Turbine engine fuel nozzle

Information

  • Patent Grant
  • 6832481
  • Patent Number
    6,832,481
  • Date Filed
    Thursday, September 26, 2002
    22 years ago
  • Date Issued
    Tuesday, December 21, 2004
    20 years ago
Abstract
A performance-enhancing fuel nozzle is disclosed. The nozzle suitable for use in combustors which combine high-swirl-number combustion in a pilot zone with low-swirl-number combustion in a main combustion zone. The nozzle includes a fuel delivery member adapted for fluid communication with a fuel source and a flow conditioning member having a fuel exit port. The fuel exit port is in fluid communication with the fuel supply and is adapted to ensure that the recirculation region adjacent the nozzle tip remains flame free. In one aspect of the invention, the fuel concentration profile of the nozzle is characterized by a radially-outward region that is flammable and a radially-inward region that is substantially non-flammable. In another aspect of the invention, the fuel exit port being is disposed a radially-outward portion of the flow conditioning member. In another aspect of the invention, the flow conditioning member is characterized by a swirl number lower than about 0.5. In another aspect of the invention, the exit are high-momentum jets, having a design ratio pressure of greater than about 1.1. In another aspect of the invention, the nozzle is part of a combustor which has a high-swirl-number combustion in a pilot zone and low-swirl-number combustion in a main combustion zone.
Description




FIELD OF THE INVENTION




This invention relates generally to the field of fuel nozzles and, more particularly, to a combustor and associated fuel nozzle having improved fuel concentration profile characteristics.




BACKGROUND OF THE INVENTION




Combustion engines are machines that convert chemical energy stored in fuel into mechanical energy useful for generating electricity, producing thrust, or otherwise doing work. These engines typically include several cooperative sections that contribute in some way to this energy conversion process. In gas turbine engines, air discharged from a compressor section and fuel introduced from a fuel supply are mixed together and burned in a combustion section. The products of combustion are harnessed and directed through a turbine section, where they expand and turn a central rotor.




A variety of combustor designs exist, with different designs being selected for suitability with a given engine and to achieve desired performance characteristics. One popular combustor design includes a centralized pilot nozzle and several main fuel injector nozzles arranged circumferentially around the pilot nozzle. With this design, the nozzles are arranged to form a pilot flame zone and a mixing region. During operation, the pilot nozzle selectively produces a stable flame which is anchored in the pilot flame zone, while the main nozzles produce a mixed stream of fuel and air in the above-referenced mixing region. The stream of mixed fuel and air flows out of the mixing region, past the pilot flame zone, and into a main combustion zone, where additional combustion occurs. Energy released during combustion is captured by the downstream components to produce electricity or otherwise do work.




In one version of this type of combustor, two types of combustion occur: high-swirl-combustion occurs in the pilot flame zone, with low-swirl-number combustion occurring in the main combustion zone. As is known in this field, high-swirl-number combustion is characterized by relatively-compact flames, with high rates of rotation and relatively-low rates of longitudinal propagation. Low-swirl-number combustion, conversely, is characterized by flames which are relatively more spread out. By combining high swirl number combustion in the pilot flame zone with low swirl number combustion elsewhere, this type of combustor provides stable and predictable operation and a high degree of monitorability. As a result, this type of combustor is suitable for use across a wide range of operating conditions. Additionally, by providing a combustion scheme which yields a wide-spread distribution of energy within the combustion chamber, this type of combustor is also resistant to thermo-acoustic excitations. These combustors also present a relatively-long pre-combustion mixing path for the fuel and air which helps ensure even-temperature burning and reduced emissions levels. Accordingly, this type of combustor is a popular choice for use in industrial turbine engines.




In order to ensure optimum performance of this type of combustor, it is generally preferable that the internal fuel-and-air streams are well-mixed, to avoid localized, fuel-rich regions. Combustion of over-rich pockets of fuel and air leads to high-temperature combustion that produces high levels of unwanted NOx emissions. As a result, efforts have been made to produce combustors with essentially-uniform distributions of fuel and air. Swirler elements, for example, are often used to produce a stream of fuel and air in which air and injected fuel are evenly mixed.




