This invention relates to gas turbine combustion systems and, specifically, to a fuel nozzle design which minimizes combustor damage during a combustion flame flashback or flame holding event.
A gas turbine combustor mixes large quantities of fuel and compressed air and burns the resulting mixture. Conventional combustors for industrial gas turbines typically include an annular array of cylindrical combustion “cans” in which air and fuel are mixed and combustion occurs. Compressed air from an axial compressor flows into the combustor. Fuel is injected through fuel nozzle assemblies that extend into each can. The mixture of fuel and air burns in a combustion chamber of each can. The combustion gases discharge from each can into a duct that leads to the turbine.
Combustion cans, designed for low emissions, include premix chambers and combustion chambers. Fuel nozzle assemblies in each combustion can inject fuel and air into the chambers of the can. A portion of the fuel from the nozzle assembly is discharged into the premix chamber of the can, where air is added to and premixed with the fuel. Premixing air and fuel in the premix chamber promotes rapid and efficient combustion in the combustion chamber of each can, and low emissions from the combustion. The mixture of air and fuel flows downstream from the premix chamber to the combustion chamber which supports combustion and under some conditions receives additional fuel discharged by the front of the fuel nozzle assembly. The additional fuel provides a means of stabilizing the flame for low power operation, and may be completely shut off at high power conditions.
A flashback or flame holding condition may occur in combustion cans having premix chambers. The premix chambers are not intended to support combustion. Flashback occurs when flame propagates into the premix chamber from the downstream combustion chamber, typically caused by momentary transient conditions. Flame holding occurs when a flame is initiated in the premixing zone, possibly by an external source such as a spark or hot foreign object ejected by the compressor, and the flame then stabilizes in a recirculation zone or weak boundary layer zone immediately downstream of the portion of the fuel nozzle assembly discharging fuel into the premix chamber. The damage resulting from flashback or flame holding may include burning combustor components not intended to be subjected to the heat of combustion. The damage caused by burning these combustor components may cause the components to malfunction and break up. If broken sections of the combustor flow into the combustion gas stream, they potentially may damage the hot gas path, e.g., turbine in the gas turbine.
Fuses in fuel nozzle assemblies prevent flame holding by diverting fuel away from the fuel nozzles for the premix chamber. The diversion of fuel from the premix chamber causes the abnormal flame to burn out and prevents further combustion in the premix chamber. However, conventional fuse designs, such as disclosed in U.S. Pat. No. 5,685,139, are not suited to all types of fuel nozzle assemblies. Accordingly, there is a need for novel designs of fuses.
A fuel nozzle assembly for a combustor of a gas turbine has been developed comprising: a nozzle body having a front and an inner tube defining a fuel passage extending through the nozzle body; an outer tube around the inner tube and defining an air passage between the outer tube and the inner tube; a weakened region of the outer tube which burns through in event of a flashback thereby causing a portion of premix fuel to bypass the injectors and to be discharged from the weakened region; an expandable conduit arranged in the air passage and having an outlet adjacent the weakened region, wherein fuel flows through the expandable conduit when the weakened region of the outer tube burns through and the fuel flow is discharged from the conduit, through the weakened region and towards the front of the nozzle body, and a collar attached to the nozzle body, the collar including a premix fuel passage and ports discharging fuel from the collar, wherein the expandable conduit has an inlet open to the premix fuel passage.
A method has been developed for quenching a flashback condition in a combustor of a gas turbine, the method comprising: injecting fuel and compressed air from a fuel injector assembly to a premix chamber of the combustor, wherein the injected fuel and compressor air does not normally combust in the premix chamber; combusting the fuel and compressed in a combustion chamber downstream of the premix chamber in the combustor; providing air to the combustion chamber from a front of the injector assembly through an air passage extending through a nozzle body of the fuel injector; injecting fuel to the combustion chamber from a fuel passage having an outlet at the front of the injector assembly; opening an outlet of a conduit in response to a flashback condition adjacent the fuel injector assembly, wherein the outlet is proximate the front of the injector assembly and the conduit extends through the air passage; diverting fuel from the premix chamber to the conduit by the opening of the outlet, and quenching flames of the flashback condition by the diversion of fuel.
Pressurized air from the compressor enters each combustion can 18 the combustor 10 and flows (see air arrow 19) through an annular duct 20 formed between a cylindrical sleeve 22 and an inner cylindrical liner 24 of the can. Compressed air flows through the duct 20 towards the end cover assembly 26 of the can in a reverse flow direction to the combustion gases formed in the can (see combustion gas arrow 28). Air enters the combustion chamber 30 and premix chambers 32 in each can through various openings in the liner 24 and through the premixer inlets 25 in the fuel nozzle assemblies 34.
