NO166340B - COMBINED DIFFUSION AND premix control nozzle. - Google Patents

Description

The invention relates to a combined diffusion and premixing nozzle according to the preamble.

In an effort to reduce the amount of NOx in the exhaust gas from a gas turbine, inventors Wilkes and Hilt have devised a two-stage, double-acting burner which is shown in US 4,292,801, October 6, 1981 to a joint applicant of this invention. In the aforementioned patent incorporated herein by reference, it is discovered that the amount of exhaust NOx could be significantly reduced compared to a conventional single-stage, single-fuel f-nozzle burner if there were two combustion chambers, so that under normal operating loads the upstream, primary combustion chamber acted as a premix chamber while the actual combustion took place in downstream, other combustion chambers. Under this described mode of operation, there would be no flame in the primary chamber, leading to a reduction in the formation of NOx. In such operation, the secondary or center nozzle constitutes the flame source for the operation of the burner. The particular design of the invention comprises an annular series of primary nozzles, each of which is emptied into the primary combustion chamber and a central, secondary nozzle which is emptied into the second combustion chamber. These nozzles can all be described as diffusion nozzles in that each nozzle has an axial fuel supply tube and is surrounded at its discharge end by an air vortex which provides air for combustion at the discharge of the fuel nozzle. The inventors have discovered that further reduction of NOx can be achieved by changing the design of the central or secondary nozzle so that it can be described as a combined premix and diffusion nozzle. In operation, a relatively small amount of fuel is used to maintain a diffusion igniter while a premix portion of the nozzle provides additional fuel to ignite the main fuel supply from upstream primary nozzles directed into the primary combustion chamber.

It is an object of the invention to provide a stable and complete heat source for igniting a primary, premixed stream under a variety of operating conditions. It is also an object of the invention to reduce the contribution from the flame source to NOx exhaust gases. It is also an object of the invention to reduce the amount of fuel used to provide a diffusion stone flare.

The new properties which are believed to be characteristic of the invention are set out in the appended claims. The invention itself together with other purposes and advantages will, however, be best understood with reference to the following description and drawings.

This invention is particularly suitable for gas turbine burners of the type comprising two burner chambers separated by a venturi throat area. An annular array of primary nozzles discharge fuel into an upstream or primary combustor while a single center nozzle discharges fuel into a downstream or second combustor. The way it works is that under base load the primary nozzles flare up while one of the central or other nozzles entertains the combustion of premixed fuel from the primary nozzles. According to the invention, the one central second nozzle which has been characterized as a diffusion nozzle is replaced by a combined diffusion and premixing nozzle which reduces the fuel f flow to the center diffusion flame from about 20% of the total fuel flow to about 2% of the total fuel f flow for the entire burner. This is done by installing an air supply pipe around a minimum fuel supply pipe to maintain the diffusion flame combustion while the maximum fuel supply into the secondary nozzle occurs by means of radial fuel distribution pipes which each discharge fuel into a premix chamber enclosing the diffusion igniter comprising the axial fuel supply pipe and its enclosing air supply pipe. In this way, a relatively minimal amount of fuel, in a diffusion flame, can be used to ignite the flow from the center nozzle's premix chamber, but the required amount is considerably less than what would be needed to ignite the main premix flow from the remaining enclosing primary nozzles. The design thus simultaneously minimizes the proportion of the total fuel flow in the burner that burns as one diffusion flame (with NOx exhaust gases) but makes it possible to add sufficient heat to ignite the main premix flow by using the premixed flow from the igniter (which has low NOx -exhaust gases). The aforementioned advantages are achieved with the burner according to the present invention as described with the features listed in the claims.

In the drawing, fig. 1 a side view of a gas turbine engine partly in cross-section, fig. 2 is an enlarged, detailed side view of a combustor portion of the gas turbine engine, FIG. 3 is a schematic view of the combined diffusion and premixing nozzle according to the invention.

