EP2470833A2

EP2470833A2 - Swirl blade, burner and gas turbine

Info

Publication number: EP2470833A2
Application number: EP10749630A
Authority: EP
Inventors: Andreas Böttcher; Mariano Cano Wolff; Andre Kluge; Tobias Krieger; Sascha Staring; Ulrich Wörz
Original assignee: Siemens AG
Current assignee: Siemens AG
Priority date: 2009-08-26
Filing date: 2010-08-23
Publication date: 2012-07-04
Also published as: RU2535433C2; WO2011023648A2; CN102906500B; CN102906500A; WO2011023648A3; DE102009038845A8; RU2012111257A; DE102009038845A1

Abstract

The invention relates to a swirl blade (19) comprising a first gas nozzle set (21) and a further additional second gas nozzle set (23). Said nozzles (21) are fed by a first distributor pipe (61) and the nozzles (23) by a second distributor pipe (65), the distributor pipe (61, 65) being integrated into the swirl blade (19) which is embodied as two blade halves (19a, 19b) separated between the first distributor pipe (61) and the second distributor pipe (65). The invention also relates to a burner and a gas turbine.

Description

description

Swirl Blade, Burner and Gas Turbine The present invention relates to a swirl blade, in particular for the burner in a gas turbine. In addition, the invention relates to a burner and a gas turbine.

In view of the global efforts to reduce pollutant emissions from firing systems, particularly in gas turbines, burners have been developed in recent years that have particularly low emissions of nitrogen oxides (NOx). In the process, it is often emphasized that such burners can be operated either selectively or in combination not only with one fuel, but also with different fuels, for example oil and natural gas, in order to increase the supply reliability and flexibility of the operation. Such burners are for example in the

EP 0 276 696 B1.

The burner described in EP 0 276 696 B1 is a hybrid burner for premixing operation with gas and / or oil, as it is used in particular for gas turbine plants. The burner comprises a central fuel supply arrangement, in which also a pilot burner system is integrated, which is operable with gas and / or oil as a so-called diffusion burner or as a separate premix burner. In addition, the possibility for feeding in inert materials is provided. The central fuel supply assembly is surrounded by a main burner system having an air supply annular channel system with a swirler blading therein having a plurality of vanes and pre-mixing gas nozzles located upstream of the vanes. In addition, inlet nozzles for oil in the area of the swirl vanes are present in the fuel supply arrangement, which allow premixing of the main air flow with oil. Instead of EP 0 276 696 B1 by means of nozzle tubes located upstream of the swirl vanes, the fuel gas can also be injected into the air duct through nozzle openings arranged in the swirl vanes themselves, as described, for example, in EP 0 580 683 B1.

In order to increase the control of emissions and combustion stability in the future, in addition to a gas injection by the blade, as in EP 0 580 683 B1, a further gas injection through the blade should be used. This additional gas injection should be controllable separately from the main gas stage, i. In addition to the previously existing gas and oil channels, an additional, second gas channel must be introduced into the central fuel supply device of the burner. One difficulty now is that the swirl blade with the additional gas channel meets the necessary strength criteria, while having a long life. Object of the present invention is therefore to provide an advantageous swirl vane with a first gas injection and a further additional second gas injection available. It is a second object of the present invention to provide an advantageous burner. Another object is to provide an advantageous gas turbine.

The first object is achieved by a burner according to claim 1, the second object by a burner according to claim 8 and the further object by a gas turbine according to claim 9. The dependent claims contain advantageous embodiments of the invention.

In this case, such a swirl blade according to the invention has a first gas injection and a further additional second gas injection, wherein the first nozzles are fed by a first manifold and the second nozzles from a second manifold, wherein the manifold in the swirl Schaufei is integrated. The swirl vane and the fuel supply assembly, which supplies fuel or a fuel mixture to the distribution pipes, have a fuel flow direction.

According to the invention, it has been recognized that, if the blade introduction are carried out the same way in the lower and in the upper region, as it were, a double fit is created. Thus, adjustment of the blade orientation via the one fulcrum would also be desirable. by means of existing shims no longer possible. Due to several injection axes and the double fit no real fulcrum is now available.

According to the invention, therefore, the swirl blade between the first distributor tube and the second distributor tube is designed divided into two blade halves.

