This invention relates to the field of gas turbine engines, and more particularly, to a can combustor for use in a gas turbine engine.
Gas turbine engines are known to include a compressor for compressing air; a combustor for producing a hot gas by burning fuel in the presence of the compressed air produced by the compressor, and a turbine for expanding the hot gas to extract shaft power. The combustion process in many older gas turbine engines is dominated by diffusion flames burning at or near stoichiometric conditions with flame temperatures exceeding 3,000° F. Such combustion will produce a high level of oxides of nitrogen (NOx). Current emissions regulations have greatly reduced the allowable levels of NOx emissions, requiring improvements in combustors to reduce undesirable NOx production.
Gas turbine engines using annular combustion systems typically include a plurality of individual burners disposed in a ring about an axial centerline for providing a mixture of fuel and air to an annular combustion chamber disposed upstream of the annular turbine inlet vanes. The combustion process of the several burners will interact in the combustion chamber since all burners discharge the combustible mixture to the single annulus. Consequently, combustion processes in one burner may affect the combustion processes in the other burners. Other gas turbines use can-annular combustors wherein individual burner cans feed hot combustion gas into respective individual portions of the arc of the turbine inlet vanes. Each can includes a plurality of main burners disposed in a ring around a central pilot burner, as illustrated in U.S. Pat. No. 6,082,111. Can annular combustors are generally more expensive to fabricate as a result of the use of multiple burners within each of the multiple combustor cans which may include cross flame tubes connecting combustor baskets.
The demand to decrease exhaust emissions continues, thus improved techniques for economically controlling the combustion conditions of a gas turbine engine are needed.
The invention will be more apparent from the following description in view of the drawings that show:
In conventional can annular gas turbine engine configurations, each combustor typically includes a plurality of main burners disposed in a ring around a pilot burner. However, such can annular combustors are generally more complex and expensive to fabricate and maintain because of the use of multiple burners within each of the combustors. The inventors of the present invention have innovatively recognized that a single main burner 12, instead of a plurality of burners, can reduce the complexity and expense of fabricating a can annular combustor, while additionally providing reduced NOx emissions.
In an aspect of the invention, the single main burner 12 includes a single main burner swirler 58. The main burner swirler 58 includes mixing vanes 60 having fuel injection openings 62 for providing a flow of a fuel/oxidizer mixture 22 into a combustion chamber 30. The combustion chamber 30 is defined by the combustion chamber liner 32 positioned downstream of the main burner 12 and receives the fuel/oxidizer mixture 22 from the main burner 12. The combustion chamber liner 32 has a larger inside diameter, D1, than a diameter, D2, of the outlet end 24 of the main burner 12, thereby forming an annular space between the main burner 12 and the combustion chamber liner 32. Each combustor 10 may also include a central pilot burner 26, wherein pilot fuel 74 may be premixed with an oxidizer, such as air, and passed through pilot mixing vanes 64 to provide a stable, low emission pilot flame near an outlet end 24 of the main burner 12. The central pilot burner 26 may be operated as a diffusion burner, a partially premixed burner, or a premixed burner. For example, the pilot burner 26 may be operated as a diffusion burner at low turbine load conditions, and operated as a premix burner at high turbine load conditions.
The main burner 12 is positioned within the liner support 72. The liner support 72 may be attached to the casing 40, for example, at an upstream end 142. The liner support 72 may include a number of spaced apart struts 102, so that a first portion of the oxidizer flow 18 can flow through the liner support 72 in a flow reversal region 118. The combustion chamber liner 32 may be attached to the liner support 72 with removable fasteners, for example, by bolting an upstream end 116 of the liner 32 to a downstream end 112 of the support 72, for ease of installation and removal.
The combustion chamber liner 32 may further be provided with one or more resonators 70 for damping combustion pressure oscillations within the combustion chamber 32. For example, the resonator 70 may include a number of resonator openings 80 in the combustion chamber liner 32 in fluid communication with a resonator cavity 82 positioned around an exterior portion of the combustion chamber liner 32. In another aspect, the resonator 70 may extend circumferentially around the combustion chamber liner 32 downstream of the outlet end 24.
The combustor 10 of
A fuel outlet 44, such as a fuel injection ring, or a “tophat” type fuel injector, as known in the art, may be positioned in the flow reversing region 118 for premixing a secondary fuel flow 46 into the oxidizer flow 42 before it is delivered to the main burner 12. The fuel outlet 44 may include an annular ring having an inlet opening 84 for receiving the secondary fuel flow 46, and a plurality of outlet openings, for example, circumferentially distributed in the fuel outlet 44, for discharging the secondary fuel flow 46 into the oxidizer flow 42.
