EP1456508A1 - Hot gas path subassembly of a gas turbine - Google Patents

Abstract

The invention relates to a hot gas path subassembly, in particular that is suitable for use in the hot gas path of a gas turbine, comprising an impingement-cooled gas-impermeable element (8) and a transpiration-cooled gas-permeable element (2), which constitute a hot gas channel wall. The gas-permeable element constitutes in particular an impact covering for a sealing tip (7a) and the gas-impermeable element constitutes a blade foot (16) of a turbine blade. Coolant (4) is conducted in sequence, first through an impingement cooling element (17) in order to cool the gas-impermeable element (8) by impingement, then flows through the gas-permeable element in order to cool it by transpiration, before optionally cooling the sealing tip (7a). The coolant is thus used in a particularly effective manner. The subassembly is also provided with partitioning walls (24) for the lateral partitioning of the coolant path (9), in particular in the peripheral direction, said walls being arranged in segments (26). As a result of said partitioning, if the gas-permeable element in one segment is damaged, the other segments remain essentially unaffected. In a preferred embodiment, redundant coolant orifices (18) guarantee the coolant flow, even if the flow resistance increases in a transpiration-cooled element.

Description

 HOT GAS PATH ASSEMBLY OF A GAS TURBINE

Technical application area

The present invention relates to a

Hot gas path assembly for a turbomachine, in particular for a gas turbine, according to the preamble of claim 1.

It also relates to a turbomachine in which an assembly according to the invention is used.

State of the art

The efficiency of an axially flowing gas turbine is influenced, among other things, by leakage flows of the compressed gas that occur between rotating and non-rotating components of the turbine. The gap that occurs between the tips of the rotor blades and the housing wall surrounding the rotor blades plays an important role here. The aim is therefore to keep the column as small as possible. If there are deviations from the design point, it is easy for the moving components to touch the static components. For this reason, components that are tolerant of abrasion and / or abrasion, such as for example Honeycomb seals, or also porous ceramic or metal structures or felts, are used, which serve as mating surfaces for the sealing tips of the rotor blades, and which are partially cut by these during a running-in phase. The

Use of such sealing-tolerant sealing elements reduces serious machine breakdowns in the event of smaller rubbing events, since the rubbing is absorbed by the soft structure of the mating surface without damaging the blades.

Both the tips of the rotor blades or guide vanes and the honeycomb seals used are exposed to very high temperatures in hot gas operation of the gas turbine.

It is therefore known, for example, from US Pat. No. 3,365,172 to apply cooling air to the sealing tips of the rotor blades through honeycomb seals. For this purpose, the carrier for the honeycomb seals is penetrated with small cooling air holes, which are supplied with cooling air via a circumferential annular chamber.

JP 61149506 shows a similar embodiment, in which the honeycomb seals are carried by a layer of porous metal, which adjoins a supply chamber for cooling air. In this embodiment, too, the cooling air is brought up to the blade tips through the honeycomb seals.

The guidance of cooling air through porous sealing elements is also known from US Pat. No. 6,171,052. Here, the porous sealing elements flow through with the cooling air perspiration-cooled. US 4,013,376 discloses a configuration in which the mating surface of the blades is both impingement-cooled and perspiration-cooled. No. 3,728,039 likewise discloses perspiration-cooled porous rings as counter-running surfaces of blades. The ring is segmented with cooling air. The ring itself is made in one piece.

A problem with a variety of configurations is that if the gas permeable elements are damaged by rubbing or even an area is torn out completely, the coolant pressure collapses and the entire sealing arrangement overheats and eventually fails. Likewise, if the porosity in a region becomes blocked by deformation due to the abrasion or also by dirt, the coolant flows around this region of the sealing element. Its cooling is no longer guaranteed and local overheating occurs. Overheating can burn out the affected area. The cooling air now flows through the large hole formed in this way, and the areas not previously affected are no longer cooled. As a result, the construction part as a whole, the entire circumference, fails.

