EP2182285A1 - Burner insert for a gas turbine combustion chamber and gas turbine - Google Patents

Abstract

The burner insert (41) comprises a burner insert wall (42) with a cold side (43) and a hot side, and an edge (46) limiting the burner insert wall. A burner opening for inserting a burner is formed in the burner insert wall. The edge has an edge bar (51) projecting partially over the cold side in a circumferential manner. Independent claims are included for the following: (1) a gas turbine combustion chamber with a combustion chamber wall; and (2) a gas turbine with a cooling fluid reservoir.

Description

The present invention relates to a combustor liner for a gas turbine combustor having a burner port for inserting a combustor. In addition, the invention relates to a gas turbine.

Gas turbine combustors have a burner-side end and a turbine-side end. The turbine-side end is open and allows outflow of combustion gases in the hot combustion gases to the turbine. At the burner end is often a burner insert is present, which has a heat-resistant hot side and a cooled cold side. The burner is inserted into an opening of the burner insert. During operation of the gas turbine, cooling air, which usually comes from the compressor, flows along the cold side from the burner opening of the burner insert to its outer edge, from where the cooling air flows into the combustion chamber. An example of a burner insert in a tube combustion chamber is in US 2005/0016178 A1 described.

In the case of annular combustion chambers, that is to say of combustion chambers which extend annularly around the turbine rotor, a multiplicity of combustion inserts in the circumferential direction of the annular combustion chamber are usually arranged next to one another. The cooling air flowing past the cold side of the burner side then flows into the combustion chamber between the radially outer wall and the radially inner wall of the combustion chamber. In addition, cooling air can also be introduced into the combustion chamber by gaps between circumferentially adjacent combustion inserts. Such an annular combustion chamber is, for example, in EP 1 557 607 A1 described. Alternatively, it is also possible to direct the cooling air away from the burner opening of the burner insert towards the burner opening and then through an annular gap between the edge of the burner opening and the burner used to be introduced into the combustion chamber, as in EP 1 767 855 A1 is described.

A burner insert for an annular combustion chamber is shown schematically in FIG FIG. 1 shown. The figure shows a burner insert for an annular combustion chamber in a cut perspective view on its cold side 103. In the center of the cold side 103 of the burner insert 100 is an opening 105 into which the burner can be used. The burner insert is fastened by means of an annular ridge 107 in a cold side projecting portion 109 of the burner insert 100 to a support structure in the gas turbine housing.

During operation of the gas turbine combustor, this can lead to pressure fluctuations, which can stimulate the burner insert to high-frequency oscillations. These burden the burner insert and shorten its service life. In order to stiffen the burner insert and to guide the cooling air, the cold side 103 of the burner insert 100 is provided with ribs 111. In addition, support screws 113 are present, which in FIG. 1 are indicated only schematically. The screws 113 and the ribs 111 represent support sections, with which the cold side comes to rest on the support structure in the gas turbine housing. In such a burner inserts, it may lead to the formation of a non-uniform gap along the peripheral edge of the burner insert, which can lead to an oversupply of cooling air in places with increased gap. In addition, this is due to the fact that in addition to the ribs 111 and the support bolts 113 are present, a static overdetermination, since the burner insert 100 is to rest on the screws except at the same time on the ribs 11.

Compared to this prior art, it is an object of the present invention to provide an advantageous burner insert for a gas turbine combustor available. Another The object is to provide an advantageous gas turbine combustion chamber and an advantageous gas turbine available.

The first object is achieved by a burner insert according to claim 1, the second object by a gas turbine combustion chamber according to claim 9 and a gas turbine according to claim 13. The dependent claims contain advantageous embodiments of the invention.

An inventive burner insert for a gas turbine combustor has a burner insert wall with a cold side and a hot side. In the burner insert wall, a burner opening for inserting a burner is formed. The burner insert has an outer edge delimiting the burner insert wall with an at least partially encircling edge web projecting over the cold side. The edge may in this case be substantially circular, for example in the case of a tube combustion chamber, or, for example in the case of an annular combustion chamber, have the shape of the edge of a circular ring cutout. Other contours are basically possible depending on the shape of the combustion chamber.