This has the advantage that the blade or the two

Shovel halves can now be adjusted in their orientation again on the shims. In addition, a separate fuel control via both independent distribution pipes is possible. Also, the split blade is simple and cheaper to manufacture. During operation, the two blade halves preferably have a flow direction and are connected upstream to a first and a second fuel distributor channel, wherein the first and the second fuel distributor channel is arranged in a central fuel supply arrangement. The swirl vane halves are arranged in an annular air channel for supplying combustion air.

Thus, in the first manifold, the fuel from the first fuel distribution channel; In the second manifold of the fuel from the second fuel distribution channel are injected independently. Thus, a different "staging" of the fuel of the fuel distributor channels and thus the swirl vane halves is possible. de when switching between full load and partial load or when rinsing beneficial because this way a completely separate fuel supply to a thermal stresses can be avoided and on the other hand switching can be accomplished much faster.

Preferably, the swirl vane halves are disposed in an annular air passage for supplying combustion air surrounding the central fuel supply assembly, wherein the first fuel nozzles are fed from a first fuel distributor feed in the fuel supply assembly and the second fuel nozzles are fed from a second fuel distributor channel in the fuel supply assembly. In a preferred embodiment, furthermore, the fuel distributor feed comprises a flow direction and a feed pipe, which is connected downstream to one of the swirl vane halves and a ring attachment, wherein the supply pipe is connected upstream with the ring attachment, the ring attachment being upstream of the fuel distribution channel.

Preferably, both blade halves have a fitting pin downstream and an associated sliding seat upstream. In this case, the sliding seat projects upstream into the fuel supply arrangement at least partially. In this case, the two blade halves are preferably only inserted into the fitting pins. Thus, a thermal expansion of both blade halves is possible. Thermal stresses can thus be avoided. The life of the split swirl blade and thus of the entire burner is thereby substantially increased.

In an advantageous embodiment, the two blade halves each have a nut with which the blade halves are tightened against the downstream boundary wall. Such a swirl blade is preferably provided in a burner. In a preferred embodiment, the burner is further provided in a gas turbine. Further features, properties and advantages of the present invention will become apparent from the following description of embodiments with reference to the accompanying figures. Show in it

2 shows a schematic diagram of a combustion chamber hub with two gas stages and an oil channel, FIG.

3 shows a schematic representation of a swirl blade with

two gas levels,

4 shows a schematic representation of a split swirl blade according to the invention (cross section through the

5) in the hub, FIG. 5 shows a schematic diagram of a split swirl blade according to the invention (top view) in the hub,

6 shows a cross-section of a combustion chamber hub according to the invention with a ring attachment and split spin view, FIG.

7 shows a plan view of a ring attachment with divided

Swirl blade. In the following, the concept underlying the burner is described with reference to FIG. 1, which shows a burner according to the invention in a highly schematic diagram. The burner according to the invention, which can optionally be used in conjunction with a plurality of similar burners, for example in the combustion chamber of a gas turbine plant, comprises an inner pilot burner system and a main burner system concentrically surrounding the pilot burner system. Both the pilot burner system and the main burner system may optionally be operated with gaseous and / or liquid fuels, such as natural gas or fuel oil. The pilot burner system includes an inner oil supply passage 1 concentrically surrounded by an inner annular gas supply passage 3. This is in turn surrounded by an inner air supply channel or Inertstoffzufuhrkanal 5 concentrically. In addition, a suitable ignition system may be arranged in or on this air supply channel (not shown in the figure). The pilot burner system has a combustion chamber 7 zuwerende outlet opening 9, in whose area a twist blading 11 is arranged in the air supply channel. By means of nozzle openings 13, gas from the inner Gaszufuhr- channel 3 in the field of swirl blading or upstream of the

Swirl blading be injected into the air supply channel 5. Oil from the oil supply channel can be injected by means of oil nozzles 15 downstream of the swirl blading into the supplied air or the supplied inert material.

The pilot burner system can be operated in a conventional manner with oil and / or gas as a diffusion burner, in which the fuel is injected directly into the flame. However, it is also possible to operate the pilot burner system as a premix burner, in which the fuel is thoroughly mixed with air before the mixture is fed to the flame.