A further question is how to use the available cooling air as efficiently as possible, since considerable savings are made in cooling air

Performance and efficiency potential can be tapped. Presentation of the invention

The object of the present invention is now to provide a hot gas path assembly of the type mentioned at the outset which avoids the disadvantages of the prior art. In particular, a hot gas path assembly should be designed in such a way that the cooling air is used as efficiently as possible, and that in the event of damage to an area, that of the

Sealing element, the cooling of the areas not directly affected remains essentially unaffected. In other words, potential damage should be limited to the location of the primary event that caused the damage.

The object is achieved with the hot gas path assembly according to claim 1.

The essence of the invention is, on the one hand, to connect two cooling points in series in a cooling air path in such a way that the flowing cooling air is used in succession to perform two cooling tasks. In one embodiment of the invention, the stator of a gas turbine is cooled once in the area of a guide blade row and in the area of a rotor blade row with the same cooling air flow, and at the same time the same cooling air is applied to the blade tips or the blade cover band. In this way, the maximum permissible cooling air heating is achieved and the cooling potential of the cooling air is exploited to the maximum. On the other hand, the partition wall is like this explained that the cooling air flow paths of individual segments arranged next to one another in the circumferential direction of the machine are hermetically separated from one another downstream of an impact cooling element. An impact cooling element is provided with a large number of comparatively small openings, via which a cooling air flow is directed at high speed onto the cooling side of the component to be cooled. Baffle cooling plates are often used. Because of this function, the impingement cooling elements cause a comparatively high pressure loss and are the essential throttle point in the respective coolant path, which also essentially causes the metering of the coolant flowing through. With a corresponding distribution of the pressure drops, the pressure loss coefficient of the impingement cooling element being greater, preferably at least by a factor of 2, than the pressure loss coefficient of the flow cross sections arranged downstream thereof, the entire flow is determined in a first approximation only by the impingement cooling element. For the configuration according to the invention, this means that if damage to the gas-permeable element, in particular a sealing element, occurs in a segment, the flow conditions of the coolant are not changed dramatically and the segments not primarily affected by the damage event are still adequately supplied with cooling air.

In a preferred embodiment of the invention, a plurality of gas-permeable elements are arranged next to one another in the circumferential direction. Due to the multi-piece, lateral, especially in the circumferential direction, Segmented execution of the sealing ring is further guaranteed that a local damage event remains mechanically limited to the segment directly affected. This is all the more fulfilled if the individual sealing ring segments are arranged and fastened in such a way that the greatest possible mutual mechanical decoupling is achieved. At least one individual gas-permeable element is preferably arranged in each segment. As already explained, the assembly according to the invention is particularly useful when the gas-permeable element is a component of a contactless seal of a turbomachine, in particular between a guide vane and the rotor and very particularly between a rotor blade and the stator.

In one embodiment of the invention, the gas-impermeable element is arranged upstream of the gas-permeable element in the direction of the hot gas flow. It is advantageous if the gas-impermeable element has a further, redundant, coolant opening, which opens on the hot gas side of the assembly. The coolant opening preferably opens upstream of the gas-permeable element, as close as possible to the gas-permeable element

Element. As far as possible, the coolant opening is designed such that coolant escaping there flows as parallel as possible to the hot gas-side surface of the gas-permeable element, in such a way that a cooling film is formed there. This has the following major advantages: If the flow cross-sections of the gas-permeable element of the respective segment are not due to contamination or deformation allow unimpeded flow more, on the one hand, a coolant flow through the impingement cooling holes or impingement cooling nozzles of the impingement cooling element is ensured, and the cooling of the gas-impermeable element is ensured.

