EP2011965B1 - Method and device for clamping bladed rotor discs of a jet engine - Google Patents

Description

The invention relates to a jet engine with a device for clamping bladed rotor disks and a method for clamping bladed rotor disks with the device in a jet engine.

In turbine engines, the turbine and compressor are usually arranged on a shaft. In particular, in axial flow design, the compressor consists of several rotor discs, each carrying a row of blades and are welded or bolted together.

In some compressors, only part of the compressor on the inlet side consists of blisks, each having a disk integrally formed with the associated blades. Significant weight savings can be achieved especially in the front part of the drum. For better interchangeability and repair these usually quite expensive individual components are preferably screwed instead of welded. For this single flanges come into question, but add weight and worsen the rotor dynamic behavior.

Furthermore, arrangements are also known in which all the rotor disks of the compressor or the entire rotor are clamped by tie rods.

When clamping a larger number of disks, however, the problem arises that a sufficiently large biasing force over the entire operating range must be maintained, which requires a good coordination of the thermal behavior of the rotor and tie rods. In addition, the tie rod must have good rigidity.

When using tie rods also arise problems in disassembly of the blisks in case of damage. It is always necessary to disassemble the entire rotor or at least the entire compressor in order to exchange the blisks. In addition, existing vortex rectifiers, e.g. in tubular construction, difficult to install and remove.

The US 6,267,553 B1 discloses a gas turbine with a high pressure compressor in which there are a plurality of tubular tie rods. The tie rods are guided through openings in the rotor disks, which are arranged radially around the center of the disk. The bracing is done by screws, which are screwed into the internal thread of the tie rods.

The US 5,537,814 describes a tie rod for a gas turbine engine that clamps not only the rotor disks of the compressor but also those of the turbine. The tie rod here is a hollow shaft, which is bolted to the blisk in the first stage. Downstream of a radial compressor impeller, a nut is threaded onto a thread of the tie rod to tension the tie rod.

The DE 10 2005 052 819 A1 discloses a compressor rotor of a jet engine with all features of the preamble of Anprüche 1 and 9, wherein the compressor rotor is composed of Blisks and braced by a central tie rod.

The passage of a tie rod through the discs requires additional holes in the discs or increased disc inside diameter, which increases the weight of the disc.

An undivided shaft also allows no separate modular design of compressor and turbine. The air passage of a possibly existing vortex rectifier is difficult.

The length of the tie rod and various materials and expansion coefficients of the discs complicate the thermal balance between the shaft and rotor and thus maintaining a uniform biasing force. The variable during operation biasing force and the length of the tie rod deteriorate the rigidity of the rotor.

For the lowest possible thermal stress and therefore low weight of the disks, the temperature gradient along the disk should be relatively low. However, since the temperature at the rotor outer diameter increases from stage to stage, the uniform temperature inside the rotor leads to considerable temperature gradients for individual disks.

The invention is therefore an object of the invention to provide a device for clamping bladed rotor discs in a jet engine, which is easy to assemble and disassemble.

This object is achieved by a jet engine with a device for clamping bladed rotor disks sowhol with the features of claim 1 and, alternatively, this with the features of claim 9. Furthermore, the object is achieved by a method for clamping bladed rotor disks having the features of claim 15. The dependent claims contain advantageous developments of the invention.

The clamping of the blisks with the help of a tie rod allows easy assembly and disassembly both during installation and during maintenance or in case of damage. The blisks can be easily installed or removed without, e.g. multiple glands must be solved. The fact that the blisks are clamped separately from the other rotor discs, resulting in the tie rod a short overall length and thus good rigidity.

The tie rod is substantially tubular, disposed within central apertures in the blisk-formed rotor discs, and fixedly connected to a shaft which is driven by at least one turbine section. The existing in the blisks anyway central openings can be used well for mounting and dismounting of the tie rod, and there are no additional holes in the discs required. The tie rod is not passed through the rotor discs following in the flow direction on the Blisks, so that the disc diameter of these rotor discs need not be increased.

