RU2680026C1 - Burners block for annular combustion chamber with resonators - Google Patents

Abstract

FIELD: instrument engineering.SUBSTANCE: burner units with the defining annular combustion chamber comprises a housing with placed in the annular combustion chamber burners. Each burner is located in the provided in the housing through hole. In the through holes made in substantially sleeve-shaped form the burners receiving and leveling adapters are provided, which protrude inside the annular combustion chamber and on their located on the annular combustion chamber side ends, carry a protruding radially to the burners axes shielding plate. Shielding plate is equipped with through holes made concentrically with respect to through holes. Adapters are located on the ring between the essentially cylindrical outer shell of the annular combustion chamber and, essentially cylindrical and located on the hub side wall. Between the adapters and the outer shell or located on the hub side wall, as well as the housing and the shielding plate, a hollow space is formed. Shielding plate contains the resonator holes. In the hollow space dividing walls are located.EFFECT: invention allows to complement the burners block with burners of various sizes and enables damping of various frequencies.9 cl, 4 dwg

Description

The invention relates to a burner unit with a housing defining an annular combustion chamber and several burners flowing into the annular combustion chamber, each burner located in a through hole provided on the housing.

To damp vibrations that occur during operation in an annular chamber, at least one resonator is often provided, the volume of which is connected to the internal space of the combustion chamber to couple the vibrations arising from combustion. For these resonators, of course, an appropriate space for embedding should be prepared, as a result of which they are often placed on the wall of the combustion chamber in the compressor air flow branch and, if necessary, they must also be made with the corresponding aerodynamic shape.

This type of burner unit is already known in the art in various designs. As burners, it is possible to use, for example, systems with stabilization of turbulences. New developments of burner systems based on a pre-mixed reactive flame due to the absence of turbulence induced by turbulence create advantages compared to systems with stabilization of turbulence due to the absence of turbulence induced by turbulence, in particular, from the point of view of thermoacoustics, and for this reason they are more and more focused when choosing the type burners. These new type burners often have external dimensions that differ from the external dimensions of the burners used before. Therefore, to ensure the possibility of completing the existing block of burners with burners having different external dimensions, a new design or coordination of the housing defining the annular combustion chamber is necessary.

The objective of the invention is to provide an alternative burner unit, which can be easily equipped with burners with different sizes and ensures good use of the space for installation. A further object of the invention is to indicate an appropriate annular combustion chamber.

In accordance with the invention, the problem is solved due to the fact that in the case of a burner block with a housing defining an annular combustion chamber and several burners flowing into the annular combustion chamber, each burner is located in a through hole provided in the housing, and mainly provided through holes in the form of sleeves, receiving and leveling burners, transitional devices that protrude inside the annular combustion chambers and on their annular measures of combustion at the ends hold a shielding plate extending radially relative to the axis of the burners, which is equipped with through holes made concentrically relative to the through holes, and the transition devices are located on the ring between the approximately cylindrical outer shell and the approximately cylindrical and located on the side of the hub wall, as a result between the transition devices and the outer shell or the wall located on the side of the hub, as well as the housing and screens uyuschey plate is formed by a hollow space, the screening device comprises a resonator plate and in the hollow space disposed dividing walls.

Using this unit, with the help of transitional devices, burners with different external dimensions can be fixed. At the same time, the free space around the transition devices is used as a resonator. Depending on the choice of position of the separation walls, various frequencies can be suppressed.

In a preferred embodiment, the partition walls extend from the housing to the shield plate. Due to this, the useful use of the total depth of the hollow space for the resonator is achieved.

In the following preferred embodiments, at least one wall extends radially outward from the adapter to the outer shell or from the adapter radially inward to the wall located on the side of the hub. Due to this, it is possible, on the one hand, to distinguish between subspaces in hollow space, which, depending on the choice of a certain volume, quench the corresponding frequencies. Further, the connection of the transition devices and the outer shell or the wall located on the side of the hub leads to increased rigidity of the system and, thereby, to a further positive effect on the impeccability or service life of structural elements based on changes in natural frequencies.

In a further preferred embodiment, the interleaving alternating devices on the perimeter comprise in one case radial dividing walls in the outer direction to the outer shell and inwardly to the wall located on the side of the hub, and in the other case do not contain radial dividing walls. Due to this, a sufficiently large volume of the resonator is determined.

In an alternative embodiment, at least one dividing wall extends from the adapter in the circumferential direction to the adjacent adapter. Advantageously, one dividing wall extends between all the transition devices in the circumferential direction. Thus, two large cavity spaces can be defined, one in the direction of the outer shell and one in the direction of the hub, which, if necessary, can be further separated by radial dividing walls.

It may be preferable when the dividing walls contain holes, due to which the formed resonator spaces can interact with each other.

Also, the problem is solved using a gas turbine with a burner unit in accordance with the invention.

The invention is explained in more detail as an example based on the drawings. The drawings show the following:

FIG. 1 - gas turbine in longitudinal section,

FIG. 2 is a section of a burner block with an annular combustion chamber,

FIG. 3 is a cross section of an annular combustion chamber with a transition device,

FIG. 4 - a hollow space formed by transitional devices on an annular combustion chamber with an outer shell and a wall located on the side of the hub.

FIG. 1 shows, in a schematic simplified representation, a sectional view of a gas turbine 17. The gas turbine 17 comprises in its interior a rotor 19 with a shaft 20, which is also rotatably rotatable around the axis of rotation 18, with a shaft 20, which is also called a turbine impeller. Along the rotor 19, a suction casing 21, a compressor 22, a combustion system 23 with a burner unit 1 with a housing 3 defining an annular combustion chamber 2 and several burners 4, a fuel supply system (not shown) for the burners, a turbine 24 and an exhaust gas housing 25 alternately follow.

