WO2015022222A1 - Heat shield having at least one helmholtz resonator - Google Patents

Abstract

The invention relates to a heat shield (30) for a combustion chamber (25). The heat shield comprises a support structure (32), a number of heat shield elements, and at least one Helmholtz resonator (48), wherein the heat shield elements (34a, 34b) are detachably fastened to the support structure (32) essentially so as to cover the surface and by means of stone holders (50) while leaving expansion gaps (36). Each heat shield element HAS a cold side (40) facing the support structure (32), and a hot side (38) located opposite the cold side, which can be acted upon by means of a hot medium, and circumferential sides (42). The Helmholtz resonator (48) comprises a resonance volume (54), a housing (52) surrounding the resonance volume, and at least one resonator neck channel (58) fluidically connecting the resonator volume (54) to the environment. The heat shield according to the invention makes the damping of thermo-acoustic vibrations in a defined frequency range possible, under particularly little cooling air consumption. To this end, at least a partial area of the resonance volume extends along an expansion gap (36) or an expansion gap section between circumferential sides (42) of the heat shield elements (34a, 34b).

Description

description

Heat shield with at least one Helmholtz resonator The invention relates to a heat shield for a combustion chamber, in particular a gas turbine. The heat shield comprises a support structure and a number of heat shield elements, wherein the heat shield elements are substantially surface-mounted while leaving expansion gaps, and are fastened detachably to the support structure by means of stone holders. Each heat shield element has a cold side facing the support structure and a hot side which is opposite the cold side and can be charged with a hot medium. The hot side is connected to the cold side over peripheral sides.

In many technical applications, heat shields are used which must withstand hot gases of 1000 to 1600 degrees. In particular, gas turbines, such as those used in power-generating power plants and aircraft engines, have correspondingly large shielded by heat shields

Areas inside the combustion chambers. Because of thermal expansion and large dimensions, the heat shield must be composed of a plurality of individual, generally ceramic heat shield bricks, spaced apart from each other with a sufficient gap to a support structure. This gap offers the heat shield bricks, which can also be called heat shield elements, sufficient space for thermal expansion. A gas turbine in the simplest case comprises a compressor, a combustion chamber and a turbine. In the compressor there is a compression of sucked air, which is then admixed with a fuel. In the combustion chamber, a combustion of the mixture, whereby a hot working gas flow is produced, which is supplied to the turbine. This removes energy from the hot working gas and converts it into mechanical energy. In the combustion chamber there may be an interaction of acoustic oscillations and fluctuations in the heat release, which can swell each other. Such thermoacoustic oscillations, which occur in particular in the combustion chamber of the gas turbine, can lead to considerable damage to the components during operation of the gas turbine and force shutdown of the system.

To damp these thermoacoustic oscillations, it is known to arrange Helmholtz resonators on the combustion chamber wall. The Helmholtz resonators include a resonant volume, a housing surrounding the resonant volume, and at least one resonator throat channel fluidly connecting the resonant volume to the ambient. The resonator neck channel has a diameter and a length, wherein these dimensions can be related to the resonance volume in such a way that the Helmholtz resonator is tunable to a frequency or frequency band. The thermoacoustic vibrations to be damped meet an input opening of the

Resonator neck on and are passed over the resonator neck in the interior of the resonant volume. In this sense, the acoustic vibrations can be coupled into the resonance volume by means of the resonator neck channel. When the heat shield is charged with hot gas, the temperature inside the Helmholtz resonators changes, as a result of which the frequency range damped by the resonator also changes continuously. In order to keep the frequency range constant, the known resonators are purged with cooling air during operation of the gas turbine. However, this scavenging air is then no longer available for combustion. This deteriorates the exhaust gas values of the gas turbine.

The object of the present invention is to provide an initially mentioned heat shield with at least one Helmholtz resonator, with which the damping of thermoacoustic oscillations in a predetermined frequency range using particularly low cooling air consumption is made possible. A further object of the invention is to specify a Helmholtz resonator for the aforementioned heat shield, a combustion chamber with such a heat shield and a gas turbine with such a combustion chamber, with which the damping of thermoacoustic oscillations in a predetermined frequency range using particularly low cooling Air consumption is enabled. The object is achieved in a heat shield of the type mentioned in that

at least a portion of the resonance volume extends along a strain column or a strain column section between peripheral sides of the heat shield elements, wherein the Helmholtz resonator substantially at least partially closes the expansion gaps for protection against hot gases.

