Piloted rich-catalytic lean-burn hybrid combustor

Information

  • Patent Grant
  • 6415608
  • Patent Number
    6,415,608
  • Date Filed
    Tuesday, September 26, 2000
    24 years ago
  • Date Issued
    Tuesday, July 9, 2002
    22 years ago
Abstract
A catalytic combustor assembly which includes, an air source, a fuel delivery means, a catalytic reactor assembly, a mixing chamber, and a means for igniting a fuel/air mixture. The catalytic reactor assembly is in fluid communication with the air source and fuel delivery means and has a fuel/air plenum which is coated with a catalytic material. The fuel/air plenum has cooling air conduits passing therethrough which have an upstream end. The upstream end of the cooling conduits is in fluid communication with the air source but not the fuel delivery means.
Description




BACKGROUND OF THE INVENTION




Field of the Invention




This invention relates to a catalytic combustor for a combustion turbine and, more specifically, to a piloted rich-catalytic lean-burn hybrid combustor having a plurality of cooling air conduits passing through a fuel/air mixture plenum.




BACKGROUND INFORMATION




Combustion turbines, generally, have three main assemblies: a compressor assembly, a combustor assembly, and a turbine assembly. In operation, the compressor compresses ambient air. The compressed air flows into the combustor assembly where it is mixed with a fuel. The fuel and compressed air mixture is ignited creating a heated working gas. The heated working gas is expanded through the turbine assembly. The turbine assembly includes a plurality of stationary vanes and rotating blades. The rotating blades are coupled to a central shaft. The expansion of the working gas through the turbine section forces the blades, and thereafter the shaft, to rotate. The shaft maybe connected to a generator.




Typically, the combustor assembly creates a working gas at a temperature between 2,500 to 2,900 degrees Fahrenheit (1371 to 1593 degrees centigrade). At high temperatures, particularly above about 1,500 degrees centigrade, the oxygen and nitrogen within the working gas combine to form the pollutants NO and NO


2


, collectively known as NOx, a known pollutant. The formation rate of NOx increases exponentially with flame temperature. Thus, for a given engine working gas temperature, the minimum NOx will be created by the combustor assembly when the flame is at a uniform temperature, that is, there are no hot spots in the combustor assembly. This is accomplished by premixing all of the fuel with all of the of air available for combustion (referred to as low NOx lean-premix combustion) so that the flame temperature within the combustor assembly is uniform and the NOx production is reduced.




Lean pre-mixed flames are generally less stabile than non-well-mixed flames, as the high temperature regions of non-well-mixed flames add to a flame's stability. One method of stabilizing lean premixed flames is to react some of the fuel/air mixture in a catalyst prior to the combustion zone. To utilize the catalyst, a fuel/air mixture is passed over a catalyst material, or catalyst bed, causing a pre-reaction of a portion of the mixture and creates radical which aid in stabilizing combustion at a downstream location within the combustor assembly.




Prior art catalytic combustors completely mix the fuel and the air prior to the catalyst. This provides a fuel lean mixture to the catalyst. However, with a fuel lean mixture, typical catalyst materials are not active at compressor discharge temperatures. As such, a preburner is required to heat the air prior to the catalyst adding cost and complexity to the design as well as generating NOx emissions, See e.g., U.S. Pat. No. 5,826,429. It is, therefore, desirable to have a combustor assembly that burns a fuel lean mixture, so that NOx is reduced, but passes a fuel rich mixture through the catalyst bed so that a preburner is not required.




One disadvantage of using a catalyst is that the catalyst is subject to degradation when exposed to high temperatures. High temperatures may be created by the reaction between the catalyst and the fuel, pre-ignition within the catalyst bed, and/or flashback ignition from the downstream combustion zone extending into the catalyst bed. To reduce the temperature within the catalyst bed, prior art catalyst beds included cooling conduits which pass through the catalyst bed. The cooling conduits were free of the catalyst material and allowed a portion of the fuel/air mixture to pass, unreacted, through the cooling conduits. Another portion of the fuel/air mixture passed over, and reacted with the catalyst bed. Then, the two portions of the fuel/air mixture were combined. The unreacted fuel/air mixture absorbed heat created by the reaction of the fuel with the catalyst and/or any ignition or flashback within the catalyst bed. See e.g., U.S. Pat. No. 4,870,824 and U.S. Pat. No. 4,512,250.