Unfortunately, while attempts to reduce emissions by uniformly distributing fuel and air are effective in some cases, they are not suitable with all combustors. For example, combustors like the ones described above, which combine high-swirl-number combustion in a pilot zone with low-swirl-number combustion in a main combustion zone, can actually suffer increases in unwanted emissions and acoustic resonance problems when used with nozzles that produce uniform distributions of fuel and air. In this type of combustor uniformly distributed mixtures of fuel and air lead to flame holding at the main nozzle tips which, in addition to increasing unwanted emissions and acoustic problems, also introduces the need for nozzle tip cooling and increases the risk of dangerous flashback. Therefore, while efforts to improve performance through uniformly distributing fuel and air are effective in some settings, they can actually reduce the performance of some combustors.




Accordingly, there remains a need for a performance-enhancing nozzles suitable for use in combustors which combine high-swirl-number combustion in a pilot zone with low-swirl-number combustion in a main combustion zone. The nozzle should eliminate combustion outside the mixing zone immediately downstream of the nozzle, without negatively impacting the overall performance of the combustor. The nozzle should produce a radially-biased fuel concentration profile which reduces the tendency for flame holding at the nozzle tip. The nozzle should also provide the desired fuel concentration profile over a wide range of operating conditions, without regard to fluctuating fuel and air inputs.




SUMMARY OF THE INVENTION




The instant invention is a performance-enhancing nozzle suitable for use in combustors which combine high-swirl-number combustion in a pilot zone with low-swirl-number combustion in a main combustion zone. The nozzle includes a fuel delivery member adapted for fluid communication with a source of fuel and a flow conditioning member that includes at least one fuel exit port which is in fluid communication with the fuel supply and adapted to ensure that the region adjacent the nozzle tip remains flame free. In one aspect of the invention, the nozzle produces a fuel concentration profile characterized by a radially-outward region that is flammable and a radially-inward region that is substantially non-flammable. In another aspect of the invention, the flow conditioning element includes a radially-inboard first portion and a radially outward second portion, with the fuel exit ports being disposed in the second portion. In another aspect of the invention, the flow conditioning element is characterized by a swirl number lower than about 0.6. In another aspect of the invention, the exit ports may be characterized as high-momentum, having a design ratio pressure of greater than about 1.1. In another aspect of the invention, the nozzle is part of a combustor which produces high-swirl-number combustion in a pilot zone and low-swirl-number combustion in a main combustion zone.




Accordingly, it is an object of the present invention to provide a fuel nozzle that eliminates combustion outside a mixing zone immediately downstream of the nozzle, without negatively impacting the overall performance of the combustor.




It is another object of the present invention to provide a nozzle that produces a radially-biased fuel concentration profile which reduces the tendency for flame holding at the nozzle tip.




It is yet a further object of the present invention to provide a nozzle that produces the desired fuel concentration profile over a wide range of operating modes, without regard to fluctuating nozzle inlet conditions.




It is also an object of the present invention to provide a nozzle that is compatible with previously-installed combustors, allowing the nozzle to be used in retrofit operations.




Other objects and advantages of this invention will become apparent from the following description taken in conjunction with the accompanying drawings wherein are set forth, by way of illustration and example, certain embodiments of this invention. The drawings constitute part of this specification and include exemplary embodiments of the present invention and illustrate various objects and features thereof.











BRIEF DESCRIPTION OF THE DRAWING





FIG. 1

is a side elevation of a combustion engine employing the nozzle of the present invention;





FIG. 2

is a side sectional view of the nozzle of the present invention; and





FIG. 3

is a partial side elevation of a combustor using the nozzle shown in FIG.


2


.