At the same time, the air flowing out of the coolant opening lies as a cooling film over the gas-permeable element, and thus ensures a minimum cooling of this element, although due to the reduced flow, the perspiration cooling effect of the air flowing through the element is reduced or has completely failed. It is advantageous if the flow cross sections of the gas-permeable element and the coolant openings are dimensioned such that the pressure loss of the

The coolant opening is larger than that of the gas-permeable element, such that, by design, preferably less than 50%, and in particular less than 30%, of the total coolant flow through the coolant opening, and the rest is conducted as a perspiration coolant through the gas-permeable element. If its pressure loss increases due to the effects described above, the coolant shifts into the coolant opening and the proportion of film cooling increases. As stated above, the whole remains

Coolant mass flow is constant in the first approximation if the pressure loss through the impingement cooling holes predominates.

As already indicated, the assembly according to the invention is particularly suitable for use in turbomachines, the gas-permeable elements having a circumferential ring for contactless sealing form with an opposite blade ring, the gas-impermeable elements preferably also form a circumferential ring; this ring is preferably arranged upstream of the ring of the gas-permeable elements in the direction of the hot gas flow through the turbomachine. In a preferred embodiment, the gas-impermeable elements are impact-cooled heat accumulation segments, in a further preferred embodiment, the impact-cooled gas-impermeable elements

Turbine blades, in particular guide blades. In particular then the assembly according to the invention is arranged in the stator of the turbomachine.

It is a preferred embodiment, especially when the assembly is part of a turbomachine, that the dividers or partition walls for dividing the segments run parallel to the chords of blades arranged in the flow channel, and in particular on the gas-impermeable elements.

In one embodiment, the assembly consists of a number of subassemblies arranged side by side, in particular in the circumferential direction, which are constructed such that each subassembly comprises a gas-impermeable element and a gas-permeable element. A baffle cooling element is then essentially spaced apart on the hot gas side of the subassembly, opposite the gas-impermeable element, and a cover element is arranged opposite the gas-permeable element. Between the cover element and the impingement cooling element on the one hand and the gas-permeable and gas-impermeable element, on the other hand, an annular segment-shaped space or a substantially annular segment-shaped gap for the coolant is formed. According to the invention, such a subassembly comprises at least one

Partitioning wall for fluid-dividing and / or delimiting the annular gap in the lateral direction, in particular in the circumferential direction. in one embodiment, the subassembly carries at least one turbine blade; the partition wall then preferably runs parallel to the chord of this blade.

An annular assembly should preferably be subdivided in the circumferential direction into at least four segments which can be acted upon independently by cooling medium. By forming a larger number of segments, the reliability of the cooling is increased if individual sections of the gas-permeable elements are damaged.

In addition to honeycomb structures, "honeycombs", among other things, porous ones, for example produced by foaming, come as gas-permeable and in particular abrasion-tolerant elements

Structures made of metal or ceramic materials in question, or felts or fabrics made of metallic or ceramic fibers, in question.

In an advantageous embodiment of the present device, means are also provided for applying coolant to at least some of the segments independently of one another. This can be realized by a device which controls the supply of cooling medium to the individual segments via the respective supply channels independently of one another. In this way, an inhomogeneous temperature distribution during operation of the

Fluid machine over the circumference of the flow channel can be compensated by supplying individual segments with appropriately adapted amounts of cooling medium. This is still suitable for realizing a gap width control.

Even if in the following exemplary embodiments a ring-shaped or ring-segment-shaped configuration of the assembly, in particular in a turbomachine, and very particularly in a gas turbine, is assumed, the person skilled in the art will readily recognize that the invention can also be applied, for example, to flat geometries, the Then segments are not arranged next to each other in the circumferential direction but laterally.

BRIEF DESCRIPTION OF THE DRAWINGS The present cooling and sealing arrangement is explained below using exemplary embodiments in conjunction with the figures. Show in detail:

Figure 1 shows an example of the implementation of the invention in a gas turbine;

Figure 2 shows an example of the implementation of the invention with an impact-cooled guide vane root; FIG. 3 shows a simplified partial cross section of an assembly according to the invention;

FIG. 4 shows a subassembly for constructing an assembly according to the invention in a turbomachine, in particular a gas turbine assembly; and

Figure 5 is a simplified top view of the subassembly.