The disadvantage of such cooling systems is that the cooling conduits utilize a gas comprising a fuel/air mixture. This fuel/air mixture is subject to premature ignition within the cooling conduits. Such premature ignition would destroy the heat absorbing capability of the fuel/air mixture thereby allowing the catalyst bed to overheat.




There is, therefore, a need for a catalytic reactor assembly for a combustion turbine, which includes a cooling means that does not rely on a fuel/air mixture to be a cooling fluid.




There is a further need for a catalytic reactor assembly for a combustion turbine, which eliminates the possibility of igniting the gas within a cooling passage.




There is a further need for a catalytic reactor assembly which improves the performance of the catalyst to a point where a preburner is no longer required.




There is a further need for a catalytic reactor assembly which maybe retrofitted with existing combustor designs.




SUMMARY OF THE INVENTION




These needs, and others, are satisfied by the disclosed invention which provides a catalytic reactor assembly having a fuel/air plenum with cooling conduits passing therethough. The cooling conduits are in fluid communication with an air source. The outer surface of the cooling conduits and the inner surface of the fuel/air plenum are coated with a catalytic material. The fuel/air plenum and the cooling air conduits each have a downstream end which is in fluid communication with a mixing chamber. Thus, a fuel rich fuel/air mixture may pass through the fuel/air plenum. Air passes through the cooling conduits. When the fuel/air mixture and the cooling air are mixed, a fuel lean pre-ignition gas is created. The fuel lean pre-ignition gas is ignited creating a working gas with a reduced amount of NOx.




The fuel/air plenum is created by an inner shroud and an end plate which is located opposite the downstream end of the fuel/air mixture plenum. A first plenum surrounds the fuel/air plenum. The first plenum is in fluid communication with a fuel source and an air source. The air source may be the same source which provides air to the cooling conduits. At the downstream end of the mixing chamber is a flame chamber and igniter assembly.




The catalytic reactor assembly may be included in the combustor assembly of a combustion turbine which includes a compressor assembly, a combustor assembly and a turbine assembly. Typically, the combustion turbine includes an outer shell which encloses a plurality of combustor assemblies. The outer shell creates a compressed air plenum which is fluid communication with the compressor assembly. At the downstream end of the combustor assemblies are transition sections, which are also enclosed within the compressed air plenum, which are coupled to the turbine assembly.




It is advantageous to have a fuel rich mixture in the catalyst section for several reasons. For example, the catalyst is more active because more fuel is in contact with the catalytic material. This allows the catalyst to be active at temperatures below the temperature of the air at the exit of the compressor. Therefore a pre-burner is not required upstream of the catalyst to preheat the fuel/air mixture. Additionally, having an oxygen lean environment in the catalyst zone controls the amount of fuel that is reacted. When less fuel is reacted, less heat is created therefore limiting the temperature in the catalyst bed.




In operation the compressor assembly compresses ambient air which is delivered to the compressed air plenum. Compressed air within the compressed air plenum is split into at least two portions: the first portion enters the first plenum and the second portion travels through the cooling conduits. A third portion may be directed to an pilot assembly. Within the first plenum, a fuel is introduced from a fuel source and mixed with the first compressed air flow to create a fuel rich fuel/air mixture. The fuel rich fuel/air mixture is delivered to the fuel/air plenum which surrounds the cooling air conduits and is in contact with the catalyst material. The fuel rich fuel/air mixture is reacted with the catalyst material and delivered to the mixing chamber. The second portion of compressed air enters the cooling chambers and absorbs heat from the catalytic reaction. The second portion of the compressed air then passes into the mixing chamber where it is mixed with the heated fuel/air mixture to create a pre-ignition gas. The combined pre-ignition gas contains an excess of air and is, therefore, fuel lean. The fuel lean pre-ignition gas is delivered to a flame zone where it auto-ignites or is ignited by the pilot assembly creating a working gas. The working gas travels through the transition sections and is delivered to the turbine assembly.











BRIEF DESCRIPTION OF THE DRAWINGS




A full understanding of the invention can be gained from the following description of the preferred embodiments when read in conjunction with the accompanying drawings in which:





FIG. 1

is a cross sectional view of a combustion turbine.