The blisks are by means of the tie rod between at least a first arrangement, which is upstream of the Blisks, and at least one second arrangement, downstream of the Blisks is located and connected to a rotor disk which is adjacent to the Blisks, clamped. In this way it is ensured that the blisks can be clamped independently of the connection between the other rotor disks.

In this case, the first arrangement comprises a stop arrangement and the second arrangement comprises a clamping arrangement. Due to the clamping arrangement, the blisks can be clamped in a simple manner relative to the stop arrangement.

The stop assembly includes upstream of the blisk an extension of a blisk of the first stage adjacent to a stop on the tie rod. This represents a simple embodiment of a stop arrangement.

The tensioning arrangement preferably comprises at least one tensioning element which serves to transmit power between the tensioning armature and the rotor disk.

The tensioning element is substantially annular and has a flange-shaped, radially outwardly directed attachment portion, an axial tubular center portion and a radially inwardly directed tension portion. As a result, a power transmission is possible, which takes place uniformly over the circumference.

The radially outwardly directed attachment portion of the tension member is secured to a portion of the rotor disc which is adjacent to the blisks downstream. As a result, the voltage generated in the clamping element and in the tie rod is transmitted to the rotor disk.

The radially outwardly directed attachment portion of the clamping element is located on a radially inner portion attached to the rotor disk, which is adjacent to the Blisks downstream.

Advantageously, the attachment portion of the tensioning element is attached to a radially inner portion of the rotor disc, which is adjacent to the Blisks downstream. The power transmission takes place in this case without major deflections.

Preferably, the tie rod has at its downstream end a shoulder whose outer diameter is smaller than the outer diameter of an upstream adjacent portion of the tie rod, and the radially inwardly directed clamping portion of the clamping element enclosing the shoulder radially, wherein the radially inwardly directed clamping portion of the clamping element axially displaceable relative to the shoulder and spaced from an axial boundary of the shoulder in operation and adjacent to the clamping means. This arrangement offers the advantage of a low construction cost and good mounting and dismounting.

The tensioning means may in particular be a tie-rod nut, which can be screwed onto an external thread on the shoulder of the tie rod. Due to the tie rod nut, the tension between the blisks is easily adjustable.

Alternatively, the first arrangement upstream of the blisk comprises a tensioning arrangement with a tensioning means and the second arrangement downstream of the blisk comprises at least one screw connection between the tensioning bolt and the rotor disk. This alternative offers good accessibility to the clamping device.

Preferably, the upstream end of the tie rod radially adjoins from the inside to a tubular upstream Prolonging the first level blisk. The tensioning means is axially adjacent to the extension and radially to the tensioning ring adjacent to the upstream end of the tie rod, and the tension anchor has a flange at its downstream end which attaches to the rotor disc which is adjacent to the blisk downstream is. Here, the first arrangement serves to generate a voltage with respect to the rotor disk, which is adjacent to the Blisks downstream, and has a very low construction costs. The clamping device is easily accessible from the compressor inlet side.

The tie rod has a conical extension in the flow direction, and the flange of the tie rod is attached to a radially outer portion of the rotor disc, which is adjacent to the Blisks downstream. This allows for clamping of the blisks near the blade and good sealing between the blisks. When attached to the radially outer portion of the rotor disc, which is adjacent to the Blisks downstream, occurs a low bending stress of the rotor disc during tensioning of the tie rod.

The upstream end of the tie rod is fastened to the tie rod ring with at least one screw connection, which has an external thread, and the tensioning means is a tie nut, which is screwed onto the external thread of the Zugankerrings. The tie-rod nut makes it easy to adjust the tension in the tie rod ring, in the screw connections and in the tie rod.

Preferably, the clamping means simultaneously clamps a radially inner bearing ring of a Zugankerlagers. As a result, no additional components for mounting the bearing ring are required.

At least one tube-type vortex rectifier may be attached to the rotor disc adjacent the blisks downstream. The vortex rectifier flows compressed, heated air in the radial direction from outside to inside and is passed to the turbine for cooling. By placing the vortex rectifier outside the blisks, local heating in the disk area of the blisks is avoided. Also, the attachment of the vortex rectifier outside the blisks is easier.