The edge web of the burner insert according to the invention leads to an increase in the natural frequencies in comparison to a burner insert according to the prior art, as with reference to FIG. 1 has been described. The vibration load of the burner insert during operation of the combustion chamber is therefore reduced in comparison to the burner insert from the prior art. In addition, during operation of the gas turbine combustor, the edge web can rest completely on the support structure in the gas turbine housing, so that a uniform gap, preferably a zero gap, is present along the entire edge. In order not to interrupt the cooling air flow in the presence of a zero gap, the edge web is to be provided in an embodiment of the invention with openings for the passage of cooling fluid. For realizing the openings, the edge web may have crenels between which the openings are formed, and / or with through-holes, for example Holes, be equipped. Due to the fact that defined openings in the edge web can be produced by means of the battlements or holes, an exact adjustment of the amount of cooling air passing through the edge web is possible by suitable choice of the pebble size or the free diameter of the holes. In the case of battlements, these can be generated, for example, by interrupting the edge web. It is advantageous, however, if the edge web is not interrupted and, instead, the edge web projects further in the crenellated areas over the cold side than in the remaining regions of the edge web. In addition to the openings described also other forms of openings are conceivable, for example. Slots.

Preferably, the edge web runs around the entire edge of the burner insert. The rigidity of the edge of the burner insert is then particularly high.

In a particular embodiment of the burner insert according to the invention the burner opening is surrounded by an annular, over the cold side projecting and provided with an annular web wall portion. Otherwise, the burner insert wall is formed flat, d. H. There are no other structures, such as the existing in the art ribs. In the case of the burner insert according to the invention such ribs are superfluous, since it has been shown that a uniform distribution of the cooling air takes place even without such ribs. Also, a stiffening function of the ribs is not needed in the burner insert according to the invention.

Overall, the burner insert according to the invention makes it possible to save cooling air, since no uneven gap dimensions occur, which can lead to an oversupply in the cooling air supply. The reduced supply of cooling air into the combustion chamber results in a reduced pollutant emissions of the gas turbine and higher turbine inlet temperatures, which in turn allows an increase in efficiency of the gas turbine. In the case of openings in the edge gap, for example. In the form of battlements or through holes, can also by a suitable choice of the opening cross sections, the amount of cooling air flowing into the combustion chamber can be set in a defined manner. In addition, the setting of a zero gap between the end face of the edge web or the pinnacles and the support structure or the combustion chamber wall is possible. Finally, the design of the burner insert according to the invention also enables a cost reduction, since the stiffening screws are eliminated and therefore fewer components are required in comparison to the burner insert described in the introduction.

A gas turbine combustor according to the invention has at least one burner, at least one combustion chamber wall surrounding a combustion chamber interior, and at least one burner end wall on the burner side. It comprises a burner insert according to the invention whose burner insert wall forms the combustion chamber end wall, the hot side of the burner insert wall facing the combustion chamber interior. In the combustion chamber according to the invention, the combustion chamber wall may be cylindrical in the case of a tube combustion chamber. In the case of an annular combustion chamber, however, two combustion chamber walls are present, namely a radially outer and a radially inner combustion chamber wall.

The achievable with the burner insert advantages of the invention can thus be realized in the gas turbine combustor according to the invention.

In the gas turbine combustor according to the invention, a gap may be present between the combustion chamber closure wall formed by the at least one burner insert and the at least one combustion chamber wall, which allows the outflow of cooling air from the cold side of the combustion insert into the combustion chamber.

In the case of a gas turbine combustor designed as an annular combustion chamber with an annular combustion chamber formed between an inner combustion chamber wall and an outer combustion chamber wall Combustor interior, the burner-side combustion chamber end wall can be formed in particular by a number in the circumferential direction of the combustion chamber juxtaposed burner inserts. There may be gaps between adjacent burner inserts which allow the flow of cooling air between the burner inserts into the annular combustion chamber.

A gas turbine according to the invention is equipped with at least one gas turbine combustion chamber, which is designed as a gas turbine combustion chamber according to the invention. In addition, the gas turbine according to the invention comprises a cooling fluid reservoir, for example a combustion chamber plenum communicating with the output of a compressor, wherein the cold side of the burner insert wall is fluidically connected to the cooling fluid reservoir. Such a gas turbine makes it possible to realize the advantages of a combustion chamber with burner insert according to the invention.

Further features, properties and advantages of the present invention will become apparent from the following description of an embodiment with reference to the accompanying figures.

FIG. 1 shows a burner insert according to the prior art.

FIG. 2 shows a gas turbine in a longitudinal section.

FIG. 3 shows an annular combustion chamber in a partially sectioned perspective view.

FIG. 4 shows a burner insert according to the invention.

FIG. 5 shows the edge of the burner insert FIG. 4 ,

FIG. 6 shows the edge of the burner insert in a detailed view.

FIG. 7 shows the edge of a modified burner insert in a detailed view.