FIG. 2

is a detailed partial cross sectional view of a combustor assembly shown on FIG.


1


.





FIG. 3

is an isometric view showing modular catalytic cores disposed about a central axis.











DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT




As is well known in the art and shown in

FIG. 1

, a combustion turbine includes a compressor assembly


2


, a catalytic combustor assembly


3


, a transition section


4


, and a turbine assembly


5


. A flow path


10


exists through the compressor


2


, catalytic combustor assembly


3


, transition section


4


, and turbine assembly


5


. The turbine assembly


5


may be mechanically coupled to the compressor assembly


2


by a central shaft


6


. Typically, an outer casing


7


encloses a plurality of catalytic combustor assemblies


3


and transition sections


4


. Outer casing


7


creates a compressed air plenum


8


. The catalytic combustor assemblies


3


and transition sections


4


are disposed within the compressed air plenum


8


. The catalytic combustor assemblies


3


are, preferably, disposed circumferentiality about the central shaft


6


.




In operation, the compressor assembly


2


inducts ambient air and compresses it. The compressed air travels through the flow path


10


to the compressed air plenum


8


defined by casing


7


. Compressed air within the compressed air plenum


8


enters a catalytic combustor assembly


3


where, as will be detailed below, the compressed air is mixed with a fuel and ignited to create a working gas. The working gas passes from the catalytic combustor assembly


3


through transition section


4


and into the turbine assembly


5


. In the turbine assembly


5


the working gas is expanded through a series of rotatable blades


9


which are attached to shaft


6


and the stationary vanes


11


. As the working gas passes through the turbine assembly


5


, the blades


9


and shaft


6


rotate creating a mechanical force. The turbine assembly


5


can be coupled to a generator to produce electricity.




As shown in

FIG. 2

, the catalytic combustor assembly


3


includes a fuel source


12


, a support frame


14


, an pilot assembly


16


, fuel conduits


18


, and a catalytic reactor assembly


20


. The catalytic reactor assembly


20


includes a catalytic core


21


, an inlet nozzle


22


, and an outer shell


24


. The catalytic core


21


includes an inner shell


26


, an end plate


28


, a plurality of cooling conduits


30


, and an inner wall


32


. The catalytic core


21


is an elongated toroid which is disposed axially about the igniter assembly


16


. Inner wall


32


is disposed adjacent to igniter assembly


16


. Both the inner shell


26


and the inner wall


32


have interior surfaces


27


,


33


respectively, located within the fuel/air plenum


38


(described below).




Outer shell


24


is in a spaced relation to inner shell


26


thereby creating a first plenum


34


. The first plenum


34


has a compressed air inlet


36


. The compressed air inlet


36


is in fluid communication with an air source, preferably the compressed air plenum


8


. A fuel inlet


37


penetrates outer shell


24


. Fuel inlet


37


is located downstream of air inlet


36


. The fuel inlet


37


is in fluid communication with a fuel conduit


18


. The fuel conduit is in fluid communication with the fuel source


12


.




A fuel/air plenum


38


is defined by endplate


28


, inner shell


26


, and inner wall


32


. There is at least one fuel/air mixture inlet


40


on inner shell


26


, which allows fluid communication between first plenum


34


and fuel/air plenum


38


. The fuel/air plenum


38


has a downstream end


42


, which is in fluid communication with a mixing chamber


44


.




The plurality of cooling conduits


30


each have a first end


46


and a second end


48


. Each cooling conduit first end


46


extends through plate


28


and is in fluid communication with inlet nozzle


22


. The cooling conduit first ends


46


, which are the upstream ends, are isolated from the fuel inlet


37


. Thus, fuel cannot enter the first end


46


of the cooling conduits


30


. Each cooling conduit second end


48


is in fluid communication with mixing chamber


44


. The conduits


30


have an interior surface


29


and an exterior surface


31


. A catalytic material, such as platinum or palladium, may be bonded to the conduit outer surface


31


. Additionally, the catalytic material may be bonded to the interior surface


27


of inner shell


26


and the interior surface


33


of inner wall


32


. Thus, the surfaces within the fuel/air plenum


38


are, generally, coated with a catalytic material. In the preferred embodiment, the cooling conduits are tubular members. The cooling conduits


30


may, however, be of any shape and may be constructed of members such as plates.