A mixture of fuel and air is supplied to the premix chambers 32 and the combustion chamber by fuel nozzle assemblies 34 arranged at the front of the can and attached to the end cover. The fuel and compressed air mix in the premix chamber and flow to the combustion chamber 30. The mixture burns in the combustion chamber and the resulting combustion gases flow (see combustion flow arrow 28) from the cans to a transition duct 36 that directs the combustion gases to the turbine blades 16.
Each combustion can 18 includes a substantially cylindrical combustion casing 38 which is secured at an open aftward end to the compressor casing 14. The forward end of the combustion can is closed by the end cover assembly 26 which may include conventional fuel supply tubes, manifolds and associated valves for feeding gas, liquid fuel and air (and water if desired) to the combustor can. The end cover assembly 26 supports multiple fuel nozzle assemblies 34 for each can. For example, fuel nozzle assemblies may be arranged in a circular array around a center nozzle assembly. These nozzle assemblies may be treated has having the same structure, at least for purposes of describing the fuse system.
Fuel from the fuel passage, that would normally flow to the premix chamber, flows through the rear fuse base 58 and the helical conduits 56 to the nozzle base 60 when the fuse is activated by a flashback event. After the fuse has been activated, the fuel flowing through the helical conduits 56 diverts fuel from the premix chamber(s) to prevent further combustion of fuel in that chamber(s).
Openings 63, 64 on the front fuse and nozzle base 60 allow the fuel from the helical conduits 56 to discharge through the front of the nozzle body and into the combustion chamber. The openings 63, 64 are normally blocked to prevent the flow of fuel through the helical conduits. When the openings 64 are not blocked, the flow of fuel through helical conduits diverts fuel from the premix chamber, so as to quench a flash back or flame holding condition. The front fuse and nozzle base also includes air nozzles 66 for air discharged from the front of the fuel nozzle. The discharged air forms an air curtain around the fuel flowing from the front 46 of the fuel nozzle.
As indicated by flow arrow 72, the fuel gas flows from the gas passage 70, through passages 71 in the rear fuse base 58, the openings 61, 62 that lead to the radial vanes 50 of the rear collar, out the fuel ports 52 in the vanes and into the premix chamber. The gas flows as indicated by arrow 72, unless the fuse has been activated. An single flow arrow 72 is shown to indicate a premix gas path through the rear collar 42 and passages in the vanes 50. However, one or multiple premix gas paths may be in the rear collar and vanes. Each of the premix gas paths may be associated with a different one of the helical conduits 56. Further each of the premix gas paths may be associated with one or more of the helical conduits.
When the fuse is activated, the gas flows from passage 70, through the passages 71 in the rear fuse base 58 and to the helical conduits 56 as indicated by flow arrow 74. The conduits 56 provide a flow path that diverts most of the fuel in passage 70 away from the vanes 50 and the fuel ports 52.
The helical conduits 56 are arranged in an annular air passage 76 between the tube 69 of the gas passage 68 and an outer tubular casing 78 of the nozzle body 40. Air enters through ports 77 in the rear collar 42 and flows into the air passage 76. The air flows through the passage 76, across outer surfaces of the helical conduits 56 and to the front fuse and nozzle base. The size and number of the conduits 56 are such that the air flowing through the passage 76 is sufficient for the curtain of air flow needed at the front of the fuel nozzle. Preferably, the helical conduits occupy less than one half of the volume of the passage 76.
The openings 64 in the front fuse and nozzle base 60 are adjacent a weakened section 80, e.g., a relatively thin annular section, of the casing 78. The weakened sections 80 may be a segmented annular region of the casing 78 that has been machined to remove some of the thickness of the casing wall adjacent the openings 64 of the base 60. The weakened sections 80 are susceptible to burning through in the event of a flashback. Once burned through, the opened weakened sections 80 allow fuel to flow out the openings 64 in the fuse and nozzle base 60 and flow through the helical conduits 56. The flow of fuel through the helical conduits diverts fuel from the premix chamber and starves and quenches any flame occurring in the premix chamber to stop the flash back condition.
The inner cylindrical wall of the gas passage 68 has a front end that fits into a quasi-conical inner sleeve assembly 82 that supports the front nozzle 84. The inner sleeve assembly allows for thermal expansion between the cylindrical wall of the gas passage and the front nozzle. Air from the annular passage 76 flows through the front fuse and nozzle base 60 and through swirl vanes 86 before being discharged around the front of the center fuel discharge nozzle ports 88 for the gas passage 68.
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.
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Number | Date | Country | |
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20090293482 A1 | Dec 2009 | US |