In addition, the object is achieved by a method for clamping blisks using the jet engine described above, in which the blisks are releasably clamped by means of the tie rod and the other rotor discs are connected separately and independently of the tie rod firmly together. The separate clamping of the blisks allows for easy assembly and disassembly of the blisks.

In particular, the blisks are clamped by means of the tie rod between an assembly located upstream of the blisk and an assembly located downstream of the blisk and connected to a rotor disc adjacent the blisks downstream. By the two arrangements, the application of a force on the tie rod is made possible.

The tie rod is tensioned by the second arrangement located downstream of the blisks.

Alternatively, the tie rod can be stretched from the first arrangement located upstream of the blisk. Here, a good accessibility of the arrangement is given.

Fig. 1

die erste Ausführungsform mit einer ersten Vorrichtung, bei der der Zuganker von der stromab der Blisks liegenden Seite gespannt wird,

Fig. 2

eine Detailansicht der Spannvorrichtung der ersten Ausführungsform,

Fig. 3

die zweite und alternative Ausführungsform mit einer zweiten Vorrichtung, bei der der Zuganker von der stromauf der Blisks liegenden Seite gespannt wird, und

Fig. 4

eine Detailansicht der Spannanordnung der zweiten Ausführungsform.

Two alternative examples of the jet engine according to the invention with a device for clamping bladed rotor disks are based on the FIGS. 1 to 4 explained in more detail. It shows:

Fig. 1

the first embodiment with a first device in which the tie rod is tensioned by the side lying downstream of the blisk,

Fig. 2

a detailed view of the clamping device of the first embodiment,

Fig. 3

the second and alternative embodiment with a second device in which the tie rod is stretched from the side lying upstream of the Blisks, and

Fig. 4

a detailed view of the clamping arrangement of the second embodiment.

In Fig. 1 1, a rotor 1 of a nine-stage axial compressor is shown, which has six rotor disks formed as blisks 6, three rotor disks 4, 9 with rotor blades 5, and at least one vortex rectifier 38. In addition, the rotor 1 has a first device 3 of the jet engine according to the invention for clamping the blisks 6.

On the rotor 1 of the compressor, the first six bladed rotor disks 6 in the flow direction 40 are designed as blisks 6. The blisks 6 are bladed rotor disks in which one disk is integrally formed with the associated blades. On the Blisks 6 follow in the flow direction 40 three bladed Rotor disks 4, 9, the blades 5 are releasably attached. The rotor disk 9 adjoins the last blisk 6 in the flow direction 40. However, it is also possible to use a different number of blisks 6 and rotor disks 4, 9. The number of levels is variable. Each blisk 6 has close to the rotor blades 5 at least one axial extension 44, which abuts at least one adjacent blisk 6 respectively. The rotor disk 9 abuts close to the rotor blades 5 with an axial extension 43 to the last in the flow direction 40 Blisk 6.

In the Fig. 1 and Fig. 2 illustrated first embodiment of the device 3 comprises a tie rod 12, a stop assembly 27 and a clamping assembly 28, which in Fig. 2 is shown enlarged.

The tie rod 12 is tubular and has at its upstream end 21 a radially inwardly recessed shoulder 42 with a stop 16. At its downstream end 14 (FIG. Fig. 2 ), a shoulder 15 is provided, which is set back radially inwardly relative to an axial section 19 of the tie rod 12 and is limited by an axial boundary 17 against the flow direction 40. The shoulder 15 may also have a sprocket. An external thread 18, whose outside diameter is smaller than the outside diameter of the shoulder 15, adjoins the shoulder 15 downstream.

The tie rod 12 is disposed centrally within openings 8 in the blisks 6. It adjoins at its upstream end 21 in the stop assembly 27 to a blisk 6 of the first stage of the compressor. At its downstream end 14 of the tie rod 12 is connected via the clamping assembly 28 with the downstream of the Blisks 6 rotor disk 9.