The mixing chamber


44


has a downstream end


49


, which is in fluid communication with a flame zone


60


. Flame zone


60


is also in fluid communication with pilot assembly


16


.




The pilot assembly


16


includes an outer wall


17


, which defines an annular passage


15


. The annular passage


15


is in fluid communication with compressed air plenum


8


. The pilot assembly


16


is in further communication with a fuel conduit


18


. The pilot assembly


16


mixes compressed air from annular passage


15


and fuel from conduit


18


and ignites the mixture with a spark igniter. The compressed air in annular passage


15


is swirled by vanes in annular passage


15


. The angular momentum of the swirl causes a vortex flow with a low-pressure region along the centerline of the pilot assembly


16


. Hot combustion products from flame zone


60


are re-circulated upstream along the low-pressure region and continuously ignite the incoming fuel air mixture to create a stabile pilot flame. Alternately, the spark igniter may be used when pilot flame is unstable.




In operation air from an air source, such as the compressed air plenum


8


, is divided into at least two portions; a first portion, which is about 10 to 20 percent of the compressed air in the flow path


10


, flows through air inlet


36


into the first plenum


34


. A second portion of air, which is about 75 to 85 percent of the compressed air within the flow path


10


, flows through inlet


22


into cooling conduits


30


. A third portion of air, which is about 5 percent of the compressed air in the flow path


10


, may flow through the pilot assembly


16


.




The first portion of air enters the first plenum


34


. Within first plenum


34


the compressed air is mixed with a fuel that enters first plenum


34


through fuel inlet


37


thereby creating a fuel/air mixture. The fuel/air mixture is, preferably, fuel rich. The fuel rich fuel/air mixture passes through fuel/air inlet


40


into the fuel/air plenum


38


. As the fuel rich fuel/air mixture, which is created in first plenum


34


, enters the fuel/air plenum


38


. The fuel/air mixture reacts with the catalytic material disposed on the conduit outer surfaces


31


, inner shell interior surface


27


, and inner wall interior surface


33


. The reacted fuel/air mixture exits the fuel/air plenum


38


into mixing chamber


44


.




The second portion of air travels through inlet


22


and enters the cooling conduit first ends


46


, traveling through cooling conduits


30


to cooling conduit second end


48


. Air which has traveled through cooling conduits


30


also enters mixing chamber


44


. As the air travels through conduits


30


, it absorbs heat created by the reaction of the fuel/air mixture with the catalytic material. Within mixing chamber


44


, the reacted fuel/air mixture and compressed air is further mixed to create a fuel lean pre-ignition gas. The fuel lean pre-ignition exits the downstream end of the mixing chamber


49


and enters the flame zone


60


. Within flame zone


60


the fuel lean pre-ignition gas is ignited by pilot assembly


16


thereby creating a working gas.




The use of the catalytic material allows a controlled reaction of the rich fuel/air mixture at a relatively low temperature such that almost no NOx is created in fuel/air plenum


38


. The reaction of a portion of the fuel and air preheats the fuel/air mixture which aids in stabilizing the downstream flame in flame zone


60


. When the fuel rich mixture is combined with the air, from the second portion of compressed air, a fuel lean pre-ignition gas is created. Because the pre-ignition gas is fuel-lean, the amount of NOx created by the combustor assembly is reduced. Because compressed air only travels through the cooling conduits


30


, there is no chance that a fuel air mixture will ignite within the cooling conduits


30


. Thus, the cooling conduits


30


will always be effective to remove heat from the fuel/air plenum


38


thereby extending the working life of the catalytic material.




As shown in

FIG. 3

, for ease of construction the catalytic reactor assembly may be separated into modules


50


that are disposed about a central axis


100


. Each module


50


includes inner shell


26




a


, an inner wall


32




a


and sidewalls


52


,


54


. A plurality of cooling conduits


30




a


are enclosed by inner shell


26




a


, inner wall


32




a


and sidewalls


52


,


54


. Each module also has an end plate


28




a


, an outer shell


24




a


and a fuel inlet


37




a


. As shown, six modules


50


form a generally hexagonal shape about the central axis


100


. Of course, any number of modules


50


of various shapes could be used.




