combustion.
While the disclosure has been described in detail in connection with only a limited number of embodiments, it should be readily understood that the invention is not limited to such disclosed embodiments. Rather, the invention can be modified to incorporate any number of variations, alterations, substitutions or equivalent arrangements not heretofore described, but which are commensurate with the spirit and scope of the invention. Additionally, while various embodiments of the invention have been described, it is to be understood that aspects of the disclosure may include only some of the described embodiments. Accordingly, the invention is not to be seen as limited by the foregoing description, but is only limited by the scope of the appended claims.
This written description, which includes the best mode, uses examples to disclose the invention and to enable any person skilled in the art to practice the invention, including making and using any devices or systems and performing any incorporated methods. The patentable scope of the invention is defined by the claims, and may include other examples that occur to those skilled in the art. Such other examples are intended to fall within the scope of the claims if they include structural elements that do not differ from the literal language of the claims, or if they include equivalent structural elements with insubstantial differences from the literal language of the claims.
Number | Date | Country | |
---|---|---|---|
Parent | 15709958 | Sep 2017 | US |
Child | 17358377 | US |