EP1654440A1

EP1654440A1 - Gas turbine having a sealing element between the vane ring and the moving blade ring of the turbine part

Info

Publication number: EP1654440A1
Application number: EP04740664A
Authority: EP
Inventors: Peter Tiemann
Original assignee: Siemens AG
Current assignee: Siemens AG
Priority date: 2003-08-11
Filing date: 2004-07-05
Publication date: 2006-05-10
Anticipated expiration: 2024-07-05
Also published as: ES2316994T3; PL1654440T3; EP1654440B1; CN1833094A; WO2005019602A1; US20060245915A1; CN100395431C; DE502004008830D1; US7303371B2

Abstract

The invention relates to a gas turbine (1). The aim of the invention is to provide an axial sealing between a vane ring (11) and a moving blade ring (13), which has an excellent sealing effect, is easy to install and inexpensive to produce. For this purpose, a sealing element (35) is used that extends across at least a fourth of the hot gas channel circumference. Preferably, said sealing element extends across approximately half the circumference and is inserted in grooves of the vane support (79) and the vane platforms.

Description

GAS TURBINE WITH A SEALING ELEMENT BETWEEN GUIDANCE RANZ AND RUNNING SHUTTER LIFT OF THE TURBINE PART

The invention relates to an axial gas turbine, arranged in the hot gas duct axially successive vane rings and blade rings. These blade rings are subjected to cooling air from different pressure levels. For sealing between the individual pressure levels, a sealing element is provided.

An axial gas turbine comprises a compressor, a combustion chamber and a turbine part. In the compressor combustion air is highly compressed, which is burned in the combustion chamber with fuel. The resulting hot gas is passed through a hot gas duct in the turbine part. In the turbine part follow each other alternately

Vane rings and blade rings. In each of these blade rings guide vanes are arranged adjacent in the circumferential direction.

The temperatures in such a gas turbine can reach values which exceed the melting points of the materials used or intolerably reduce the heat resistance of the materials. For this reason, the components in the hot gas channel are often cooled with a cooling medium. Mostly this air is diverted from the compressor as cooling air. The cooling requirement decreases along the flow direction in the hot gas duct. For this reason, a cooling air with a lower pressure level than cooling air for front turbine stages is sufficient for cooling rear turbine stages. In order to keep the cooling air consumption as low as possible, since this reduces the efficiency of the gas turbine, the axially different turbine stages, ie the different blade rings, are acted upon by cooling air from different pressure levels. In the direction of flow further forward blade rings are supplied with compressed air higher pressure than blade rings, which are further downstream in the flow direction. From this different supply of adjacent vane rings follows the need for a seal between the different pressure levels. A seal is also necessary to avoid the interference of hot gas in the cooling air, and thus a lower cooling effect.

U.S. Patent No. 5,833,244 shows a gas turbine seal assembly. The sealing of two adjacent blade rings is achieved here by a labyrinth seal system. Individual sealing elements are arranged in grooves of rotor discs. These sealing segments have transversely to the flow direction and in the axial direction one behind the other arranged tooth-like elevations, which are arranged opposite a vane tip. By the juxtaposition in the circumferential direction of such segments is a circumferentially circumferential

Labyrinthdichtungssystem provided, which is particularly suitable for the seal in large gas turbines.

From the sealing system between two blade rings in the axial direction is to distinguish a sealing arrangement which acts in the circumferential direction between blades of one and the same blade ring. Such a circumferential seal serves to shield the hot gas flowing in the hot gas duct against the rotor disks or guide blade carrier. Such arrangements can be found for example in US Pat. No. 5,785,499 or US Pat. No. 6,273,683.

The object of the invention is to provide a sealing system for sealing located between two blade rings of a gas turbine pressure levels, which has a particularly good sealing effect and at the same time is easy to install and inexpensive. According to the invention, this object is achieved by an axial gas turbine directed along a turbine axis, comprising a compressor, a combustion chamber and a turbine part, in the turbine part axially successive vane rings and rotor blade rings in one

In operation, a hot gas flowing through the hot gas channel and wherein the vane rings and blade rings are cooled with cooling air, the pressure level decreases in the flow direction of the hot gas, wherein between at least one blade ring and a directly adjacent vane ring, a sealing element is arranged, which the various Compressive levels against each other and at least a quarter of a perpendicular to the turbine axis as a center extending circle integrally extends.