DETAILED DESCRIPTION OF THE INVENTION




Reference is now made in general to the Figures, wherein the nozzle


10


of the present invention is shown. With reference to

FIG. 1

, the nozzle


10


of the present invention will be described in use within an industrial combustion turbine engine


12


. By way of overview, and with additional reference to

FIG. 2

, the nozzle


10


includes a centralized fuel delivery member


14


which is in fluid communication with a source of fuel (not shown). Several flow conditioning members


16


are disposed circumferentially around the fuel delivery member


14


, and each of the flow conditioning members includes one or more fuel exit ports


18


. The fuel exit ports


18


are, in turn, fluidly coupled with the fuel deliver member


14


. Fuel


20


passes through the exit ports


18


, and joins air


22


travelling over the flow conditioning members


16


to form a mixture


24


of fuel and air. As described more fully below, the fuel exit ports


18


and flow conditioning members


16


ensure that the air and fuel mixture


24


has a concentration profile


26


that substantially reduces or prevents the formation of flames at the downstream end


28


of the fuel delivery member


14


. The nozzle


10


of the present invention will now be described in further detail.




With continued reference to

FIG. 2

, and with additional reference to

FIG. 3

, the nozzle


10


of the present invention has features which make it especially well-suited for use as a main nozzle within a combustion system


30


that combines high-swirl-number combustion in a pilot flame zone


32


and low-swirl-number combustion in a main combustion zone


34


. The nozzle


10


includes an elongated fuel delivery member


14


which resembles a tube characterized by a downstream tip


28


. In one embodiment, the fuel delivery member


14


is mounted within a nozzle sleeve


35


, and the flow conditioning members


16


extend between the delivery member and the sleeve. In the present embodiment, the flow conditioning members


16


and fuel delivery member


14


may be formed as an integral unit; however, the flow conditioning members may be formed separately, if desired. A flashback annulus


37


, which allows fluid communication between the inlet air


22


and the mixing region


36


is also included and helps lower flame-holding tendencies at the downstream end


39


of the nozzle sleeve


35


.




With continued reference to

FIGS. 2 and 3

, the flow conditioning members


16


are airfoil-shaped swirlers that extend radially outward from the fuel delivery member


14


. With particular reference to

FIG. 2

, the flow conditioning members


16


include preferably three fuel exit ports


18


positioned on each side so as to produce a radially-biased fuel concentration profile


26


in a mixing zone


36


located between the nozzle


10


and the main combustion zone


34


. More particularly, the fuel exit ports


18


are located within a radially-outward portion


38


of the flow conditioning members


16


; the radially-inward portion


40


of the flow conditioning members extending between the radially-outward portion and fuel delivery member contains no fuel exit ports. The distance D between the radially-innermost fuel exit port


18


and the fuel delivery member is within the range of about 30% to 40% of the passage height S


R


. The fuel exit ports


18


are spaced to produce a nearly even fuel distribution within the radially outward portion


38


, but other suitable distributions such as biased toward the center of the passage may be employed as desired. The fuel exit ports


18


are spaced to produce a nearly-uniform fuel distribution within the radially-outward portion


38


, but other suitable distributions such as biased toward the middle of the annulus (to enhance performance of the flashback annulus


37


) may be employed as desired. It is also noted that the flow conditioning members


16


need not have an airfoil-shaped cross section, other suitable shapes which increase the turbulence, including static mixing elements may be used, as desired. It is also noted that not all flow conditioning members


16


need to include three fuel exit ports


18


on each side; more or fewer ports may be included, and some conditioning members may have no exit ports.




In keeping with the objects of the invention, the fuel exit ports


18


are sized and shaped to produce streams of fuel


20


having relatively-high momentum. For example, the fuel exit ports


18


are characterized by a design pressure of about 1.2, with the preferred design pressure being between about 1.1 to about 1.4. The fuel exit ports


18


are generally formed normal to the surface of flow conditioning member


16


, but this may be modified if desired, and the ports may have different or uniform diameters in order to achieve the required mixing profile within the circumferential variation over the operating range. The use of high-momentum jets is not required; however, injecting fuel in this manner provides enhanced stability of the fuel concentration profile


26


, making the fuel distribution less sensitive to varying nozzle inlet conditions.




In one embodiment, the flow conditioning members


16


are swirlers shaped to impart low-swirl-number flow to fluids such as a mixture


24


of air


22


supplied by a compressor section


42


, and fuel introduced by the fuel delivery member


14


. Although swirlers having a variety of properties may be used, swirlers that induce flow having a swirl number in the range between about 0.2 to about 0.6 are desired.