Elements not necessary for understanding the invention have been omitted. The

Exemplary embodiments are to be understood as instructive and are intended to provide a better understanding, but not to limit the invention, which is characterized in the claims.

Ways of Carrying Out the Invention

Figure 1 shows a section of a flow channel of a turbomachine, for example a turbine of a gas turbine group. A hot gas flow 12 flows through the flow channel from right to left. In the stator 13 is a guide vane root 16 with a not shown and not relevant to the invention, but familiar to the expert

Guide vane 10 arranged. A rotor blade 11 with a shroud 7 and shroud tips 7a is arranged downstream of the guide vane 10. The shroud tips, in conjunction with suitable stator elements 2 arranged opposite, minimize the leakage gap and thus the hot gas leakage flow 12a. In order to be able to keep the leakage gap small under nominal conditions, the opposite element 2 is normally a comparatively soft, touch-tolerant element. In the present case, this is designed as a perspiration-cooled, gas-permeable honeycomb element. The outflow of a coolant flowing through into the leakage gap in a cross-flow to the leakage flow is quite suitable for further reducing the leakage flow. The element 2 is held in a carrier 1. The assembly according to the invention, which is fastened in the stator, further comprises a gas-impermeable, impact-cooled element 8 arranged upstream of the gas-permeable element 2, here a heat accumulation segment. Coolant, in particular cooling air or steam, is supplied via a feed 14 in the housing 13. The coolant 4 is first at a high speed through openings or nozzles

Impact cooling element 17 out, and hits the cooling side of the element 8 with high momentum, which is cooled by impingement cooling. After the impingement cooling has been carried out, the coolant 4 continues to flow through the gas-permeable element 2 as transpiration coolant into the hot gas flow, the blade cover band 7 and the sealing tip 7a being further cooled in the present configuration. The best possible utilization of the coolant 4 results from this coolant guide. As can be seen, between the gas-permeable element 2, the gas-impermeable element 8, an upstream wall 22, a downstream wall 23, the impingement cooling element 17, and a cover element 21, there is a ring or annular segment-shaped space or gap 5, 9 formed. According to the invention, this is in the circumferential direction of the turbomachine divided, as explained in more detail below in particular in connection with Figure 3.

Another embodiment of the invention is shown in FIG. Essential elements are self-explanatory in the light of the explanations for Figure 1. In this exemplary embodiment, the gas-impermeable, impact-cooled element 8 also serves as a blade root 16 of the guide vane 10. Analogously to FIG. 1, between the gas-permeable element 2, the gas-impermeable element 8, the impingement cooling element 17, a cover element 21, and an upstream wall 22 and a downstream wall 23, a space 9 is formed, which is subdivided in the circumferential direction which cannot be seen here. Coolant passes through it

Impact cooling element 17 in room 9. Under undisturbed nominal conditions, the coolant 4 at least predominantly flows through the gas-permeable element 2. Furthermore, the gas-impermeable element 8 has a further, redundant coolant opening 18, through which the coolant 4 can flow out of the space 9. This coolant opening opens out on the hot gas side of the assembly in such a way that coolant emerging there flows as a cooling film over the hot gas side of the gas-permeable element. In particular, the redundant coolant opening 18 opens essentially tangentially to the hot gas-side surface of the gas-permeable element 2. The redundant coolant opening is preferably dimensioned such that under undisturbed nominal conditions less than half, in particular less than 30%, of the coolant mass flow 4 flow through the redundant coolant openings 18. If it is For example, due to contamination or a rubbing event, if the flow resistance of the gas-permeable element 2 increases significantly, the coolant flow shifts into the redundant coolant openings 18. On the one hand, the flow for cooling the gas-impermeable element 8 is maintained, and on the other hand, a flow due to decreasing through-flow becomes insufficient Perspiration cooling is successively replaced by film cooling through the openings 18.