With reference to fig. 1, a gas turbine 12 comprises a compressor 14, a burner 16 and a turbine 18 shown with a single blade. Although it is not specifically shown, it is known that the turbine is operated connected to the compressor along a common axis. The compressor compresses air which is then reversed or sent in the opposite direction to the burner because it is used to cool the burner and also to provide air to the combustion process. The gas turbine comprises several burners (one shown) which are placed around the circumference of the gas turbine. In a particular gas turbine model, there are fourteen such burners placed around the circumference of the gas turbine. A transition duct 20 connects the outlet end of this particular burner with the inlet end of the turbine to supply heat products from the burner process to the turbine.

The invention to be described is particularly useful in a two-stage, low-NOx, double burner of the type described in US 4,292,801. As described in that patent and shown in fig. 2 herein, each burner comprises a primary or upstream combustor 24 and a second downstream combustor 26 separated by a venturi throat area 28. The burner is enclosed by a burner flow sleeve 30 which channels the compressor air flow to the burner. The burner is further surrounded by an outer housing 31 which is bolted to the turbine housing 32.

Primary nozzles 36 supply fuel to the upstream burner 24 and are arranged in an annular array around a central secondary nozzle 38. In a gas turbine model, each burner may include six primary nozzles and one secondary nozzle. To complete the description of the burner, fuel is supplied to the nozzles through the tubes 42 in a well-known manner and is fully described in the previously mentioned patent. Ignition in the primary burner is caused by a spark plug 48 not shown in fig. 2 and in nearby burners by means of cross-ignition tubes 50 which are also

known.

In US 4 292 801 it is emphasized that the fuel nozzles, both primary and secondary, are identical to each other, i.e. that the nozzles are all of the diffusion type. With reference to the present fig. 2, a diffusion nozzle 36 comprises a fuel supply nozzle 54 and an annular swirl device 56. The nozzle 54 only delivers fuel which is then mixed with swirl air for combustion. According to the patent description, the secondary nozzle also becomes a diffusion nozzle, which will be described further.

During base load operation, the two-stage, dual burner is intended to operate in a premix position so that all primary nozzles simply mix fuel and air to be ignited by the diffusion flame maintained by the second or center diffusion nozzle. This premixing of the primary nozzle fuel and ignition of the secondary diffusion nozzle leads to less NOx emissions in the burner. However, there was one main drawback to the described system. For example, laboratory tests revealed that even if the least amount of fuel was used in the secondary nozzle to reduce NOx emissions under some operating conditions, the same amount of fuel in the secondary nozzle would not provide sufficient heat to satisfactorily burn the main combustion stream under other operating conditions.

Applicants have discovered that a satisfactory flash of the main premix stream from the upstream premix (primary) nozzles can be maintained by using minimal diffusion flash in combination with a central nozzle premix chamber. Thus, the invention reduces the proportion of the total fuel in the burner that burns as a diffusion flame (with large NOx emissions) while allowing sufficient heat supply to ignite the need for the mixture stream by using the premixed, secondary or control stream.

Therefore, according to the invention and with reference to fig. 2 and 3 show a combined diffusion and premix nozzle 100. The combined nozzle comprises a diffusion control part 62 with a fuel supply pipe 64. The fuel supply pipe has an axial pipe 66 and several radial, closed fuel distribution pipes 68 which extend radially outward from the axial pipe. In the preferred embodiment, there may be six such fuel distribution pipes. As can be seen from fig. 3, each fuel distribution pipe comprises several fuel outlet holes 70 which are directed downstream towards the outlet end of the combined nozzle. The fuel distribution holes are of such a size that the desired proportion of fuel flows into the premixing chamber, which will be described below.

The diffusion control part 62 further comprises an air supply pipe 74 coaxial with and surrounding the fuel supply axial pipe 66. The air supply into the air supply pipe is exhaust air from the compressor which is turned the other way around the burner into the space 76 formed by the flow sleeve 30 and the combustion chamber liner 78. The diffusion control part comprises at the outlet end a first vortex opening or diffusion control vortex device 82 which is to direct the outlet air from the air supply pipe towards the diffusion igniter.