In this application, the term swirl number refers to the known measurement term which quantifies the ratio between longitudinal momentum and rotational momentum for a given stream of fluid at the nozzle exit plane. In the present embodiment, the flow conditioning members contribute to fluid flow in the mixing zone and main combustion zones characterized by a swirl number of about 0.4.




With particular reference to

FIGS. 1 and 3

, the nozzle


10


of the present invention acts as a main nozzle in a staged combustion system


30


. During operation, several, for example eight, main nozzles


10


are grouped together with a pilot nozzle


44


to combust a mixture


24


of fuel


20


and air


22


. As discussed above, the products of this combustion provide a high-energy working fluid


46


that is transferred downstream to a turbine section


48


of an associated engine


12


, where energy is extracted to do further work. A combustor liner


58


downstream of the main and pilot nozzles


10


,


44


bounds the main combustion zone and interfaces with a transition section


60


to guide the products of combustion


46


into the turbine section


48


.




In the combustion system


30


shown in

FIG. 3

, the pilot fuel nozzle


44


produces a stable flame within a pilot flame zone


32


, which may be partially bounded by a boundary cone


50


, as shown. As fuel


20


and air


22


flow downstream from the main nozzles


10


, they flow through a mixing region


36


, where they form a mixture


24


having a radially-biased fuel concentration profile


26


(which is shown in FIG.


2


). With this arrangement, the radially-outward portion


52


of the fuel-and-air mixture


24


flowing near the nozzle sleeve


35


is flammable, while the radially-inward portion


54


of the mixture is not flammable. As a result, the nozzle


10


of the present invention does not support combustion in the recirculation zone


56


located adjacent the nozzle downstream end or tip


28


. In one embodiment, the flammable, radially-outward portion


52


of the fuel-and-air mixture


24


occupies approximately the outer 75% of the radial spacing between the center of the passage and the outside of the passage. The fuel concentration profile


26


need not occupy the outer 75 percent, and may occupy an amount ranging from 60 to 90%. With this arrangement, the recirculation zone


56


remains essentially flame-free, while low-swirl-number combustion is supported in the main combustion zone


34


. With continued operation, the fuel-and-air mixture


24


travels downstream until it contacts the pilot flame zone


32


which provides an anchoring flame and feeds continued combustion in the main combustion zone


34


. The nozzle


10


of the present invention may be used in a new engine


12


, or may be installed into an existing combustion system


30


during a retrofit operation.




It is to be understood that while certain forms of the invention have been illustrated and described, it is not to be limited to the specific forms or arrangement of parts herein described and shown. It will be apparent to those skilled in the art that various changes, including modifications, rearrangements and substitutions, may be made without departing from the scope of this invention and the invention is not to be considered limited to what is shown in the drawings and described in the specification. The scope of the invention is defined by the claims appended hereto.