The main burner system surrounding the pilot burner system comprises a radial outer air supply channel 17, also called an annular air channel, through which several swirl vanes 19 of a swirl blading extend. These swirl vanes 19 have first gas nozzles 21 and second gas nozzles 23, through the fuel gas can be injected into the air flowing through the radial air supply channel 17 air. In the air flowing through the air supply channel 17 air can also be injected by means of oil nozzles 25 oil. Although oil and oil nozzles are mentioned in the present exemplary embodiment, this should only be representative of suitable liquid fuels and corresponding nozzles.

The first gas nozzles 21 and second gas nozzles 23 located in the swirl vanes 19 and the oil nozzles 25 are supplied with fuel via a radially inner fuel supply arrangement, the so-called hub 27. In this first and second annular gas distribution channels 29 and 31 are arranged, which supply the gas nozzles 21 and 23 with gas. The

Swirl vanes 19 and the fuel supply arrangement have a fuel flow direction 100. Furthermore, in the hub 27, an annular oil distribution channel 33 is arranged, which supplies the oil nozzles 25 with oil. The gas distribution channels 29, 31 and the oil distribution channel 33 are supplied via Gaszufuhrka- channels 35, 37 or via an oil supply channel 39 with the appropriate fuel. The gas supply channels 35, 37 supply the gas distribution channels 29, 31 with fuel. For the oil supply channel 39 is a separate oil supply pipe 43 before. Figure 2 shows a fuel hub 27 with the fuel distribution channel 29 and 31 with openings, which leads the fuel into the blade 19. The two fuel distribution channels 29 and 31 are arranged substantially parallel and separated by a web 50.

FIG. 3 shows a schematic representation of a swirl blade 7 with two integrated gas stages B and D, which can be controlled independently of one another. The swirl blade 19 has two gas distributor channels 29 and 31 which are independent of each other. The one gas distribution channel 29 with the outlet nozzles 21, for example, for injecting a different medium of the medium D than the second gas distribution channels 31 via the outlet nozzles 23 (medium B) are used. Preferably, both media to be injected through the gas distribution channels 29 and 31 of the swirl vane 19 will be gaseous, eg, the one natural gas and the other coal gas. Likewise, via these outlet nozzles 21 and / or 23 as needed

Inertstoff such as water vapor are injected.

According to the invention, it has been recognized that two double fits 51 are created in the upper and lower region with a double, identical embodiment of the blade injection, which means that the blade 19, in particular the blade alignment, can no longer have these fits 51, which may comprise at least one adjustment disk , are adjustable. This results from the fact that now no fulcrum (pivot) longer exists. It can be seen as a fulcrum, especially the Eindüseachse. Due to several Eindüseachsen and the double fit thus no more pivot point is available.

The swirl blade 19 is configured with a first gas injection 21 and a further additional second gas injection 23. In this case, the nozzles 21 are fed by a first distributor pipe 61 and the nozzles 23 by a second distributor pipe 65, wherein the distributor pipe 61, 65 is integrated in the swirl blade 19.

According to the invention, the swirl blade 19 between the first distributor pipe 61 and the second distributor pipe 65 is divided into two blade halves 19a, 19b (FIG. 4). This has the advantage that the injections via the injection ports 21 and 23 are separately controllable. Thus, a different "staging" is possible, and thus the channels 31 and 29 are separately controllable, which also has an advantageous effect on the service life, since the two channels 31 and 29 are now also controlled with regard to their thermal loads This is especially true when changing from

Part load on full load and vice versa advantageous. Also, a split blade 19a, 19b is much faster and less expensive to manufacture than a double-action blade 51. In addition, adjustment of the blade alignment of the two blade halves 19a, 19b via the shims is possible. The blade halves 19a, 19b also have at the outer boundary wall 17b of the air supply channel 17 a fit, that is, a so-called fitting pin 90a, 90b and a sliding seat 85a, 85b, which is mounted so to speak in the hub 27 itself. By means of the locating pins 90a, 90b and the sliding seat 85a, 85b, the two blade halves 19a, 19b are now thermally separately expandable, which also reduces stresses. At the outer boundary wall 17b of the air supply channel 17, the two blade halves 19a, 19b are tightened against the outer boundary wall 17b with a nut 86a, 86b (FIG.