The inventors have discovered that positioning of the fuel outlet 44 in the flow reversing region 118 near the inlet end 20 of the main burner 12 provides a less restricted flow around the fuel outlet 44 than placing the fuel outlet 44, for example, near the upstream end 78 of the oxidizer flow path 38. This position advantageously results in a smaller pressure differential between the oxidizer flow 42 upstream of the fuel outlet 44 and downstream of the fuel outlet 44 compared to a position of the fuel outlet 44 in an area of the flow path 38 having a smaller cross sectional area than the flow reversing region 118. Accordingly, positioning of the fuel outlet in the flow reversing region can minimize oxidizer flow 42 pressure build-up upstream of the fuel outlet 44.
In an aspect of the invention, an essentially flat (i.e. perpendicular to the axial direction of airflow) burner insert assembly 88 is provided at the outlet end 24 of the main burner 12 to prevent the oxidizer flow 38 from bypassing the main 12 burner. The flat geometry of the burner insert assembly 88 provides an abrupt diameter change from the outlet end 24 of the main burner 12 to the combustion chamber 30, which causes a flow vortex 76 just downstream of the burner insert assembly 88 within the combustion chamber 30. The flow vortex 76 promotes mixing and appears to improve combustion performance. The inventors have experimentally determined that the flat geometry of the burner insert assembly 88 advantageously provides reduced NOx formation compared to other geometries, such as a tapered shape.
In one form, the burner insert assembly 88 may be constructed of two portions—an annular burner insert 34 having a hot side surface 36 that is exposed to the hot combustion gas, and a burner insert support 48 that is protected from the hot combustion products produced in the combustion chamber 30.
The burner insert 34 may be formed from a heat resistant material alloy, such as Hastelloy® (a registered trademark of Haynes International, Incorporated) or other high temperature nickel-based or cobalt-based alloy, and the hot side surface 36 may be coated with a heat resistant material such as a thermal barrier coating (TBC) to withstand hot combustion products in the combustion chamber 30. In one aspect, the TBC may be about 1.6 mm thick. The burner insert 34 may have a generally “J” shaped cross-section 90 forming a circumferential mounting lip 92 for attaching the burner insert 34 to the support 48. The outside diameter, D3, of the burner insert 34 may be slightly smaller than the inside diameter D1 of the combustion chamber liner 32 so that a second portion of the oxidizer flow 42 can flow into the combustion chamber 30 around the burner insert 34. For example, D3 may be about 0.4 millimeters (0.016 inches) less than D1. The burner insert 34 may also include a number of raised spacing tabs 94 extending a radial distance further than the outside diameter, D3, of the burner insert 34, and spaced apart around the outer periphery 110 of the burner insert 34 for keeping the burner insert spaced away from the inside diameter, D1, of the combustion chamber liner 32. For example, each spacing tab 94 may extend a radial distance of 0.2 millimeters (0.008 inches) further than D3.
The burner insert support 48, depicted in
The insert support 48 may further include an impingement plate 54 as shown in
The combustor 10 may further feature passageways 114, such as combustor liner openings, in the upstream end 116 of the combustion chamber liner 32 near the periphery 110 of the burner insert 34 for allowing passage of a third portion of the oxidizer flow 66 into the combustion chamber 30. For example, the passageways 114 may be distributed uniformly around the combustion chamber liner 32 near the burner insert 34, or at different distances apart. The passageways 114 may be sized, shaped, and angled to provide a desired flow path through the combustion chamber liner 32 into the combustion chamber 30. Accordingly, the passageways 114 may be configured so that the third portion of the oxidizer flow 66 flowing through the passageways 114 is about 2.0% of the oxidizer flow 42 provided to the combustor 10. Experimental tests have demonstrated that this third portion of the oxidizer flow 66 flowing into the combustion chamber 30 appears to reduce emissions of NOx during the combustion process due, it is believed, to improved dynamic pressure stability.
A turbine 136, receives the hot combustion gas 134, where it is expanded to extract mechanical shaft power. In one embodiment, a common shaft 138 interconnects the turbine 136 with the compressor 122, as well as an electrical generator (not shown) to provide mechanical power for compressing the ambient air 124 and for producing electrical power, respectively. The expanded combustion gas 140 may be exhausted directly to the atmosphere or it may be routed through additional heat recovery systems (not shown). The gas turbine engine 10 provides improved manufacturing, maintainability and, reduced NOx formation as a result of features of the combustor 10 described above and shown more clearly in
While the preferred embodiments of the present invention have been shown and described herein, it will be obvious that such embodiments are provided by way of example only. Numerous variations, changes and substitutions will occur to those of skill in the art without departing from the invention herein. Accordingly, it is intended that the invention be limited only by the spirit and scope of the appended claims.
This application claims the benefit of U.S. Provisional Application 60/436,228 filed Dec. 23, 2002.
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