Claims
  • 1. A nozzle for a combustor comprising:a fuel delivery member adapted for fluid communication with a source of fuel, said fuel delivery member including a solid and closed downstream end; a swirl-inducing flow conditioning member disposed adjacent said fuel delivery member, said flow conditioning member including a fuel exit port in fluid communication with said fuel delivery member; wherein said flow conditioning member is adapted to dispense fuel in a manner which produces a radially-biased fuel concentration profile within the nozzle characterized by a radially-outward region that is flammable and a radially-inward region that is substantially non-flammable, whereby said fuel concentration profile is effective to ensure that a region adjacent said fuel delivery member downstream end is substantially flame-free.
  • 2. The nozzle of claim 1, wherein said flow conditioning member extends radially from said fuel delivery member.
  • 3. The nozzle of claim 1, wherein said nozzle forms a recirculation zone adjacent said fuel delivery member downstream end, and wherein said fuel concentration profile is adapted to ensure said recirculation zone is substantially non-flammable.
  • 4. The nozzle of claim 1, wherein the conditioning element includes a radially-inward first portion and a radially-outward second portion, said fuel exit port being disposed only within said second portion.
  • 5. The nozzle of claim 4, wherein said flow conditioning member includes a plurality of fuel exit ports disposed within said conditioning element second portion.
  • 6. The nozzle of claim 4, wherein said radially-outward second portion is spaced apart from a longitudinal axis of said fuel delivery member by a distance of about 30% to 40% of a radial height of said flow conditioning member.
  • 7. The nozzle of claim 4, wherein said flow conditioning member is adapted to induce a downstream fluid flow characterized by a swirl number, wherein said swirl number is lower than about 0.6.
  • 8. The nozzle of claim 1, wherein said fuel exit ports are characterized by a design pressure ratio effective to introduce fuel in a manner characterized by momentum effective to ensure said fuel concentration profile remains substantially consistent as pre-selected operational conditions vary.
  • 9. The nozzle of claim 8, wherein said design pressure ratio is higher than about 1.1.
  • 10. The nozzle of claim 9, wherein said design pressure ratio is within a range of about 1.1 to about 1.4.
  • 11. The nozzle of claim 8, wherein the conditioning element includes a radially-inward first portion and a radially-outward second portion, said fuel exit port being disposed only within said second portion.
  • 12. The nozzle of claim 8, wherein the conditioning element includes a radially-inward first portion and a radially-outward second portion, said radially-outward second portion being spaced apart from a longitudinal axis of said fuel delivery member by a distance of about 30% to 40% of a radial height of said flow conditioning member.
  • 13. The nozzle of claim 8, wherein said flow conditioning member adapted to induce a downstream fluid flow characterized by a swirl number, wherein said swirl number is lower than about 0.6.
  • 14. A combustor comprising:a source of fuel; a liner member defining an interior region, said interior being characterized by a pilot flame zone and a main combustion zone; a pilot nozzle disposed adjacent a first end of said liner member, said pilot nozzle being in fluid communication with said source of fuel and adapted to provide a pilot flame to said pilot flame zone; a main nozzle disposed adjacent said first end of said liner member, said main nozzle including a fuel delivery member in fluid communication with a source of fuel; said fuel delivery member including a solid and closed downstream end; a swirl-inducing flow conditioning member disposed adjacent said fuel delivery member, said flow conditioning member including a fuel exit port in fluid communication with said fuel delivery member, wherein said flow conditioning member and said flow conditioning member produce a mixture having a fuel concentration profile within the main nozzle characterized by a radially-outward region that is flammable and a radially-inward region that is substantially non-flammable, whereby said mixture combusts in said main combustion zone and whereby said fuel concentration profile is effective to ensure that a region adjacent said fuel delivery member downstream end is substantially flame-free.
  • 15. The combustor of claim 14, wherein said flow conditioning member is adapted to induce a downstream fluid flow characterized by a swirl number, wherein said swirl number is lower than about 0.6.
  • 16. The combustor of claim 14, wherein said fuel exit port is characterized with respect to said fuel delivery member by a design pressure ratio effective to introduce fuel in a manner characterized by momentum effective to ensure said fuel concentration profile remains substantially consistent as pre-selected operational conditions vary.
  • 17. The nozzle of claim 16, wherein said design pressure ratio is higher than about 1.1.
US Referenced Citations (16)
Number Name Date Kind
5251447 Joshi et al. Oct 1993 A
5317864 Shorb et al. Jun 1994 A
5407347 Bortz Apr 1995 A
5461865 Snyder et al. Oct 1995 A
5471840 Lovett Dec 1995 A
5778676 Joshi et al. Jul 1998 A
5813232 Razdan et al. Sep 1998 A
5901555 Mandai et al. May 1999 A
6038861 Amos et al. Mar 2000 A
6047551 Ishiguro et al. Apr 2000 A
6070411 Iwai et al. Jun 2000 A
6094916 Puri et al. Aug 2000 A
6158223 Mandai et al. Dec 2000 A
6179608 Kraemer et al. Jan 2001 B1
6438961 Tuthill et al. Aug 2002 B2
6655145 Boardman Dec 2003 B2
Foreign Referenced Citations (3)
Number Date Country
1 174 662 Jan 2002 EP
09119639 May 1997 JP
09-119639 May 1997 JP