EP2025867A1 - Rotor for an axial flow engine - Google Patents

Abstract

The rotor (12) has multiple rotor discs (10,14,16,24,26) that are arranged in stacks and clamped together with a tie rod (58). The rotor discs (24,26) of the rotor comprises a smaller outer diameter than one of the neighboring rotor discs (16) and that the difference in diameter is compensated by a drum (28) surrounding the rotor disc with the smaller outer diameter as a ring. An independent claim is included for a gas turbine with a compressor.

Description

The invention relates to a rotor for an axial flow-through turbomachine, with a plurality of stacked rotor disks, which are clamped together axially by means of at least one tie rod.

Generic rotors have long been known from the general state of the art. The rotor disks used in the rotor are known to carry on their outer sides in a ring arranged blades, by means of which a working medium compressible or by means of which the energy contained in a working medium can be converted into the rotational movement of the rotor. The adjacent stacked rotor discs are braced together by at least one tie rod. For this purpose, the tie rod extends through the rotor discs and is biased by nuts screwed end. The tie rod ensures the firm juxtaposition of the rotor discs.

Furthermore, from the DE 199 14 227 B4 It is known that a welded-together rotor can have an outer drum-shaped heat-insulating jacket for protecting the inner region of the rotor.

In general efforts to increase the efficiency and performance of gas turbines used to generate energy, relatively large compressor mass flows are required with high compressor pressure ratios. Larger compressor mass flows occur, for example, in compressors of gas turbines whose rated power is greater than 50 MW. The compressor pressure ratio is greater than 1:16. Due to the comparatively high pressure ratio, the temperature of the compressed air rises to several hundred degrees Celsius. The high air temperature heats the adjacent elements of the compressor, especially in the area of the rear compressor stages, so that nowadays due to the increased pressure conditions the materials used so far can no longer sufficiently withstand the now occurring temperatures. When using more temperature-resistant materials for rotor disks, however, due to the size of compressors with large mass flows further disadvantages in the strength and workability, so that they are only partially suitable and only limited use. In addition, the more temperature-resistant materials are also more expensive.

The object of the invention is therefore to provide a rotor for an axially flow-through turbomachine, preferably for a high pressure compressor with a pressure ratio of greater than 1:16 and a comparatively large compressor mass flow, in which, while maintaining the concept with stacked adjacent rotor discs cost design can be specified , At the same time, the rotor should have a particularly long life. Furthermore, the efficiency of the compressor should be further improved.

The aforementioned objects are achieved by a rotor of the type mentioned, in which an at least two adjacent rotor discs annularly encompassing drum is provided with an endless surface on its inner surface web, which web is axially braced between two of the encompassed rotor discs.

According to the invention, a multi-part rotor, as seen in its radial direction, is thus proposed, in which the inner rotor disks can be made of a different material than the drum provided on the outside. The most suitable materials can thus be selected for the different loads of drum and rotor disks. Thus, both the drum and the encompassed rotor discs can each be made of a material with which a particularly long life of the component can be achieved. At the same time, a device indicated, by which the drum can be rotatably connected to the rotor discs. A slip-laden relative movement between the outside arranged drum and radially further inwardly arranged rotor discs is thus not possible, whereby a total of transmitted between the components to be transmitted torques and forces can be passed lossless. In addition, the drum allows the sealing of gaps between the two rotor disks, so that at this point in the prior art possibly existing leakage flow can be suppressed here. This increases the efficiency of the compressor.

In addition, due to their reduced diameter, the rotor disks can also be better examined for possibly existing material inclusions, imperfections and / or cracks by means of the known ultrasonic methods than the rotor disks with a larger diameter known from the prior art.

Advantageous embodiments are specified in the subclaims.

Preferably, the two - seen in the axial direction of the rotor - the outer of the rotor disks encompassed by the drum are hooked to it for receiving centrifugal forces. The drum thus encompasses at least two rotor disks, wherein each of the two outer rotor disks, seen in the axial direction, each provide an entanglement at their outer peripheries which can be brought into engagement with a corresponding hook or groove provided on the inside of the drum. The direction of entanglement is selected so that the centrifugal forces acting on the drum can be at least partially absorbed by the rotor disks. As a result, the centrifugal force occurring in this section of the rotor can be evenly distributed from the drum to the rotor discs arranged radially further inside. Due to the required mountability of the stackable construction with radially inward arranged rotor disks and radially outwardly arranged drum, it is necessary that at least the two outer rotor disks are hooked to the drum. In an arrangement in which the drum engages around only two rotor disks, thus both rotor disks are hooked to the drum.

According to a particularly advantageous embodiment of the invention, the drum is formed of a heat-resistant material than the rotor disks. In particular, this is a particularly inexpensive rotor can be specified because the heat-resistant and cost-intensive material is only to use for the drum. The construction according to the invention is preferably used in the rear stages of an axial compressor, in which particularly high temperatures in the range of greater than 400 ° C occur during the compression process. With a more heat resistant drum, the life of the rotor can at least be maintained, if not extended even further. Since a lower temperature prevails in the interior of the rotor due to the temperature gradients in the drum material than in the air to be compressed, it may be sufficient that the rotor disks are made of a material which meets lower requirements in terms of temperature resistance. Accordingly, the material of the rotor discs can be a cheaper than the material of the drum. For example, the drum may be made of a nickel-based alloy and the rotor disks encompassed by it may be made of a heat-resistant steel or alloy.