While specific embodiments of the invention have been described in detail, it will be appreciated by those skilled in the art that various modifications and alternatives to those details could be developed in light of the overall teachings of the disclosure. For example, although the catalytic core has been shown as being disposed circumferentially about the pilot assembly, the catalytic core could be disposed on just one side of the pilot assembly. Accordingly, the particular arrangements disclosed are meant to be illustrative only and not limiting as to the scope of invention which is to be given the full breadth of the claims appended and any and all equivalents thereof.



Claims
  • 1. A catalytic combustor assembly comprising:an air source; a fuel delivery means; a catalytic reactor assembly in fluid communication with said air source and fuel delivery means and having a fuel/air plenum which is coated with a catalytic material; said fuel/air plenum having cooling air conduits passing therethrough having an upstream end; said cooling conduits in fluid communication with said air source and isolated from said fuel delivery means at said upstream end; a mixing chamber in fluid communication with said fuel/air plenum and said cooling air conduits; and a means for igniting a fuel/air mixture.
  • 2. The catalytic combustor of claim 1, wherein said catalytic reactor assembly includes an outer shell and an elongated catalytic core;said catalytic core spaced from said outer shell creating a first plenum; said outer shell having at least one fuel inlet and at least one air inlet; said catalytic core forming said fuel/air plenum having the plurality of cooling air conduits passing axially therethrough; said fuel/air plenum in fluid communication with said first plenum; and wherein fuel and air may be introduced through said fuel inlet and said air inlet into said first plenum creating a fuel/air mixture which is then passed through said fuel/air plenum.
  • 3. The catalytic combustor of claim 2, wherein said air source is further in fluid communication with both said air inlet and said cooling conduits.
  • 4. The catalytic combustor of claim 3, wherein:said fuel/air plenum and cooling conduits each have a downstream end; and said downstream end of said fuel/air plenum and said downstream end of said cooling conduits are in fluid communication with said mixing chamber.
  • 5. The catalytic combustor of claim 4, wherein:said means for igniting a fuel/air mixture is an pilot assembly; said mixing chamber has a downstream end; said downstream end is disposed adjacent to said pilot assembly; and said downstream end is in fluid communication with said pilot assembly.
  • 6. The catalytic combustor of claim 5, wherein:said catalytic core has an inner shell, an upstream end and an inner wall; said catalytic core includes a plate at said upstream end of said inner wall; said inner shell, said inner wall and said end plate define said fuel/air plenum; said cooling conduits include a plurality of tubular members having open upstream ends and open downstream ends; and said plurality of tubular member open upstream ends passing through said end plate.
  • 7. The catalytic combustor of claim 6, wherein said tubular member open upstream ends are in fluid communication with said air source.
  • 8. The catalytic combustor of claim 7, wherein:said catalytic reactor assembly includes a flame zone; said flame zone is disposed downstream of, and in fluid communication with, said mixing chamber and pilot assembly.
  • 9. A combustion turbine comprising:a compressor assembly; a catalytic combustor assembly; a turbine assembly; an outer casing surrounding said catalytic combustor assembly and defining a compressed air plenum; a flow path extending through said compressor assembly, said compressed air plenum, said catalytic combustor assembly, and turbine assembly; wherein said catalytic combustor assembly includes: a fuel delivery means; a catalytic reactor assembly in fluid communication with said compressed air plenum and fuel delivery means and having a fuel/air plenum which is coated with a catalytic material; said fuel/air plenum having cooling air conduits passing therethrough having an upstream end; said cooling conduits in fluid communication with said air source and isolated from said fuel delivery means at said upstream end; a mixing chamber in fluid communication with said fuel/air plenum and said cooling air conduits; and a means for igniting a fuel/air mixture.
  • 10. The catalytic combustor of claim 9, wherein:said catalytic reactor assembly includes an outer shell and an elongated catalytic core; said catalytic core spaced from said outer shell creating a first plenum; said outer shell having at least one fuel inlet and at lease one air inlet; said catalytic core forming said fuel/air plenum having said plurality of cooling air conduits passing axially therethrough; said fuel/air plenum in fluid communication with said first plenum; and wherein fuel and air may be introduced through said fuel inlet and said air inlet into said first plenum creating a fuel/air mixture which is then passed through said fuel/air plenum.