At the turbine inlet, the combustion system 23 flows into an annular channel of hot gas through which the hot working gas of the combustion system flows to successive stages of the turbine 24. Each stage of the turbine is formed by the rim of the blades. When looking in the direction of flow of the working gas in the hot gas channel, the row formed by the working blades 27 is next to the formed guide vanes 26. In this case, the guide vanes 26 are mounted on the inner housing of the stator 28, in contrast to which the working vanes 27 of one row are placed, for example, using the turbine disk on the rotor 19. To the rotor 19 is connected, for example, a generator (not shown).

During operation of the gas turbine 17, the compressor 22 draws air through the suction body 21 and compresses it. Prepared at the end of the compressor 22 located on the turbine side, the compressor air is directed along the cascade 29 of burners to the combustion system 23 and in it is directed to the burner block 1 and in the burners 4 of the burner block 1, it is mixed with fuel and / or enriched with fuel in the outlet region of the burners 4. In this case, the fuel supply systems supply burners 4 with fuel. The mixture or compressor air and fuel are introduced via burners 4 into the combustion chamber 2 and burned to produce a hot working gas stream in the combustion zone inside the wall of the combustion chamber or outer shell 11 of the combustion chamber 2. From there, the working gas stream flows along the hot gas channel past the guide vanes 26 and the working vanes 27. On the guide vanes 27, the pressure of the working gas stream is released to transmit a pulse, as a result of which the working vanes 27 drive the rotor 19, and the latter drives the connected a generator to it (not shown).

FIG. 2 shows in section a block 1 of burners with an annular combustion chamber 2. The annular combustion chamber 2 is defined by the housing 3. Further, FIG. 1 shows one of several burners 4 flowing into the annular combustion chamber 2, wherein the illustrated burner 4 is located in a through hole 5 provided in the housing 3 (see also FIG. 3).

In the through holes 5 are provided mainly made in the form of sleeves, receiving and leveling burners 4 transition devices 6, which protrude inside the annular combustion chamber 2 and at their ends 7 located on the side of the annular combustion chamber carry a shielding plate 9 extending radially to the axes of the burners 8, which equipped with through holes 10 made concentrically with respect to the through holes 5. This is particularly clearly shown in FIG. 3.

Finally, FIG. 4 shows that the transitional devices 6 are located on the ring between the approximately cylindrical outer shell 11 and the approximately cylindrical and located on the side of the hub wall 12, as a result of which between the transitional devices 6 and the outer shell 11 or located on the side of the hub wall 12, as well as the housing 3 and a shielding plate 9 defines a hollow space 13, see also FIG. 3. In FIG. 3 also shows resonator holes 14 in the shield plate 9. FIG. 4 shows, in turn, the dividing walls 15 located in the hollow space 13, which extend from the housing 3 of the annular combustion chamber 2 up to the shield plate 9.

Along with this fundamental orientation between the housing 3 and the shielding plate 9, the separation walls 15 can pass both radially from the adapter 6 to the outer shell 11 or from the adapter 6 to the wall 12 located on the side of the hub, and in the circumferential direction, in particular between adjacent transition devices 6.

FIG. 4 shows a preferred embodiment of the invention in which the transition devices 6 alternating on the perimeter comprise in one case radial dividing walls 15 extending outwardly to the outer shell 11 and inwardly to the wall 12 located on the side of the hub, and in the other case not containing radial dividing walls. Additionally, between all the transition devices 6 in the circumferential direction passes the separation wall 15.

As follows, further from FIG. 4, the partition walls 15 may optionally include holes 16.

Claims (9)

1. A burner unit (1) with a housing (3) defining an annular combustion chamber (2) and several burners (4) flowing into the annular combustion chamber (2), each burner (4) located in a through hole provided in the housing (3) (5), and in the through holes (5), receiving and leveling burners (4) made essentially in the form of sleeves are provided, transition devices (6) that protrude inside the annular combustion chamber (2) and are carried on their annular side combustion chamber ends (7) extending radially to the axes (8) the burner has a shielding plate (9) that is equipped with through holes (10) made concentrically relative to the through holes (5), and wherein the transition devices (6) are located on the ring between the substantially cylindrical outer shell (11) of the annular chamber (2) combustion and a substantially cylindrical wall located on the side of the hub (12), while between the transition devices (6) and the outer shell (11) or located on the side of the hub wall (12), as well as the housing (3) and a shielding plate (9) is formed hollow space (13), characterized in that the shielding plate (9) contains resonator holes (14) and dividing walls (15) are located in the hollow space (13). 2. Block according to claim 1, characterized in that the dividing walls (15) extend from the housing (3) up to the shield plate (9). 3. The block according to claim 1 or 2, characterized in that at least one dividing wall (15) extends radially outward to the outer shell (11). 4. Block according to any one of paragraphs. 1-3, characterized in that at least one dividing wall (15) extends from the adapter (6) radially inward to the wall (12) located on the side of the hub. 5. A unit according to claim 3 or 4, characterized in that the transition devices (6) with alternation on the perimeter contain in one case radial dividing walls (15) directed outward to the outer shell (11) and inward to the wall located on the side of the hub (12), and in another case do not contain radial dividing walls (15). 6. Block according to any one of paragraphs. 1-5, characterized in that at least one dividing wall (15) extends from the transition device (6) in the circumferential direction to the adjacent transition device (6). 7. Block according to claim 6, characterized in that a dividing wall (15) extends between all the transition devices (6) in the circumferential direction. 8. Block according to any one of paragraphs. 1-7, characterized in that the dividing walls (15) contain holes (16). 9. A gas turbine (17) containing a block (1) of burners according to any one of paragraphs. 1-8.

Images