The inventive design of the Helmholtz resonator leads to a reduced consumption of cooling air in the region of the expansion gaps of the heat shield. Since the expansion column is at least partially closed by the Helmholtz resonator arranged in it, blocking the expansion gaps against hot gas infeed on this section of the expansion column is no longer necessary or only necessary to a very limited extent. The saved cooling air can be used to cool the Helmholtz resonator. Here, the arranged in the expansion column Helmholtz resonator requires only a fraction of cooling air against the open expansion column. For example, the cooling air for cooling the Helmholtz resonator can be guided past this by being guided on both sides by the gap between the peripheral side and Helmholtz resonator housing. The gap may be formed in the form of a labyrinth seal, so that an expansion of the heat shield elements is still possible. Locking the labyrinth seal simultaneously allows cooling of the Helmholtz resonator. The cooling air can, for example, or alternatively as purge air through the helmet holtzresonator be guided. The thus internally cooled Helmholtz resonator is particularly resistant to hot gases. The Helmholtz resonator can occlude the entire expansion column or only a portion of it. The Helmholtz resonator can be arranged, for example, along an axial or radial expansion gap. If the expansion gap is an axial gap of an annular combustion chamber, it may be arranged along the outer shell in an axial gap or on the hub along an axial gap. The radial expansion gaps run around a longitudinal axis of the combustion chamber. If the Helmholtz resonator is arranged in a radial expansion column, it may, for example, have a semicircular configuration or a circular one in that it is composed of a plurality of circular-segment-shaped Helmholtz resonators. The circular segment-shaped Helmholtz resonators can for example be connected to one another via a dovetail connection. In the case of the heat shield according to the invention, essentially all axial and / or radial gaps can be closed by means of the Helmholtz resonators. This allows a particularly high damping potential.

Advantageous embodiments of the invention are specified in the following description and the dependent claims, the features of which can be used individually and in any combination with each other.

It can also be considered advantageous that the resonance volume of the Helmholtz resonator is arranged between the peripheral sides of the heat shield elements.

In this case, the resonance volume is completely in the expansion column and has no protrusions extending below the heat shield. As a result, it can have a particularly simple shape. The resonance volume may, for example, have a substantially parallelepipedal shape, with the direction of the longitudinal axis of the Stretching column facing edges can be bent.

It can also be considered advantageous for the helmet-retaining resonator to extend along a number of heat shield elements and to have a shape running in the longitudinal direction of the expansion gap, in particular a curved shape, corresponding to the course of the expansion column. According to this embodiment of the invention, the length of the

Helmholtz resonator in the direction of the longitudinal extent of the expansion column greater than the side length of a heat shield stone. This reduces the number of necessary components.

Furthermore, it can be advantageously provided that the helmet holtz resonator extends in the direction of the hot side substantially to the level of the hot sides of the heat shield bricks. This allows a particularly flat surface of the heat shield.

It can also be considered advantageous that the Helmholtz resonator comprises a heat-insulating layer on its outer side facing the hot gases.

The Helmholtz resonator may consist of a metallic material, which may be provided for its protection with such a thermal barrier coating. The thermal barrier coating may be a so-called TBC (Thermal Barrier Coating) layer. The layer can also be applied to other areas of the outside of the Helmholtz resonator.

A particularly advantageous embodiment of the invention can provide that at least one input opening of a

Resonator neck channel is arranged on the hot gases facing the outside of the Helmholtz resonator. _r

This enables a particularly effective coupling of the thermoacoustic oscillations into the resonance volume. The inlet openings of the resonator neck channels can, for example, be arranged successively in a row following the course of the expansion gaps on the outside of the Helmholtz resonator facing the hot gases.

Furthermore, it can be advantageously provided that the helmet-holding resonator can be flowed through by means of cooling air and encompasses at least one purging air channel opening into the resonance volume.

This allows a particularly good control of the internal temperature of the Helmholtz resonator.

A further advantageous embodiment of the invention can provide that the Helmholtz resonator along the expansion column is formed as a stone holder of the adjacent him heat shield elements and at least one can be arranged on at least one heat shield element holding portion and at least one attachable to the support structure mounting portion.

This embodiment of the invention allows a further saving of cooling air, as beyond the Helmholtz resonator addition no further, the heat shield elements holding stone holder must be cooled.

Advantageously, it can further be provided that the peripheral sides of the heat shield elements adjoining the Helmholtz resonator form at least one retaining bolt with at least one contact surface facing the hot side, wherein the housing of the Helmholtz resonator rests on the contact surface and is braced against the support structure.

According to this embodiment of the invention, the area of the Helmholtz resonator housing resting on the support surface can form the at least one holding section. For example, the support surface may be aligned parallel to the hot side of the heat shield element. The housing of the resonator can rest completely on the retaining bolts, wherein the housing is braced with at least one fastening portion on the support structure. For example, the

Attachment portion be a fastening bolt which is resiliently anchored in the support structure.