  • 11. The combustion turbine of claim 10, wherein:said means for igniting a fuel/air mixture is an pilot assembly; said fuel/air plenum and cooling conduits each have a downstream end; and said downstream end of said fuel/air plenum and said downstream end of said cooling conduits are in fluid communication with said mixing chamber.
  • 12. The combustion turbine of claim 11, wherein said mixing chamber has a downstream end;said downstream end is disposed adjacent to said pilot assembly; and said downstream end is in fluid communication with said pilot assembly.
  • 13. The combustion turbine of claim 12, wherein:said catalytic core has an inner shell, an upstream end and an inner wall; said catalytic core includes a plate at said upstream end of said inner wall; said inner shell, said inner wall and said end plate define said fuel/air plenum; said cooling conduits include a plurality of tubular members having open upstream ends and open downstream ends; and said plurality of tubular member open upstream ends passing through said end plate.
  • 14. The combustion turbine of claim 13, wherein said tubular member open upstream ends are in fluid communication with said compressed air plenum.
  • 15. The combustion turbine of claim 14, wherein:said catalytic reactor assembly includes a flame zone; said flame zone is disposed downstream of, and in fluid communication with, said mixing chamber and said pilot assembly.
  • 16. A modular catalytic combustor assembly comprising:an air source; a fuel delivery means; a plurality of modular catalytic reactor assemblies each having an outer shell, an inner shell, an inner wall and two side walls; said inner shell, inner wall and side walls forming a fuel/air plenum said fuel/air plenum in fluid communication with said air source and fuel delivery means and coated with a catalytic material; said fuel/air plenum having cooling air conduits passing therethrough having an upstream end; said cooling conduits in fluid communication with said air source and isolated from said fuel delivery means at said upstream end; a mixing chamber in fluid communication with said fuel/air plenum and said cooling air conduits; and a means for igniting a fuel/air mixture.
  • 17. The modular catalytic combustor of claim 16, wherein:said outer shell has at least one fuel inlet and at least one air inlet, said outer shell being spaced apart from said inner shell forming a first plenum; said fuel/air plenum in fluid communication with said first plenum; and wherein fuel and air may be introduced through said fuel inlet and said air inlet into said first plenum creating a fuel/air mixture which is then passed through said fuel/air plenum.
  • 18. The modular catalytic combustor of claim 17, wherein said air source is further in fluid communication with both said air inlet and said cooling conduits.
  • 19. The modular catalytic combustor of claim 18, wherein:said fuel/air plenum and cooling conduits each have a downstream end; and said downstream end of said fuel/air plenum and said downstream end of said cooling conduits are in fluid communication with said mixing chamber.
  • 20. The modular catalytic combustor of claim 19, wherein:said means for igniting a fuel/air mixture is an pilot assembly; said mixing chamber has a downstream end; said downstream end is disposed adjacent to said pilot burner; and said downstream end is in fluid communication with said pilot assembly.
  • 21. The modular catalytic combustor of claim 20, wherein:said catalytic core has an inner shell, an upstream end and an inner wall; said catalytic core includes a plate at said upstream end of said inner wall; said inner shell, said inner wall and said end plate define said fuel/air plenum; said cooling conduits include a plurality of tubular members having open upstream ends and open downstream ends; and said plurality of tubular members open upstream ends passing through said end plate.
  • 22. The modular catalytic combustor of claim 21, wherein said tubular members open upstream ends are in fluid communication with said air source.
  • 23. The modular catalytic combustor of claim 22, wherein:said catalytic reactor assembly includes a flame zone; said flame zone is disposed downstream of, and in fluid communication with, said mixing chamber and pilot assembly.
GOVERNMENT CONTRACT

The government of the United States of America has certain rights in this invention pursuant to contract no. DE-FC21-95MC32267 awarded by the U.S. Department of Energy.

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Number Name Date Kind
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5235804 Colket et al. Aug 1993 A
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5461864 Betta et al. Oct 1995 A
5512250 Betta et al. Apr 1996 A