Thus, for the first time, the invention pursues the way of extending a sealing element for sealing in the axial direction over a greater circumferential distance. As a result, the sealing effect is considerably improved because circumferentially extending sealing boundaries are reduced. Furthermore, the reduction of components facilitates installation. The reduction in components also causes a more cost-effective design.

Preferably, the sealing element extends around half of the circle. Thus, only two sealing elements are required per stage to be sealed. In a gas turbine housing, which consists of two halves, which engage in a parting line, the sealing elements are preferably arranged so that in each case a sealing element extends along one of the two housing halves. As a result, in particular a expandability or interchangeability in a service operation on the gas turbine is facilitated. Preferably, the sealing element is designed as an annular plate with extending in the radial direction surface having an outer edge and an inner edge. Such an annular metal sheet is particularly easy to manufacture.

Further preferably, the outer edge is arranged in respectively corresponding platform grooves which are arranged in the side facing away from the hot gas channel from a respective platform of vanes of the vane ring or a guide ring located radially outside the blade ring and the outer edge in a carrier groove extending in a vane carrier. Vanes have an airfoil that is bordered by a platform. This platform serves to shield the hot gas from the vane carrier. Attached to the platform is a fixture that secures the vane to the vane support. In the axial direction adjacent to a vane ring, a blade ring, the rotor side also leads through platforms on the blades, the hot gas. The surface of the hot gas passage adjacent the vane support is shielded from the hot gas by guide rings facing the rotating blade tips of the blades. By grooves in the vanes of a vane ring, the outer edge of the annular sealing plate can be performed. The outer edge is guided in a carrier groove extending in the guide vane carrier. For installation of the sealing element thus only one insertion into said grooves is required or the sealing element is inserted into the Leitschaufelträgernut and then the vanes mounted so that the sealing element comes to lie in the platform grooves.

Preferably, the sealing element with a pressing on its surface screw, the sealing element against the opposite Plattformnuten sidewall and Trägerernuten sidewall presses, tense. With such an active approach of the sealing element a secure, independent of the operating condition sealing is achieved. More preferably, the sealing element with a plurality of screws, preferably per blade of a blade ring a screw braced.

Vanes typically have an entanglement with which they are hooked into the vane carrier. Such a hooking then defines an axial fixed point by an axial contact surface between hooking and Leitschaufelträger. Preferably, the sealing element is arranged in the region of the axial fixed points. This position of the sealing element is particularly advantageous in the above-described active approach of the sealing element, since thermal displacements in the region of the axial fixed point are small.

If no active approach of the sealing element is selected, then the sealing element is preferably arranged away from the region of the axial fixed points. Due to the large temperature differences at standstill and operating state, considerable thermally induced shifts of the blade platforms or guide rings relative to the guide blade carrier result here. By loosely inserting the sealing element in the platform or Leitschaufelträgernuten a passive approach is achieved here just by these thermal shifts. The sealing element is pressed during thermal displacement against the groove walls so that no secure seal is achieved. Further preferably, in addition to the groove walls in the guide blade carrier, a further projection extending in the circumferential direction is arranged as an axial contact surface for the sealing element. In the above-described active approach for the sealing element, it is preferable to first complete the vane ring during installation by installing the guide vanes, and then then to install the adjacent guide rings.

The invention will be explained in more detail by way of example with reference to the drawings. Like reference numerals have the same meaning in the various figures.

They show partly schematically and not to scale:

FIG. 1 shows a gas turbine,

FIG. 2 shows a cross section through the turbine part of a gas turbine, FIG.

3 shows a detail of a longitudinal section through the

Hot gas duct of the gas turbine,

Figure 4 is an enlarged view with a sealing element of Figure 3, Figure 5 shows a further detail of a longitudinal section through a gas turbine and

Figure 6 is an enlargement with a sealing element

FIG. 5.

FIG. 1 shows a gas turbine 1. The gas turbine 1 has a compressor 3, a combustion chamber 5 and a turbine part 7 directed in succession along a turbine axis 10. The compressor 3 and the turbine part 7 are arranged on a common shaft 9 extending along the turbine axis 10. In the turbine part 7 extends a conically expanding hot gas channel 12. In this hot gas duct 12 protrude guide vanes 11 and blades 13 into it. A plurality of vanes 11 are disposed adjacent to each other in a vane ring 14 in the circumferential direction. A plurality of blades 13 are arranged in a blade ring 16 circumferentially adjacent to each other. Leitschaufelkränze 14 and blade rings 16 alternate in the hot gas duct 12 alternately.