A premixing chamber 84 is formed by a sleeve resembling a truncated cone 85 which encloses the diffusion control part and includes an outlet end (see the flow arrows) and which terminates near the outlet end of the diffusion control part. Discharge air from the compressor is also returned to the premix chamber from compartment 76 as for the air supply pipe. The radial fuel distribution pipes 68 extend through the air supply pipe 74 and into the premix chamber's annular opening so that fuel and air are mixed and delivered to another swirl device or premix chamber swirl device 86 between the diffusion control part and the premix chamber's truncated cone 85.

A third swirler or central nozzle swirler 90 is provided downstream from the outlet end of the combined diffusion and premix nozzle. This vortex device is placed between an extension or bowl 92 at the outlet end of the control part and the central body wall 95 for the primary combustion chamber. Compressor air is also led in the opposite direction towards this vortex device from the space 76 which encloses the combustion chamber liners. The purpose of this third vortex device is to achieve stability in the diffusion and premix nozzle flame in combination with the primary premix flow from the primary burner.

The necessary design of the vortex devices 82, 86 and 90 will be known from practice in combustion technology <p>g therefore does not necessitate any further description. The premixing chamber or truncated cone is formed by a suitable metal consumption with gas turbines. During the start-up phase, the fuel flow and combustion are initiated in the primary burner up to a certain medium load. At this point, the fuel f stream is divided between the primary nozzles and the secondary nozzle to achieve a desired load while ignition of the secondary nozzle is established. Fuel f flow to the primary nozzles is then terminated to extinguish combustion in the primary burner. The fuel flow is then re-established in the primary nozzles which then act as the main premixing chamber for the fuel flow from the primary nozzles while the second or center nozzle remains ignited and thus becomes an ignition flare for the primary main premix flow. At this point, a diffusion flame that uses approximately 20% of the total fuel flow would alone produce relatively large NOx exhaust gases.

With the combined diffusion and premix nozzle installed according to the invention, only about 2% of the total combustion flow is used to maintain the diffusion flame, which leads to a significant reduction in the emission of NOx. The remaining part of the fuel for the control part or the second nozzle is premixed in the premixing chamber and thus emits much less NOx. The invention in sum thus produces less NOx while at the same time opportunities are made to increase the fuel flow through the secondary nozzle due to less NOx emissions, while the rejection ratio or the ability to operate under varying conditions is significantly expanded due to the addition of the diffusion control part the premix flow for the control section rather than the total premix flow from surrounding primary nozzles.

Claims (4)

1. Combined diffusion and premix nozzle (100), comprising a diffusion control nozzle (62) with a fuel supply pipe (64) comprising an axial pipe (66) with an intake end and an outlet end, an air supply pipe (74) is arranged coaxially with and around the axial tube so that a first vortex-forming annulus (82) is formed between them, CHARACTERIZED IN THAT the fuel supply tube (64) comprises several radial fuel distribution tubes (68) which project outwards from the axial tube (66), extending behind the air supply tube (74) circumference and is arranged towards the intake end of the axial pipe, that a premixing chamber (84) surrounds the diffusion control nozzle (62) and comprises an intake end and an outlet end, the radial fuel distribution pipes (68) extending into the premixing chamber (84), that at least one fuel outlet hole (70) is arranged in at least one radial fuel distribution tube (68) and is directed towards the for-bi duck chambers ts (84) outlet end, and that a second ring-shaped vortex device (86) is arranged at the fo the outlet end of the mixing chamber, between the air supply pipe and the pre-mixing chamber (84). 2. Nozzle according to claim 1, CHARACTERIZED IN THAT the premixing chamber has a conical shape. 3. Combined diffusion and premixing nozzle (100) according to claims 1-2, arranged in the center of an annular distribution of several primary nozzles (36), CHARACTERIZED IN THAT it comprises a third vortex device (90) arranged between the combined nozzle (100) and a surrounding center wall (95). 4. Nozzle according to claim 3, CHARACTERIZED IN THAT a bowl (92) is arranged downstream of the combined nozzle (199) and the central wall (95) and that the third vortex device (90) is arranged between the central wall (95) and the bowl (92) .