Figure 3 shows a schematic view of an assembly according to the invention in a cross-sectional view. Essentially radially and axially extending webs or partition walls 24 divide the space 9 in the circumferential direction into segments 26. A separate redundant coolant opening 18 is also arranged for each segment 26; at least their mouth is elongated, in order to achieve the largest possible distribution of film coolant if necessary. The entire coolant path is thus subdivided into segments that are completely independent of one another, at least downstream of the impingement cooling elements 17, by the partition walls 24. Furthermore, a single gas-permeable element 2 is still arranged for each segment 26. If a blade tip 7a (not shown here), see in this regard FIG. 1 or 2, is now strongly rubbed against a segment, only the gas-permeable element directly affected is torn out of the assembly. Due to the mechanical decoupling of the gas-permeable elements 2 of the different Segment 26, the mechanical damage event remains limited to the segments directly affected. Of course, the coolant pressure collapses in space 9 of the segment concerned. However, since the segments are separated from one another and the significant pressure loss occurs in the impingement cooling elements 17, the coolant pressure in the other segments remains constant, at least to a good approximation, and the damage event is completely localized to the segment or segments concerned. Impact cooling of the gas-impermeable element in the affected segment also remains essentially fully functional.

In a real-time fluid machine, the assembly according to the invention is advantageously constructed from a plurality of sub-assemblies arranged next to one another in the circumferential direction, which considerably simplifies the handling of the invention. Such a subassembly is shown by way of example in FIG. 4 in a perspective view. It is a subassembly of the assembly from FIG. 2, and comprises a peripheral segment with a guide vane 10, together with its impingement-cooled blade root 16. The subassembly further comprises a gas-permeable one

Element 2, an impingement cooling element 17, a cover element 21, and an upstream wall 22 and a downstream wall 23. The arrangement shown forms a ring-segment-shaped gap 9, which is closed in the radial and axial direction and is open on the U start sides of the subassembly is. According to the invention, the subassembly comprises a partition wall 24, which en can be arranged on a peripheral side of the subassembly or at another peripheral position. The partition wall is designed such that, as explained in connection with FIG. 3, it creates a fluid separation between the two circumferential sides.

FIG. 5 finally shows a schematic plan view of the subassembly from the outside radially, with “separated” walls 22, 23, 24. It can be seen that in this preferred embodiment the one that is not explicitly identified in FIG. 5 but in the light for the person skilled in the art of the preceding explanations, clearly recognizable, space 9 is divided in the circumferential direction by a dividing wall 14 in the circumferential direction, which runs parallel to the dash-dotted chord of the blade 10. The partition wall 24 is arranged directly on a peripheral side of the sub-assembly; but it could easily be arranged at another circumferential position.

The person skilled in the art can readily apply the statements made here for ring-shaped or ring-segment-shaped geometries to flat geometries, in which case instead

Circumferential segments are arranged side by side.

LIST OF REFERENCE NUMBERS

support element gas-permeable element coolant space, gap blade shroud sealing tip gas-impermeable element coolant channel, gap guide vane rotor blade hot gas flow a leakage flow housing wall, stator supply for coolant blade root impingement cooling element, impingement cooling plate, segment cooling insert redundant coolant opening cover element, upstream circumferential part of the wall upstream, lower part of the wall part

Claims

claims

1. Hot gas path assembly for one

Turbomachine, in particular a gas turbine, which hot gas path assembly has in particular an annular or ring segment cross section, and which assembly has a cooling side and a hot gas side overflowed during operation of hot gas (12), comprising at least one gas-permeable element (2) designed for perspiration cooling and at least one gas-impermeable element (8), the gas-permeable element and the gas-impermeable element being arranged at different positions in the direction of flow on the wall of the hot gas path, in which assembly the gas-impermeable element is impact-cooled, with an impingement cooling element (17) spaced apart on the cooling side, and a coolant path (9, 5) is formed on the cooling side of the assembly, which leads from the impingement cooling insert (17) to the rear of the gas-permeable element (2), characterized in that the coolant path (9) is divided laterally, in particular in the circumferential direction, into at least one partition wall (24) into segments (26) insulated from one another.