During operation of the gas turbine 1, ambient air is sucked in by the compressor 3 and compressed to compressor air 15. The

Compressor air 15 is supplied to the combustion chamber 5 and is burnt there by adding fuel to a hot gas 17. The hot gas 17 flows through the hot gas channel 12 and thus past the guide vanes 11 and the rotor blades 13. In this case, the shaft 9 is set in rotation, since the blades 13 absorb kinetic energy from the hot gas 17 and transmitted to the shaft 9, with which they are firmly connected. The energy thus obtained from the hot gas 17 may, for. B. are transmitted to a generator for power generation.

Figure 2 shows a cross section through the hot gas channel 12. A portion of the blade ring 16 and a portion of the vane ring 14 are shown. A formed as an annular plate seal member 35 extends between the vane ring 14 and the blade ring 16 in the circumferential direction over half of a circle 41 which is perpendicular to the turbine axis 10. A similar sealing element 35 runs along the second half of the circle 41, so that both sealing elements 35 form a closed circle. At a parting line 42, the two sealing elements 35 meet each other. The parting line 42 corresponds to a joint not shown in detail for the half-way division of the hot gas duct 12 enclosing the gas turbine housing. The sealing element 35 is flat, with a plan view of the surface F is shown. The surface F is bounded by an outer edge 37 and an inner edge 39 of the sealing element 35.

FIG. 3 shows a detail of a longitudinal section through the hot gas channel 12. A guide blade 11 is shown, which is enclosed in the axial direction on both sides by a respective guide ring 51. A sealing element 35 is formed according to Figure 2. The exact arrangement will be described with reference to FIG. The vane 11 is supplied to cooling air 53 from a first pressure level. The guide ring 51 is supplied with cooling air 55 from a second pressure level. The pressure level of the cooling air 53 is higher than that of the cooling air 55, since there is a higher cooling requirement for the guide vane 11 located further forward in the direction of flow of the hot gas 17 than for the guide ring 51 located farther downstream. This axial graduation of the pressure levels of cooling air is a Another reason is the greatest possible reduction of interference of hot gas in the cooling air 53, 55, to avoid consequent heating of the cooling air and thus a lower cooling ability. The sealing element shown here is pressed by means of an active approach against axial surfaces, whereby the sealing effect is generated. This will be explained in more detail with reference to FIG.

Figure 4 shows an enlarged section of Figure 3 with the sealing element 35. In a platform 87 of the guide vane 11 is on the side facing away from the hot gas a circumferentially extending groove 85 is introduced. The guide blade 11 on the side facing away from the hot gas channel 12 is opposite a guide vane carrier 79. In Leitschaufelträger 79 is in the radial direction of the platform groove 85 opposite a Leitschaufelträgernut 83 also extending in the circumferential direction. The sealing element 35 is a correspondingly formed in FIG 2 annular metal strip whose inner edge 37 engages in the platform groove 85. The outer edge 39 of the sealing member 35 is located in the Leitschaufelträgernut 83. Between the guide blade 11 and an adjacent guide ring 51 are further circumferential seals 91 is introduced, the gap between the guide ring 51 and the platform 87 between two vanes 11 of a Seal the vane ring. The sealing element 35 is pressed by means of a pressing device 61 against the side walls on the one hand of the platform groove 85 and on the other side of the guide blade carrier groove 83. For this purpose, a pressure wedge 65, which is guided in a groove 67 of the pressing device 61, pressed by means of a screw 63 approximately in the radial center of the sealing element 35 against this.