It can also be considered advantageous that the helmet-holtz resonator can be attached to the support structure on a fastening groove running in the support structure and underneath the expansion gaps.

The mounting groove allows the Helmholtz resonator to be moved along the groove to its intended position.

Advantageously, the fastening groove has a groove-shaped recess in the region of the groove bottom along both side walls, so that a widening of the fastening groove is formed. The at least one attachment portion of the Helmholtz resonator intervenes for attachment in this broadening. This embodiment of the fastening groove has a particularly simple construction and ensures a secure hold of the fastening section in the groove.

Tailored to this embodiment of the fastening groove, the at least one fastening portion of the housing of the

Helmholtz resonator starting to extend to the support structure and include a T-shaped end portion, the crossbar is threadable into a running in the support structure mounting groove.

The attachment portion can be threaded into the groove, for example in the region of a dividing joint which cuts the fastening groove. The Helmholtz resonator can be one or comprise a plurality of such attachment portions. To simplify the construction, exactly one can be provided, which extends bar-shaped below the housing and is threaded with the T-shaped end section over the entire length in the fastening groove. This allows a particularly stable attachment of the stone holder to the support structure.

Furthermore, it can be advantageously provided that at least one scavenging air duct runs through the fastening section, with at least one inlet opening for scavenging air pointing in the direction of the supporting structure and at least one outlet opening in the resonant volume.

The inlet opening of the scavenging air channel can be aligned with the outlet opening of a cooling air channel arranged in the supporting structure.

The heat shield according to the invention can extend from an inlet to an exit region of a combustion chamber and comprise axial expansion gaps and radial expansion gaps formed circumferentially perpendicular thereto. The Helmholtz resonator according to the invention can be arranged in such a radial or in an axial expansion column, wherein it can be advantageously provided that the heat shield bricks are formed overlapping along at least one expansion column of the other column type.

For example, the heat shield elements can be arranged overlapping along the axial gaps and the radial gaps of Helmholtz resonators invention be closed. This has the advantage that scavenging air emerging from the resonator neck channels distributed along the entire circumference of the combustion chamber can cool the surface of the heat shield elements by means of film cooling. The arrangement could also be reversed. This has the advantage that the

Helmholtz resonators along the axial expansion gaps may have a much less curved shape or a straight shape. This allows a further reduction of the cooling air requirement. Another object of the invention is to provide a Helmholtz resonator for the aforementioned heat shield, with which the attenuation of thermoacoustic oscillations in a predetermined frequency range using particularly low cooling air consumption is made possible.

For this purpose, it is formed as part of the heat shield according to one of claims 1 to 15.

A further object of the invention is to specify a combustion chamber lined with a heat shield mentioned at the outset and a gas turbine with which the damping of thermoacoustic oscillations in a predetermined frequency range using particularly low cooling air consumption is made possible.

For this purpose, the combustion chamber comprises at least one heat shield according to one of claims 1 to 15 and the gas turbine at least one combustion chamber according to claim 17. Further expedient refinements and advantages of the invention are the subject of description of embodiments of the invention with reference to the figure of the drawing, wherein like reference numerals refer to the same components.

It shows the

Fig.l schematically shows a longitudinal section through a gas turbine according to the prior art, and

2 schematically shows a longitudinal section through a section of a heat shield in the region of an invented Helmholtz resonator according to the invention according to one embodiment.

FIG. 1 shows a schematic sectional view of a gas turbine 1 according to the prior art. The gas turbine 1 has inside a rotatably mounted about a rotation axis 2 rotor 3 with a shaft 4, which is also referred to as a turbine runner. Along the rotor 3 follow one another an intake housing 6, a compressor 8, a combustion system 9 with a number of combustion chambers 10, a turbine 14 and an exhaust housing 15. The combustion chambers 10 each comprise a burner assembly 11 and a housing 12, which is designed to protect against hot gases is lined with a heat shield 20. The combustion system 9 communicates with an annular hot gas duct, for example. There, a plurality of successively connected turbine stages form the turbine 14. Each turbine stage is formed of blade rings. When viewed in the direction of flow of a working medium, the hot runner of a row formed by vanes 17 is followed by a row formed by buckets 18. The guide vanes 17 are fastened to an inner housing of a stator 19, whereas the moving blades 18 of a row are attached to the rotor 3, for example by means of a turbine disk. Coupled to the rotor 3 is, for example, a generator (not shown).