FIG. 2 shows a gas turbine 1 in a longitudinal section. This comprises a compressor section 3, a combustion chamber section 5 and a turbine section 7. A shaft 9 extends through all sections of the gas turbine 1. In the compressor section 3, the shaft 9 is provided with rings of compressor blades 11 and in the turbine section 7 with rings of turbine blades 13. Wreaths of compressor guide vanes 15 are located between the rotor blade rings in the compressor section 3 and rings of turbine guide vanes 17 in the turbine section 17. The guide vanes extend from the housing 19 of the gas turbine installation 1 essentially in the radial direction to the shaft 9.

During operation of the gas turbine 1, air 23 is sucked in through an air inlet 21 of the compressor section 3 and compressed by the compressor rotor blades 11. The compressed air is supplied to a combustion chamber 25 arranged in the combustion chamber 25, which is configured in the present embodiment as an annular combustion chamber, into which a gaseous or liquid fuel via at least one burner 27 is injected. The resulting air-fuel mixture is ignited and burned in the combustion chamber 25. Along the flow path 29, the hot combustion exhaust gases flow from the combustor 25 into the turbine section 7, where they expand and cool, imparting momentum to the turbine blades 13. The turbine guide vanes 17 serve as nozzles for optimizing the momentum transfer to the rotor blades 13. The rotation of the shaft 9 brought about by the momentum transfer is used to drive a load, for example an electric generator. The expanded and cooled combustion gases are finally discharged from the gas turbine 1 through an outlet 31.

The annular combustion chamber 25 of in FIG. 2 shown gas turbine is in FIG. 3 shown in a perspective, partially cutaway view. Both the outer combustion chamber wall 33 and the inner combustion chamber wall 35 are provided with a hot gas-resistant lining, which is formed from heat shield elements 37. As heat shield elements in the present embodiment, ceramic heat shield elements are used. The turbine section 7 facing the end of the combustion chamber has a hot gas outlet opening 39, through which the resulting inside the combustion chamber 25 hot combustion gases can flow to the turbine. At the hot gas outlet 39 opposite end of the annular combustion chamber 25 is formed from burner inserts 41 Brennkammerabschlusswand available. In each burner insert 41, a burner 27 is received. The burner inserts 41 are in this case not directly connected to the outer combustion chamber wall 33 and the inner combustion chamber wall 35, but arranged on a support structure (not shown), which in turn is attached to the housing of the gas turbine. Between the individual burner inserts 41 on the one hand and the outer wall 33 and the inner wall 35 on the other hand remains a gap which allows the inflow of cooling air along the respective wall into the interior of the combustion chamber. In addition, the burner inserts 41 are arranged so that between them, ie between circumferentially adjacent edges of the burner inserts 41, remain gaps that allow the entry of cooling air into the combustion chamber interior.

A burner insert is in FIG. 4 shown in a partially cut perspective view. It comprises a burner insert wall 42 with a cold side 43 and a hot side 44, which is to be turned to the combustion chamber interior (the hot side is in FIG. 4 not recognizable). The cold side 43 communicates with the outlet of the compressor in fluid communication so that compressor air can be bypassed for cooling purposes on the cold side 43 to the temperature of the hot side on one for the material of the burner insert 41 acceptable level. The hot side is also provided with a heat-insulating coating, for example in the form of a ceramic coating, in order to reduce the need for cooling air.

At its center, the burner insert 41 has an opening 45 into which the outlet of a burner 27 can be inserted. The opening 45 is delimited by a section 47 of the burner insert wall 42 projecting beyond the cold side 43. From this projecting portion 47 extending in the radial direction of the opening 45 extending annular ridge, with which the burner insert 41 can be attached to a support structure.

In the present embodiment, the entire outer edge 46 of the burner insert 41 is provided with an over the cold side 43 projecting edge web 51, which gives the edge 46 increased rigidity and ensures that the natural frequency of the burner insert wall 42 is increased. Detail views of the edge 46 with the edge web 51 are in the FIGS. 5 and 6 shown.

The edge web 51 has battlements 53, which are formed by portions of the edge web 51, which project further beyond the cold side 43 than the remaining portions 54 of the edge web 51. If the burner insert is attached to a support structure and forms part of a combustion chamber end wall, lie Pinnacles 53 with the most distant from the cold side 43 end faces 55 on a contact surface of the support structure with a zero gap. Between the pinnacles 53 windows 57 are then formed, can flow through the cooling air, which is usually supplied in the region of the projecting wall portion 47 from the compressor into the combustion chamber. The cooling air can then flow along the cold side 43, which is completely flat except for the edge web 51 and the protruding wall region 47, for cooling. The windows 57 between the pinnacles 53 represent openings for the flowing cooling air with a defined passage cross-section, since the end faces 55 of the pinnacles 53 abut with zero gap on the investment structure. By a suitable choice of the width and height of the edge web sections 54 between the pinnacles 53 in relation to the height and width of the pinnacles 53, the amount of cooling air flowing into the combustion chamber can be adjusted in a targeted manner. Due to the increased stiffness that the edge web 51 imparts to the edge 46, there are also no significant deviations of the gap between the crenellated surfaces 55 and the bearing surface, so that the flow cross-section existing for the cooling air and defined by the window is largely maintained even during operation of the gas turbine , Over supply of cooling air by increasing the gap dimensions can be significantly reduced compared to the prior art, which in turn leads to a reduction of the cooling air entry into the combustion chamber and thus ultimately to a reduction of pollutants and higher turbine inlet temperatures.

