This invention relates to gas turbine combustors and particularly to a liquid fuel cartridge designed to prevent formation of internal coke deposits about the fuel nozzle tip.
The formation of coke deposits at the tip of a fuel injector nozzle can interfere with the desired fuel/air mixture delivered to the combustion chamber throughout the various stages of combustion, and thus negatively impact on the reduction of oxides of nitrogen (NOx)required by exhaust emissions regulations.
One attempt to solve the coke formation problem is described in U.S. Pat. No. 6,715,292. A coke-resistant fuel injector for a low-emission combustor is formed with a pressure-atomizing core nozzle and an airblast secondary injector. The airblast portion includes inner and outer air passages for injecting co-annular, co-swirling streams into the combustor can. An air distribution baffle extends radially across the inner air passage to divide the inner airstream into a substream and a plurality of air jets. The presence of the air baffle and co-swirling inner and outer air streams is said to promote superior fuel-air mixing which promotes clean burning and resists coke formation.
The present invention provides a liquid fuel cartridge (LFC) that utilizes an internal heat shield and purge air to prevent internal coking formation and overheating of the LFC tip.
In a first exemplary but nonlimiting embodiment, there is provided a liquid fuel cartridge assembly for a gas turbine combustor comprising an elongated stem provided with a fuel injector tip at an aft end of said stem, said injector tip provided with a pilot fuel passage extending to a pilot fuel orifice; a plurality of air channels surrounding said pilot fuel passage and in communication with plural air exit openings; an annular main fuel passage surrounding said plurality of air channels and in communication with plural fuel exit holes; and a plurality of substantially radially oriented air supply holes in said stem upstream but proximate to a forward end of said tip in communication with said plurality of air channels.
In another aspect, the invention provides a liquid fuel cartridge assembly for a combustor of a gas turbine comprising an elongated, hollow stem provided with a fuel injector tip at an aft end of said stem, said injector tip provided with a pilot fuel passage centered within said tip along a longitudinal axis of said tip and extending to a pilot fuel orifice; a plurality of air channels surrounding said pilot fuel passage and in communication with plural air exit openings within said fuel injector tip; an annular main fuel passage surrounding said plurality of air channels and in communication with plural fuel exit openings radially outward of said plural air exit holes; a plurality of substantially radially oriented air supply holes in said stem upstream of said tip in communication with said plurality of air channels; and wherein said stem encloses a first pilot fuel supply pipe in fluid communication with said pilot fuel passage and a second main fuel supply pipe in fluid communication with said annular main fuel passage that are intertwined along a length portion of said hollow stem.
In still another aspect, there is provided a liquid fuel cartridge assembly for a combustor of a gas turbine comprising an elongated stem provided with a fuel injector tip at an aft end of said stem, said stem enclosing main fuel and pilot fuel supply pipes, said injector tip provided with a pilot fuel passage centered within said tip along a longitudinal axis of said tip; a plurality of air channels surrounding said pilot fuel passage; an annular main fuel passage surrounding said plurality of purge/cooling air channels; and a plurality of substantially radially oriented air supply holes in said stem upstream and adjacent said fuel injector tip in communication with said plurality of air channels; wherein said injector tip is comprised of an outer sleeve, a concentrically-arranged inner sleeve and a concentrically-arranged center core; said pilot fuel passage and said plurality of air channels formed in said center core; and said annular main fuel passage formed in a radial space between said first-inner sleeve and said center core.
Liquid fuel is supplied to the tip 18 by means of intertwined conduits or helix pipes 20, 22 (see also
As best seen in
The radial space between the inner sleeve 26 and the center core 28 forms an annular main fuel channel 36, and the aft tip of the inner sleeve 26 is formed with slanted fuel exit orifices 38 arranged about the flanged end 32. The center core 28 is formed with a circumferentially arranged plurality of axially-extending cooling channels 40 in the radially outer region of the center core that open into an annular space 41 formed by adjacent-tapered portions 50, 54 (described below) of a nozzle insert 42. The nozzle insert 42 is received in a counterbore 44 formed in the center of the core 28. The counterbore 44 extends in an aft direction from, and is contiguous with, the bore 46 which forms the pilot fuel passage. The nozzle insert 42 includes an axially-extending cylindrical section 48 received in the counterbore 44 and an inwardly-tapered portion 50 leading to a single, centered pilot fuel exit orifice 52. The nozzle insert then extends outwardly via tapered portion 54 to an edge 56. The outwardly-tapered portion 54 includes annular rows or arrays of openings in the form of holes and optional slots 60, 62, respectively described in further detail below. A swirler element 64 is located within the nozzle insert, upstream of the exit orifice 52, where the cylindrical section 48 joins the inwardly tapered portion 50. The swirler element swirls the pilot fuel prior to its exit via the orifice 52, thus promoting better mixing with air downstream of the nozzle tip.
From the above construction, it will be appreciated that the main fuel channel 36 is insulated on opposite radial sides by purge/cooling air flowing through the channels 40 (radially inside), and passive air in the radial space between the outer sleeve 24 and the inner sleeve 26 (radially outside). The outer sleeve 24 also serves as a heat shield for the liquid fuel. The purge/cooling air entry ports 66 are located close to the tip 18 and thus provide cooler purge air than if supplied axially through the stem 16. The purge air flowing through the channels 40 also prevents overheating of the pilot fuel flowing through the center bore 46. The annular space 41 formed by the inwardly-tapered portion 50 and outwardly-tapered portion 54 of nozzle insert 42 enables the purge air to exit the annular arrays of holes and optional slots 60, 62 in a swirling and/or counter-swirling manner to thereby prevent or at least minimize coke formation at the tip of the nozzle insert 42. The purge air discharge about the pilot fuel orifice exit 52 also provides for quasi-premix purged gas combustion with reduced NOx emissions.
While the invention has been described in connection with what is presently considered to be the most practical and preferred embodiment, it is to be understood that the invention is not to be limited to the disclosed embodiment, but on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims.
Number | Date | Country | |
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20150135716 A1 | May 2015 | US |
Number | Date | Country | |
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Parent | PCT/RU2012/000992 | Nov 2012 | US |
Child | 14082677 | US |