The stop assembly 27 is located at the upstream end 21 of the tie rod 12 and is formed by a stop 16, a shoulder 42 and an extension 7 of the blisk 6 of the first stage of the compressor.

The stop 16 forms an axial boundary of the shoulder 42 in the flow direction 40. The extension 7 of the blisk 6 of the first stage of the compressor extends axially against the flow direction 40 to the stop 16. It encloses the shoulder 16 radially, but it is axially displaceable ,

In the Fig. 2 enlarged clamping arrangement 28 includes the shoulder 15 of the tie rod 12, a clamping element 33, a tie nut 37, a plurality of screw 29 and adjoins the rotor disc 9, which is adjacent to the Blisks downstream, at.

The clamping element 33 comprises a, a flange forming, radial mounting portion 34, a center portion 35 and a clamping portion 36th

The center portion 35 of the clamping element 33 is tubular and extends in the mounted state axially and parallel to the tie rod 12. The flange-like mounting portion 34 is directed from the downstream end of the clamping element 33 from radially outward. The clamping portion 36 is directed radially inward from the upstream end of the clamping element 33 and may have a toothed ring.

The clamping element 33 is fastened with its fastening section 34 by means of screw connections 29 to an inner section 10 of the rotor disk 9. The clamping portion 36 protrudes in the assembled state of the clamping device 28 parallel to the axial boundary 17 and in the axial direction of this radially inwardly and surrounds the shoulder 15, wherein the clamping portion 36 but against the shoulder 15 is axially displaceable. If sprockets are present on the shoulder 15 and on the tensioning section 36, the toothing of the tensioning section 36 engages in the toothing of the shoulder 15. In the flow direction 40, the tie rod nut 37, which is screwed onto the external thread 18, adjoins the tensioning section 36.

For clamping the blisks 6, the radially outwardly directed fastening section 34 of the clamping element 33 designed as a flange is first fastened by means of a plurality of circumferentially distributed screw connections 29 on the inner section 10 of the rotor disk 9, which adjoins the blisk downstream. Next, the blisks 6 are pushed onto the tie rod 12. The tie rod 12 is then inserted with the shoulder 15 in the annular clamping element 33. Finally, the tie nut 37 is screwed onto the external thread 18 of the tie rod 12 and tightened.

When tightening the tie rod nut 37, a tensile force in the clamping element 33 is generated via the radially inwardly directed clamping portion 36. At the same time, the tie rod nut 37 generates a tensile force in the tie rod 12 via the external thread 18.

The tensile force in the clamping element 33 is transmitted from the radially inwardly directed clamping section 36 via the axial center section 35, the radially outwardly directed fastening section 34 and the screw connections 29 to the radially inner section 10 of the rotor disk 9. From there, the force in the rotor disk 9, which is adjacent to the Blisks downstream, in the radial direction outward into the axial extension 43rd the rotor disk 9 forwarded. The tensile force in the tie rod 12 is transmitted along the tie rod 12 on the shoulder 16.

The two tensile forces cause compressive forces between the axial extension 43 of the rotor disk 9, the abutting blisks 6 and the abutment 16 of the upstream abutment arrangement 27 via the extensions 44. These compressive forces press the blisks 6 against the extensions 44 of the blisks 6 near the blades 5 axially together and cause the restraint.

The compressive forces must be large enough to hold the blisks 6 together. But they must also not be too large, so that the tensile stressed components of the device 3, namely the tie rod 12, the external thread 18 on the tie rod 12, the clamping element 33, the screw 29 or the internal thread of the tie nut 37 are not overloaded during operation.

In the Fig. 3 and 4 shows the second and alternative embodiment of the device 3 of the jet engine according to the invention, in which the rotor 1 of the compressor is constructed the same as in Fig. 1 ,

The second embodiment of the device 3 comprises a tie rod 47, a plurality of screw connections 41 and a clamping arrangement 30, which in Fig. 4 is shown enlarged.