Although the edge bar 51 in the FIGS. 4 to 6 shown embodiment with battlements 53 is provided to define window openings 57 for the cooling air, it is also possible to let the edge web 51 project uniformly over the cold side 43. Cooling air passages can then be realized by means of through-holes 59, for example in the form of bores. A corresponding embodiment of the burner insert according to the invention is in FIG. 7 shown.

Although in the present embodiments, the edge web extends along the entire outer edge 46 of the burner insert 41, embodiments are conceivable in which areas of the outer edge 46 of the burner insert 41 have no edge web 51. In addition, embodiments for cylindrical combustion chambers are possible. In such an embodiment variant, the outer edge of the burner insert would be substantially circular and the edge web would be present at least along a part of the circumference, preferably around the entire circumference.

The invention makes it possible to increase the natural frequency of the burner insert and at the same time the targeted adjustment of the outflow of cooling air into the combustion chamber, so that the cooling air can flow only through the predefined column. Associated with this, there are further advantages of the invention such as a longer service life of the burner insert and - by the cooling air saved at the burner insert - a reduction of pollutants at the same power of the burner inserts provided with the gas turbine, when the saved cooling air is supplied to the burner. Alternatively, higher outputs can be achieved with the same emissions.

Claims (13)

A combustor liner (41) for a gas turbine combustor (25) having a burner liner wall (42) having a cold side (43) and a hot side (44), a burner aperture (45) for inserting a burner (27) into the burner liner wall (42). is formed, and which has a burner insert wall (42) limiting edge (46)
characterized in that
the edge (46) has an at least partially circumferential over the cold side (43) projecting edge web (51). Burner insert according to claim 1,
characterized in that
the edge web (51) has openings (57, 59) for the passage of cooling fluid. Burner insert (41) according to claim 2,
characterized in that
the edge web (51) has crenellations (53) and the openings (57) are formed between the pinnacles (53). Burner insert (41) according to claim 3,
characterized in that
the crenellations (53) are formed by edge web sections which project further beyond the cold side (43) than the remaining edge web sections (54). Burner insert (41) according to claim 2,
characterized in that
the openings in the edge web (51) of through holes (59) are formed. Burner insert (41) according to claim 2,
characterized in that
the openings in the edge web (51) are formed by slots. Burner insert (41) according to one of the preceding claims,
characterized in that
the edge web (51) revolves around the entire edge (46). Burner insert (41) according to one of the preceding claims,
characterized in that
the burner opening (45) is surrounded by an annular wall region (47) which protrudes beyond the cold side (43) and is provided with an annular web (49), and the burner insert wall (42) is otherwise flat Gas turbine combustor (25) having at least one burner (27), at least one combustion chamber wall (33, 35) surrounding a combustion chamber interior and a burner-side combustion chamber end wall,
characterized in that
at least one burner insert (41) according to one of the preceding claims is present, the burner insert wall (42) at least partially forms the Brennkammerabschlusswand, wherein the hot side (44) of the burner insert wall (42) faces the combustion chamber interior. Gas turbine combustor (25) according to claim 9,
characterized in that
there is a gap between the combustion chamber end wall formed by the at least one burner insert (41) and the at least one combustion chamber wall (33, 35). A gas turbine combustor (25) according to claim 9 or claim 10,
characterized in that
it is formed as an annular combustion chamber with an annular combustion chamber interior formed between an inner combustion chamber wall (35) and an outer combustion chamber wall (33), and the burner-side combustion chamber closure wall is formed by a Number in the circumferential direction of the annular combustion chamber (25) juxtaposed burner inserts (41) is formed. Gas turbine combustor (25) according to claim 11,
characterized in that
between adjacent burner inserts (41) there are gaps. Gas turbine (1) with at least one gas turbine combustion chamber (25)
characterized in that the at least one gas turbine combustion chamber (25) is a gas turbine combustion chamber according to one of claims 8 to 11, - A cooling fluid reservoir is present and - The cold side (43) of the burner insert wall (42) fluidly communicates with the cooling fluid reservoir.

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