The axial position of the sealing element 35 is selected in the region of an entanglement 71 of the guide blade 11. These

Verhakung 71 serves to assemble the vane 11. Furthermore, with this entanglement 71 by an axial contact surface, an axial fixed point 73 defined as well as a radial fixed point 75 by means of a radial approach surface. In the region of the axial fixed point 73, thermal expansions of the platform 87 of the guide blade 11 relative to the guide blade carrier 79 are relatively small, so that a good sealing effect is achieved by the active attachment of the sealing element 35, independently of the operating state of the gas turbine. The guide ring 51 is also arranged by a hooking 77 in the guide vane carrier 79. In prior art configurations, i. without the sealing member 35, an axial seal by means of entanglements 71 and 77 has often been attempted to be achieved. For this purpose, comparatively small tolerances had to be maintained in order to achieve the smallest possible gap of the entanglements 71, 77 in the guide vane carrier 79. This complicates the production and assembly. By means of the sealing element 35 is now given a simpler and more cost-effective and yet safe sealing possibility for axial sealing.

FIG. 5 shows a further detail of a longitudinal section through the hot gas channel 12. Again, a guide blade 11 is shown, which is enclosed on both sides by guide rings 51 in the axial direction. Here, however, the sealing element 35 is far away from the axial fixed point 73 arranged. In addition, no device for pressing the sealing element 35 is provided on the groove walls. This will be described in more detail with reference to FIG.

FIG. 6 shows a cutout with the sealing element 35 from FIG. 5. As already described above, the sealing element 35 is again arranged with its inner edge 39 in a platform groove 85 and with its outer edge 37 in a Leitschaufelträgernut 83. In the vane support 79, an additional shoulder 91 is formed as an axial contact surface so that it lies approximately in the region of the radial center of the sealing element 35. The platform groove 85 is arranged in the guide ring 51 in the example shown here. The guide ring 51 is movable relative to the vane support 79 to avoid thermal stresses. In operation, temperature differences result in a displacement of the guide ring 51 relative to the guide blade carrier 79. In this way, the sealing element 35 is bent and pressed against the projection 91 in the guide blade carrier 79. This form of passive approach of the sealing element 35 leads to a good sealing effect, at the same time a very low expenditure on equipment is required.

When mounting the gas turbine 1 or even during a service operation, the sealing element 35 is simply inserted into the Leitschaufelträgernut 83 and the guide vanes 11 or the guide rings 51 mounted, depending on which ^' the components has the corresponding platform groove 85. Subsequently, either the guide vanes 11 or the guide rings 51 are then mounted in each case, which adjoin the previously installed components.

Claims

claims

1. Along a turbine axis (10) directed axial gas turbine (1), comprising a compressor (3), a combustion chamber (5) and a turbine part (7), wherein in the turbine part (7) axially successively Leitschaufelkränze (11) and blade rings (13 In operation, a hot gas (17) flows through the hot gas channel (12) and the vane rings (11) and blade rings (13) are cooled with cooling air (53, 55) whose pressure level is in Flow direction of the hot gas (17) decreases, dadurchge gekennzeichn et, that between at least one vane ring (11) and a directly adjacent blade ring (13) a sealing element (35) is arranged, which seals the various pressure levels against each other and at least a quarter of a perpendicular the turbine axis as a center extending circle (41) integrally extends.

2. Gas turbine (1) according to claim 1, wherein the sealing element (35) extends around the half of the circle (41).

3. Gas turbine (1) according to claim 1 or 2, wherein the sealing element (35) as an annular plate with extending in the radial direction surface F with an outer edge (37) and an inner edge (39) is formed.

, A gas turbine (1) according to claim 3, wherein the inner edge (39) is formed in respectively corresponding platform grooves (85) in the side facing away from the hot gas channel (12) from a respective platform (87) of vanes (14) of the vane ring (11). or a guide ring (89) lying radially outside the blade ring (13) and the outer edge (37) being arranged in a carrier groove (83) extending in a guide blade carrier (79).

5. gas turbine (1) according to claim 4, wherein the sealing element (35) with a pressing on its surface F screw (65) which presses the sealing element (35) against the opposite Plattformnutenseitenwand and Trägerernuten sidewall, is braced.

6. Gas turbine (1) according to claim 5, wherein the guide vanes (14) each having an axial fixed point (73) on which they are fixed by means of a suitable entanglement (71) in the guide vane support (79) against axial displacement, wherein the sealing element (35) in the region of the axial fixed points (73) is arranged.

7. Gas turbine (1) according to claim 3, wherein the guide vanes (14) each having an axial fixed point (73) on which they are fixed by means of a suitable entanglement (71) in the guide blade carrier (11) against axial displacement, wherein the sealing element (35) is arranged away from the region of the axial fixed points (73).