In contrast to the tie rod 12 of the first embodiment, the tie rod 47 has a conical enlargement 20 in the flow direction 40. At its upstream end 21 of the tie rod 47 has a radially inwardly directed flange 45. The conical extension points its downstream end a flange 13 which is directed radially outward.

The tie rod 47 is arranged centrally within openings 8 in the blisks 6. It adjoins at its upstream end 21 radially from the inside to an axial extension 7 of the blisk 6 of the first stage of the compressor. At its downstream end, the tie rod 47 is connected via a plurality of screw connections 41 distributed over the circumference to the rotor disk 9 adjoining the blisks 6 and adjoining the blisks downstream.

The screw connections 41 are distributed in the circumferential direction on a radially outer section 11 of the rotor disk 9, which adjoins the blisks downstream. By means of the screw connections 41, the flange 13 is fastened to the rotor disk 9 at the end of the conical enlargement 20 of the tie rod 47.

The upstream tensioning assembly 30 is in Fig. 4 shown enlarged and includes a Zugankerring 24, a plurality of screw connections 32, a first spacer ring 31, a second spacer ring 39, a Zugankerlager 25 and a Zugankermutter 37th

The Zugankerring 24 is annular and has the same outer diameter as the tie rod 47. The Zugankerring 24 has at its adjacent to the tie rod 47 end a radially inwardly directed flange 46. The Zugankerring 24 also has a shoulder 23 whose outer diameter is smaller than the diameter of the upstream end 21 of the tie rod 47. At the upstream end of Zugankerrings 24 is an external thread 22 whose diameter is smaller than that of the paragraph 23rd

The first spacer ring 31 is annular and has substantially the same inner diameter as the axial extension 7 of the blisk 6 of the first stage of the compressor. The second spacer ring 39 is also annular.

The tie rod bearing 25 is a ball bearing with a radially inner bearing ring 26th

The Zugankerring 24 abuts in the axial direction of the upstream end 21 of the tie rod 47 and forms an axial extension of the tie rod 47 against the flow direction 40. The Zugankerring 24 is secured by means of several screw 32 on the flange 45 of the tie rod 47. In the radial direction, the Zugankerring 24 abuts the first spacer ring 31 from the inside.

The extension 7 encloses the tie rod 47 in the radial direction, wherein the extension 7 is displaceable relative to the tie rod 47.

The first spacer ring 31 encloses the tie rod 47 in the region of the flange 45 and the Zugankerring 24, but with a displacement in the axial direction is given. The first spacer ring 31 adjoins the extension 7 of the blisk 6 of the first stage of the compressor at its downstream end. At its upstream end of the spacer ring surrounds the shoulder 23 of the Zugankerrings 24 in the radial direction, but with a displacement in the axial direction is given.

The inner bearing ring 26 of the Zugankerlagers 25 is arranged displaceably in the axial direction on the shoulder 23 of the Zugankerrings 24. The inner bearing ring 26 adjoins the first spacer ring 31 downstream and to the second spacer ring 39 upstream.

The second spacer ring 39 also encloses the shoulder 23 of the Zugankerrings 24. The second spacer ring 39 protrudes beyond the upstream end of the paragraph 23 out.

Adjacent to the second spacer ring 39, the clamping nut 37, which is screwed onto the external thread 22 of the Zugankerrings 24.

To clamp the blisks 6, the flange 13 is first attached to the downstream end of the tie rod 47 on the rotor disk 9, which adjoins the Blisks downstream. This is done by means of the screw 41. Next, the Blisks 6 are pushed onto the tie rod 47. The Zugankerring 24 is then attached by means of the screw 32 on the tie rod 47. Then, the first spacer ring 31, the inner bearing ring 26 and the second spacer ring 39 are pushed over the Zugankerring 24. Finally, the tie rod nut 37 is screwed onto the external thread 22 of the Zugankerrings 24 and tightened.

When tightening the tie rod nut 37 41 tensile forces are generated in the tie rod 47, in Zugankerring 24 and in the screw 41. The tensile forces are transmitted from the screw 41 to the rotor disk 9.