Also, the hub 27 may include a supply tube 55 (FIGS. 6 and 7) connected downstream to one of the swirl vane halves 19 a (19 b) and a ring cap 60, with the supply tube 55 connected upstream to the ring cap 60, where Ring attachment 60 seen in the flow direction 100 seen the fuel distribution channel 31 (alternatively 29) is connected upstream. Thus, virtually one of the distribution channels 29 and 31 is formed as a feed tube 55.

The feed tube 55 discharges downstream into a manifold 61 (or alternatively 65). Upstream, the feed tube 55 is connected to the ring attachment 60. In this case, the ring attachment 60 is seen in the flow direction of the fuel distribution channel 31 (or alternatively 29) upstream. Thus, virtually the original fuel distribution channel 31 (or alternatively 29) is parallel to the supply pipe 55. The ring attachment 60 is supplied with a separate pipe connection 75. The original fuel distributor channel 31 (or alternatively 29) is supplied with another channel 80. Thus, the two leading gas passages, namely the feed tube 55 with the ring attachment 60 and the original fuel distribution channel 31 (or alternatively 29) according to the invention spatially decoupled. Of the Ring attachment 60 acts to pull the high stresses out of hub 27 and distribute them evenly over the component. This results in a defusing of the installation space due to lower voltages.

In order to obtain an additional voltage reduction, the web 50, through which the fuel distribution channel 31 (or 29) and the supply pipe 55 are separated, may be made flexible. The web 50 can be made of an elastic material. Additionally or alternatively, the web 50 can also act elastically by a corresponding geometry and thus compensate for stresses. This can e.g. be effected by a curved or corrugated web 50.

Claims

claims

A swirl vane (19) having a first gas injection (21) and a further additional second gas injection (23), the first nozzles (21) being fed by a first manifold (61) and the second nozzles (23) by a second manifold (65), wherein the manifold (61, 65) is integrated in the swirl blade (19),

That is, the swirl vane (19) between the first manifold (61) and second manifold (65) is divided into two vane halves (19a, 19b).

2. swirl blade (19) according to claim 1

The two vane halves (19a, 19b) are separately manufacturable.

3. swirl blade (19) according to claim 1 or 2,

characterized in that the swirl vane halves (19a, 19b) are disposed in an annular air passage (17) for supplying combustion air and in operation have a flow direction (100) and connected upstream to a first fuel manifold (29) and a second fuel manifold (31), respectively are, wherein the first and the second fuel distribution channel (29, 31) in a central fuel supply arrangement (27) is arranged.

4. swirl blade (19) according to claim 1 or 2,

characterized in that the swirl vane halves (19a, 19b) are disposed in an annular air passage (17) for supplying combustion air surrounding the central fuel supply assembly (27), the first fuel nozzles (21) being provided by a first fuel distributor feed (29) in the first fuel distributor Fuel supply arrangement (27) are fed and the second fuel nozzles (23) from a second fuel distribution channel (31) in the fuel supply arrangement (27) are fed.

5. swirl blade (19) according to claim 4

characterized in that the fuel distributor feed (29) has a flow direction (100) and comprises a supply pipe (55) which is connected downstream to one of the swirl vane halves (19a, 19b) and a ring attachment (60), wherein the supply pipe (55) upstream with the ring attachment (60) is connected, wherein the ring attachment (60) seen in the flow direction upstream of the fuel distribution channel (31).

6. swirl blade (19) according to any one of claims 2 to 5, d a d u r c h e c e n e c e s e, e s both vane halves (19 a, 19 b) downstream of a fitting pin (90 a, 90 b) and upstream a sliding seat (85 a, 85 b) have.

7. swirl blade (19) according to claim 6,

For example, the sliding seat (85a, 85b) projects at least partially upstream into the fuel supply arrangement (27).

8. swirl blade (19) according to one of the preceding claims 2 to 7,

The two vane halves (19a, 19b) each have a nut (86a, 86b) with which the vane halves (19a, 19b) can be tightened against the downstream boundary wall (17b) of the annular air duct (17).

9. Burner with a swirl blade (19) according to one of the preceding claims.

10. Gas turbine with at least one burner according to claim 9.