During operation of the gas turbine, air is sucked in and compressed by the compressor 8 through the intake housing 6. The compressed air provided at the turbine-side end of the compressor 8 is led to the combustion system 9 where it is mixed with a fuel in the area of the burner assembly 11. The mixture is then burned by means of the burner assembly 11 to form a working gas stream in the combustion system 9. From there, the working gas stream flows along the hot gas channel past the guide vanes 17 and the rotor blades 18. At the rotor blades 18, the working gas stream relaxes in a pulse-transmitting manner, so that the running Blades 18 drive the rotor 3 and this coupled to him generator (not shown).

FIG. 2 shows a section of a heat shield 30 according to an exemplary embodiment of the invention in a longitudinal section.

The heat shield 30 comprises a support structure 32 and, in the region of the section shown, heat shield elements 34a, 34b, which adjoin one another, leaving an expansion gap 36. The heat shield elements 34a, 34b have a hot side 38 which can be acted upon with hot gases and a cold side 40 which lies opposite the hot side. The hot side 38 is connected to the cold side 40 via peripheral sides. The circumferential sides 42 adjoining the expansion gaps 36 form a retaining bolt 44, which in each case has a bearing surface 46 facing the hot side.

In the expansion column 36, a Helmholtz resonator 48 according to the invention is arranged. This is formed according to the illustrated embodiment in the form of a stone holder 50 of the heat shield elements 34a and 34b. The Helmholtz resonator 48 comprises a resonant volume 54 surrounded by a housing 52. Resonator neck channels 58 are arranged in the housing 52 in the form of bores in the housing wall. The resonator neck channels 58 connect the resonance volume 54 with the interior of the combustion chamber 60, so that over the

Resonator neck channels 58 thermoacoustic vibrations are coupled into the resonant volume. The resonator neck channels 58 have inlet openings 62 which are arranged on an outer side 56 of the Helmholtz resonator 48 facing the hot gases. For example, the entrance openings 62 may be disposed on the outside 56 of the housing 52 in a row parallel to a longitudinal direction 64 of the expansion column.

The housing 52 and the resonance volume 54 enclosed by it are between the circumferential sides 42 in the expansion gaps 36 arranged and closes them substantially over the length of the Helmholtz resonator 48. The Helmholtz resonator 48 may for example have a length corresponding to the side length of the heat shield element 34a, 34b. However, the Helmholtz resonator can also have a substantially greater extent and extend, for example, over a section of the radial expansion gaps 36, which substantially corresponds to a ring segment. The radial expansion gap 36 extends perpendicular to a main flow direction 68 of the combustion chamber passing hot gases and circumferentially around a

 Longitudinal axis of the combustion chamber. With sufficient length for this reason, the Helmholtz resonator 48 can advantageously have a curved shape in the longitudinal direction 64 of the expansion gaps 36 in accordance with the curved course of the expansion gap 36. Perpendicular to the support structure, the Helmholtz resonator 48 extends in the direction of the hot side substantially to the level of the hot sides 38 of the heat shield bricks 34a and 34b. According to the illustrated embodiment, the Helmholtz resonator 48 is connected to the housing 52 with a portion of the housing, which may also be referred to with holding portion 70, on the formed from the peripheral sides 42 retaining bolts 44 and is braced against the support structure. For this purpose, a fastening portion 72 of the Helmholtz resonator 48 engages in a below the expansion column 36 in the support structure 32 extending mounting groove 74 a.

The fastening groove 74 has a groove-shaped recess 78 in the region of the groove bottom 76 along both side walls, so that a widening of the fastening groove 74 is formed. The mounting portion 72 engages with a T-shaped end portion 80 in this broadening for attachment.

The trained as a stone holder Helmholtz resonator 48 can be flowed through with cooling air. For this purpose, the Helmholtz resonator 48 comprises a scavenging air duct 82 extending through the fastening section 72. The scavenging air duct 82 opens into the resonant volume 54 through an outlet opening 86 and becomes supplied with purging air via an inlet opening 84 pointing in the direction of the support structure 32. For introducing scavenging air into the scavenging air duct, the inlet opening 84 is positioned, for example, via a cooling air bore 88 arranged in the groove bottom 76 of the fastening groove 74.

The purge air flows through the Helmholtz resonator 48 and cools it from the inside. As a result, the damping behavior of the Helmholtz resonator 48 can be kept constant despite exposure to hot gases. The stone holder 50 or the Helmholtz resonator 48 may be made of a metallic material. For example, it can be bent from a sheet metal and closed on the end faces in each case by means of a cover plate. For protection against hot gases, a heat-insulating layer can be applied to the exterior side 56 of the Helmholtz resonator 48 facing the hot gases.