In order to be able to specify a particularly firm and reliable connection between the drum and the rotor disks, the web has two opposite flange-like end faces, which abut against flange-like end faces of adjacent rotor disks. Preferably, the end face of the rotor discs is positively against the end face of the web. For example, the positive connection can be produced by means of a Hirth toothing. According to another embodiment it can be provided that the drum has at least one groove for receiving at least one blade. Preferably, the groove is formed as a circumferential groove, so that in the circumferential groove all blades of a blade ring can be used. The use of circumferential grooves allows a particularly large number of blades per ring. In addition, the circumferential grooves are cheaper to manufacture than axially extending slots for blades.

In a particularly preferred variant of the invention, the number of circumferential grooves can be greater than the number of rotor disks encompassed by the drum. So far, it was in the prior art so that each rotor blade stage a rotor disk was provided with a circumferential groove. This caused a comparatively large axial space for mounting the blades on the rotor. Despite the use of the modular rotor concept with rotor disks, the solution proposed can achieve a comparatively short axial installation space for the rotor and for the housing since, for example when using two rotor disks, it is possible to provide three circumferential grooves on the outer circumference of the drum. can be used in the respective blades of different blade rings. Thus, axial space can be saved, which reduces in particular the housing material costs. In addition, the mass of the rotor can be reduced. Overall, therefore, the outside of the drum for receiving arranged in wreath blades is formed, wherein the number of mountable blade rings can be greater than the number of rotor disks encompassed by the drum.

The invention is particularly useful when the rotor is used in a compressor with a pressure ratio greater than 1:16, the compressor preferably being the compressor of a stationary gas turbine used for power generation. Preferably, the rated power of the gas turbine is greater than 50 MW. The invention can in principle in each Section of a compressor can be used. Since the problems mentioned in the prior art occur especially with large rotor disks with an outer diameter of 1200 mm and larger, it is particularly advantageous if in particular such large rotor disks are replaced by the construction according to the invention with compressor disks smaller outer diameter and with a surrounding drum , Thus, the drum according to the invention preferably has an outer diameter of 1200 mm and larger. Of course, the invention can also be used in the sections of the compressor, where - if only compressor discs without a drum would be used - this would have a smaller outer diameter than 1200 mm. Thus, drum outer diameter smaller than 1200 mm are possible.

FIG 1

einen Ausschnitt durch den Längsschnitt durch einen erfindungsgemäßen Rotor und

FIG 2

den gleichen Ausschnitt wie FIG 1 mit einer modifizierten Trommel.

The invention will be explained in more detail with reference to a drawing. Other features and other advantages will be apparent from the description of the figures. It shows:

FIG. 1

a section through the longitudinal section through a rotor according to the invention and

FIG. 2

the same section as FIG. 1 with a modified drum.

The FIG. 1 shows a section through the longitudinal section of a plurality of rotor disks 10 comprehensive rotor 12 of a gas turbine, not shown. The section of the rotor 12 is chosen so that it lies in the high pressure region of the axial compressor of the gas turbine.

The rotor discs 14, 16 are manufactured in a known configuration and have at their outer peripheries 18 each have a circumferential groove extending in the circumferential direction 20, which are provided for receiving blades of the compressor. The rotor disks 14, 16 are flange-like against each other at a contact surface 22, wherein in this contact surface 22nd a Hirth toothing is provided for the positive connection.

Axially to the rotor disk 16 adjacent two further rotor disks 24, 26 are provided, which compared to the rotor disks 14, 16 have a smaller outer diameter. The two rotor discs 24, 26 are encompassed by a longitudinally section T-shaped drum 28. The drum 28 has on its inner side 30 a radially inwardly directed endless circumferential ridge 32, which is provided with two opposite end surfaces 34. The end faces 34 rest on the one hand on the rotor disk 24 and on the other hand on the rotor disk 26 on contact surfaces 36, 38 at. The contact surfaces 36, 38 are structured such that in each case a positive connection in the form of a serration is provided.

Each of the rotor disks 24, 26 has in its outer region an axially extending circumferential hooks 40, 42. The annular hooks 40, 42 each engage in an open towards the end face of the drum 28, arranged in this endless circumferential groove 44, 46 a. The grooves 44, 46 thus each form a receptacle for the hooks 40, 42 arranged on the rotor disks 24, 26.