At the same time arise in the second spacer ring 39, the inner bearing ring 26, the first spacer ring 31 and the extensions 44 of the Blisks 6 near the blades 5 pressure forces that clamp the Blisks 6.

The compressive forces must be large enough to hold the blisks 6 together. But you must not too big be so that the claimed to train components of the device 3, namely the Zugankerring 24, the external thread 22 on the tie rod 24 or the internal thread of the tie nut 37, the tie rod 47, the screw 32 and the screw 41 are not overloaded during operation.

The vortex rectifier 38 is mounted on the downstream side of the rotor disk 9 adjacent to the blisks in both the first and second embodiments so as to be located between the rotor disk 9 and a rotor disk 4 adjacent to this rotor disk 9 ,

As materials for the components of the device for clamping rotor disks of a jet engine thermally and mechanically highly resilient materials are used. The materials of the loaded on train components must have a high tensile strength. In particular, the tie rod 12, 47 and the rotor disc 9 must also have a high bending stiffness. The pressure-loaded components must accordingly have a high compressive strength. All components of the devices must also have a high fatigue strength.

LIST OF REFERENCE NUMBERS

1

rotor

3

contraption

4

rotor disc

5

blade

6

Rotor disk (blisk)

7

renewal

8th

opening

9

rotor disc

10

section

11

section

12

tie rods

13

flange

14

End of tie rod (downstream)

15

paragraph

16

attack

17

axial limitation

18

external thread

19

section

20

extension

21

End of tie rod (upstream)

22

external thread

23

paragraph

24

Zugankerring

25

Zugankerlager

26

bearing ring

27

stop assembly

28

tensioning assembly

29

screw connection

30

tensioning assembly

31

spacer ring

32

screw connection

33

clamping element

34

Fixing section (flange)

35

mid section

36

clamping section

37

Zugankermutter

38

Vortex reducer

39

spacer ring

40

flow direction

41

screw connection

42

paragraph

43

renewal

44

renewal

45

flange

46

flange

47

tie rods

Claims (18)