2. Module according to claim 1, characterized in that, in particular in the circumferential direction, a plurality of individual gas-permeable elements are arranged side by side.

3. An assembly according to claim 2, characterized in that at least one individual gas-permeable element is arranged in each segment.

4. Assembly according to one of the preceding claims, characterized in that the gas-permeable element is a sealing element of an arrangement for contactless sealing.

5. Assembly according to one of the preceding claims, characterized in that the gas-impermeable element (8) is a blade root (16), in particular a guide blade root.

6. Assembly according to one of the preceding claims, characterized in that the gas-impermeable element (8) in the flow direction (12) of the hot gas channel is arranged upstream of the gas-permeable element (2).

7. Assembly according to one of the preceding claims, characterized in that the

Partition walls (24) for the lateral subdivision of the coolant path (9) are arranged essentially parallel to the profile views of blades (10) arranged in the hot gas channel.

8. An assembly according to claim 5, characterized in that the partition walls (24) run substantially parallel to the chords of the blades (10, 16) arranged on the blade root (8, 16).

9. Assembly according to one of the preceding claims, characterized in that a coolant opening is arranged in the gas-impermeable element, which preferably opens upstream of the gas-permeable element on the hot gas side.

10. Assembly according to one of the preceding claims, characterized in that the assembly consists of a number of subassemblies arranged side by side in the segmentation direction.

11. Turbomachine, in particular gas turbine, comprising at least one assembly according to one of the preceding claims, characterized in that the gas-permeable elements (2) form a circumferential ring for contactless sealing with an oppositely arranged blade ring (11, 7, 7a).

12. Flow machine according to claim 11, characterized in that the gas-impermeable elements (8) form a circumferential ring which is arranged upstream of the gas-permeable elements (2) in the flow direction of the hot gas flow (12).

13. Fluid machine according to one of claims 11 or

12, characterized in that the gas-impermeable elements (8) are impact-cooled heat accumulation segments.

14. Fluid machine according to one of claims 11 to

13, characterized in that the gas-impermeable elements (8) carry turbine blades (10), in particular guide blades.

15. Fluid machine according to one of claims 11 to

14, characterized in that the assembly is arranged in the stator (13) of the turbomachine.

16. Subassembly of an assembly according to claim 10, with a cooling side, a hot gas side, an upstream side, a downstream side, and two lateral sides, in particular two peripheral sides, comprising: a hot gas side wall, which in turn has at least one gas-impermeable element (8, 16) and comprises a gas permeable element (2) arranged downstream thereof; a cooling-side wall, which is spaced from the hot gas-side wall and is arranged opposite it, and which in turn has at least one impingement cooling element (17) with a multiplicity of coolant passage openings for the passage of impingement cooling coolant, in particular an impingement cooling plate, and at least one cover element (21), includes, wherein the impingement cooling element (17) is arranged opposite and spaced from the gas impermeable element (8), and the cover element (21) is arranged downstream of the impingement cooling element (17), adjoining the gas permeable element (2) and spaced apart therefrom; at least one downstream wall (23) and one upstream wall (22), which establish a connection between the hot gas side wall and the cooling side wall; such that a gap (9) for coolant flow is formed between the hot gas side wall, the cooling side wall, the upstream wall, and the downstream wall, characterized in that at least one partition wall (24) is arranged which connects the upstream wall with the downstream one Connects the wall and the hot gas side wall with the cooling side wall in such a way that a fluid separation is established between the lateral sides.

17. Subassembly according to claim 16, characterized in that on the hot gas side wall (2, 8) at least one turbine blade (10) is arranged.

18. Sub-assembly according to claim 17, characterized in that the partition wall (24) is arranged substantially parallel to the chord of the blade profile.