The drum 28 has on its outer side also in the circumferential direction extending blade holding grooves 48, 50, 52, in each of which blades of a blade ring can be used. The blades have for this purpose to the blade holding grooves 48, 50, 52 corresponding formed blade roots. The blades which can be inserted in the grooves 48, 50, 52 belong to the blade stages which carry out the last pressure increases in the medium to be compressed. Accordingly, the blade holding grooves 48, 50, 52 are arranged the last three compressor blade rings of the compressor. Due to the occurring during the compression of the medium high temperatures in the region of the drum 28, this is made of a heat-resistant material than the encompassed by the drum 28 and thus radially further inside rotor disks 24, 26. The rotor disks 24, 26 can thus be made of a less temperature-resistant material, as in their In addition, the axial distance between the grooves 48 and 50 and between the grooves 50 and 52 in comparison is less than the distance when using three individual rotor disks instead of the drum 28, so that axial Space can be saved in the compressor. The saving of axial space overall allows the construction of a cheaper gas turbine or the construction of a cheaper compressor.

Although the drum 28 is integrally formed and accordingly centered by the rotor disks 24, 26 provided therein, it has been found to be advantageous that each of the rotor disks 24, 26 is hooked to the inside 30 of the drum 28. Even a slight placement of the two axially opposite ends 54, 56 of the drum 28 can thus be avoided. At the same time, the mechanical centrifugal loads resulting from the blades may be at least partially transmitted from the drum 28 to the rotor disks 24, 26 so that the mechanical loads on the drum 28 remain within the allowable limits of the drum material.

Of course, instead of a tie rod 58 extending centrally through the rotor disks 10, it is also possible to provide a number of several tension rods arranged concentrically around the machine axis 60 in order to press the rotor disks firmly against one another.

FIG. 2 shows the same section of the gas turbine as FIG. 1 , wherein like components are labeled with identical reference numerals.

In contrast to FIG. 1 has the in FIG. 2 illustrated drum 28 on a modified web 32. The web 32 according to the in FIG. 2 illustrated second embodiment of the drum 28 extends inwardly not only to those end faces 34 which abut against the contact surfaces 22 of the adjacent rotor disks 24, 26, but beyond this range. Thus, the web 32 may also comprise a further hub region 62, the radial end of which lies substantially further inward than the contact surfaces 22 of the rotor disks 24, 26. In this way, a greater load capacity of the drum 28 can be achieved.

Overall, the invention thus relates to a rotor 12 for an axially flow-through turbomachine with a plurality of stacked rotor disks 10, 14, 16, 24, 26, which are braced by means of at least one tie rod 58 with each other. In order to specify a particularly inexpensive rotor 12 with a compact design, which is designed in particular for particularly high pressure ratios with comparatively large compressor mass flows, it is proposed that an at least two adjacent rotor disks 24, 26 annularly encompassing drum 28 having a continuous on its inner surface 30 web 32nd is provided, which web 32 between two of the encompassed rotor disks 24, 26 is axially braced. Only the drum 28 may be made of a more heat-resistant material. The encompassed by her rotor discs 24, 26, however, can be made of a cheaper material, resulting in cost savings. Furthermore, the drum 28 can carry at least one blade ring more than rotor disks 24, 26, which are encompassed by it.

Claims (13)

Rotor (12) for an axial flow-through turbomachine, with a plurality of stacked rotor disks (10, 14, 16, 24, 26), which are clamped together by means of at least one tie rod (58),
characterized in that an at least two adjacent rotor discs (24, 26) annularly encompassing drum (28) with a on its inner surface (30) endlessly circumferential web (32) is provided, which web (32) between two of the encompassed rotor discs (24, 26) is axially braced. Rotor (12) according to claim 1, wherein the two - seen in the axial direction of the rotor (12) - outer of the drum (28) encompassed rotor discs (24, 26) are hooked with this for receiving centrifugal loads. Rotor (12) according to claim 2, in which the two rotor discs (24, 26) have on their peripheral side an annular, axially extending hook (40, 42) which in each case into a groove (44) provided on the drum (28) , 46) intervene. A rotor (12) according to claim 1, 2 or 3, wherein the drum (28) is formed of a more heat-resistant material than the rotor disk (24, 26). A rotor (12) according to any one of the preceding claims, wherein the web (32) has two opposed flange-like end surfaces (34) which abut flange-like end surfaces (36, 38) of the adjacent rotor disks (24, 26). Rotor (12) according to claim 5, in which the end faces (36, 38) of the rotor discs (24, 26) and the end faces (34) of the web (32) lie positively against one another. Rotor (12) according to claim 6, wherein the positive connection is formed by means of a Hirth toothing. A rotor (12) according to any one of claims 1 to 7, wherein the drum (28) has at least one groove (48, 50, 52) for receiving at least one blade. Rotor (12) according to claim 8, wherein the groove (48, 50, 52) is formed as a circumferential groove. A rotor (12) according to claim 9, wherein there are provided a number of circumferential grooves (48, 50, 52) greater than the number of rotor disks (24, 26) engaged by the drum (28). A rotor (12) according to claim 8, wherein the outside of the drum (28) is adapted to receive wafers arranged in rings, the number of wafers which are mountable being greater than the number of rotor disks (24, 24) engaged by the drum (28). 26). Compressor with a rotor according to one of the preceding claims. Gas turbine with a compressor according to claim 12.

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