Claims

claims

A heat shield (30) for a combustion chamber (25), wherein the heat shield comprises a support structure (32), a number of heat shield elements (34a, 34b) and at least one Helmholzresonator (48),

 wherein the heat shield elements (34a, 34b) are fastened to the support structure (32) substantially blanket by means of expansion gaps (36) and are detachably fastened to the support structure (32) by means of stone holders (50), and each heat shield element (34a,

34b) has a cold side (40) facing the support structure (32) and a hot side (38) which is opposite to the cold side and can be charged with a hot medium, and peripheral sides (42) connecting the hot side to the cold side,

 and wherein the Helmholtz resonator (48) comprises a resonant volume (54), a housing (52) surrounding the resonant volume, and at least one resonator neck channel (58) fluidly connecting the resonant volume to the ambient, such that acoustic resonant cavities are provided by the resonator throat channel

 Vibrations can be coupled into the resonant volume, at least a portion of the resonant volume extending along an expansion column (36) or a Dehnungsspaltenab- section between peripheral sides (42) of the heat shield elements (34a, 34b).

2. Heat shield (30) according to claim 1,

The Helmholtz resonator (48), at least in some sections, is the so-called

Strain column (36) for protection against hot gases substantially closes.

3. Heat shield according to claim 1 or 2,

characterized in that the resonance volume (54) of the Helmholtz resonator (48) between the peripheral sides (42) of the heat shield elements (34a, 34b) is arranged.

4. Heat shield according to one of claims 1 to 3, characterized in that the Helmholtz resonator (48) extends in the longitudinal direction (64) of the expansion gaps (36) along a number of heat shield elements (34a, 34b) and according to the course of the expansion gaps in a longitudinal direction (64) the expansion column extending shape, in particular a curved shape having.

5. heat shield (30) according to one of claims 1 to 4,

That is, the Helmholtz resonator (48) extends toward the hot side substantially to the level of the hot sides (38) of the heat shield bricks (34a, 34b).

6. heat shield (30) according to any one of claims 1 to 5,

The Helmholtz resonator comprises a heat-insulating layer on its outer side (56) facing the hot gases.

7. A heat shield according to one of the preceding claims, characterized in that at least one input opening (62) of a resonator throat channel (58) is arranged on the outside of the Helmholtz resonator facing the hot gases.

8. A heat shield according to one of the preceding claims, characterized in that the Helmholtz resonator can be flowed through by means of cooling air and comprises at least one flushing air duct (82) opening into the resonance volume (54).

9. Heat shield according to one of the preceding claims, characterized in that the Helmholtz resonator along the expansion column as a stone holder (50) of the adjacent him heat shield elements (34 a, 34 b) is formed and at least one can be arranged on at least one heat shield element holding portion (70) and min. at least one attachable to the support structure mounting portion (72).

10. Heat shield according to one of the preceding claims, characterized in that the peripheral sides (42) of the Helmholtz resonator adjacent heat shield elements at least one retaining bolt (44) form with at least one of the hot side facing bearing surface (46), wherein the housing (52) of the Helmholtz resonance sector (48) on the support surface (46) rests and is clamped against the support structure (32).

11. The heat shield according to claim 1, wherein the Helmholtz resonator can be fastened to the support structure on a fastening groove extending in the support structure and underneath the expansion gap.

12. Heat shield according to claim 11,

characterized in that the fastening groove in the region of the groove bottom (76) along both side walls has a groove-shaped recess (78), so that a widening of the fastening groove is formed, and engages the at least one attachment portion (72) for attachment in this widening ,

13. Heat shield according to one of the preceding claims 9 to 12,

The at least one attachment portion (72) extends from the housing of the Helmholtz resonator to the support structure and includes a T-shaped end portion (80), the crossbeam of which can be threaded into a mounting groove (74) in the support structure.

14. Heat shield according to one of the preceding claims 9 to 13,

characterized in that at least one scavenging air duct (82) extends through the fastening section (72), with at least one inlet opening (84) for scavenging air pointing in the direction of the supporting structure and at least one outlet opening (86) opening into the resonant volume.

15. The heat shield according to claim 1, wherein the heat shield elements adjoining the Helmholtz resonator are designed to overlap along the circumferential sides tapered to the expansion gap.

16. Helmholtz resonator (48),

It is a part of the heat shield (30) according to any one of claims 1 to 15.

17. combustion chamber (25) for a gas turbine,

It is at least one heat shield (30) according to any one of claims 1 to 15 that comprises at least one heat shield (30).

18. Gas turbine (1) with at least one combustion chamber (25), d a d u c h e c e n e c e n e s, at least one combustion chamber (25) according to claim 17 is formed.