1. Jet engine with an apparatus (3) for retaining bladed rotor disks (4, 6, 9), with the jet engine essentially including an axial compressor with a rotor (1) which has several bladed rotor disks (4, 6, 9), at least one turbine section, at least one shaft and at least one tie-rod, with at least two bladed rotor disks at the compressor inlet side (2) being designed as blisks (6), each forming a one-piece assembly, integrally combining a rotor disk with circumferentially distributed rotor blades (5),
   characterized in that
   the blisks (6) are releasably retained via a tie-rod (12) and in that the other rotor disks (4, 9) of the compressor rotor (1), the rotor blades (5) of which being releasably attached, are firmly connected to each other, separately and independently of the tie-rod (12), in that the tie rod (12) is essentially tubular, disposed within central apertures (8) in the rotor disks designed as blisks (6) and firmly attached to a shaft driven by at least one turbine section, that the blisks (6) are retained by means of the tie rod (12) between at least one first arrangement (27) disposed upstream of the blisks and at least one second arrangement (28) disposed downstream of the blisks (6) and connected to the rotor disk (9) provided with releasable rotor blades (5), with the rotor disk (9) adjoining the blisks (6) on the downstream side, and in that the first arrangement includes a stopper arrangement (27) and the second arrangement a tensioning arrangement (28), with the stopper arrangement (27) including, upstream of the blisks (6), a protrusion (7) of a blisk (6) of the first compressor stage which adjoins a stopper (16) on the tie-rod (12).
2. Jet engine in accordance with Claim 1, characterized in that the tensioning arrangement (28) includes at least one tensioning element (33).
3. Jet engine in accordance with Claim 2, characterized in that the tensioning element (33) is essentially annular and features a flange-type radially outward-extending attaching portion (34), an axial tubular center portion (35), and a radially inward-extending tensioning portion (36).
4. Jet engine in accordance with Claim 3, characterized in that the radially outward-extending attaching portion (34) of the tensioning element (33) is attached to a portion of the rotor disk (9) provided with releasable rotor blades (5) and adjoining the blisks (6) on the downstream side.
5. Jet engine in accordance with Claim 4, characterized in that the radially outward-extending attaching portion (34) of the tensioning element (33) is attached to a radially inner portion (10) of the rotor disk (9) provided with releasable rotor blades (5) and adjoining the blisks (6) on the downstream side.
6. Jet engine in accordance with one of the Claims 2 to 4, characterized in that the tensioning element (33) can be retained by means of at least one tensioning means (37).
7. Jet engine in accordance with Claim 6, characterized in that the tie-rod (12) is provided at its downstream end (14) with a step (15), whose outer diameter is smaller than the outer diameter of an upstream-adjoining portion (19) of the tie-rod (12), and that the radially inward-extending tensioning portion (36) of the tensioning element (33) radially embraces the step (15), with the radially inward-extending tensioning portion (36) of the tensioning element (33) being axially moveable relative to the step (15) and, in operation, remote from an axial limitation (17) of the step (15) and adjoining the tensioning means (37).
8. Jet engine in accordance with Claim 6 or 7, characterized in that the tensioning means (37) is a tie-rod nut (37) which can be screwed on an external thread (18) adjoining the step (15) of the tie-rod (12).
9. Jet engine with an apparatus (3) for retaining bladed rotor disks (4, 6, 9), with the jet engine essentially including an axial compressor with a rotor (1) which has several bladed rotor disks (4, 6, 9), at least one turbine section, at least one shaft and at least one tie-rod, with at least two bladed rotor disks at the compressor inlet side (2) being designed as blisks (6), each forming a one-piece assembly integrally combining a rotor disk with circumferentially distributed rotor blades (5),
   characterized in that
   the blisks (6) are releasably retained via a tie-rod (47) and in that the other rotor disks (4, 9) of the compressor rotor (1), the rotor blades (5) of which being releasably attached, are firmly connected to each other, separately and independently of the tie-rod (47), and in that the tie rod (47) is essentially tubular, disposed within central apertures (8) in the rotor disks designed as blisks (6) and firmly attached to a shaft driven by at least one turbine section, and in that the blisks (6) are retained by means of the tie rod (47) between at least one first arrangement (30) disposed upstream of the blisks and at least one second arrangement (41) disposed downstream of the blisks (6) and connected to the rotor disk (9) provided with releasable rotor blades (5), with the rotor disk (9) adjoining the blisks (6) on the downstream side, and in that the first arrangement, upstream of the blisks (6), includes a tensioning arrangement (30) with a tensioning means (37), and the second arrangement, downstream of the blisks (6), includes at least one bolted connection (41) between the tie-rod (47) and the rotor disk (9) provided with releasable rotor blades (5).
10. Jet engine in accordance with Claim 9, characterized in that the upstream end (21) of the tie-rod (47) adjoins radially from the inside a tubular, upstream-extending protrusion (7) of the blisk (6) of the first stage, that the tensioning means (37) axially adjoins the protrusion (7) and radially a tie-rod ring (24) next to the upstream end of the tie-rod (47) and that the tie-rod (47) is, at its downstream end, provided with a flange (13) attaching to the rotor disk (9) provided with releasable rotor blades (5) and adjoining the blisks on the downstream side.
11. Jet engine in accordance with Claim 10, characterized in that the tie-rod (47) is provided with a taper (20) in the direction of flow (40), and the flange (13) of the tie-rod (47) is attached to a radially outward-extending portion (11) of the rotor disk (9) provided with releasable rotor blades (5) and adjoining the blisks (6) on the downstream side.
12. Jet engine in accordance with Claim 9, characterized in that the upstream end (21) of the tie-rod (47) is attached to a tie-rod ring (24), which is provided with an external thread (22), by means of at least one bolted connection (32), and that the tensioning means (37) is a tie-rod nut (37), which can be screwed on the external thread (22) of the tie-rod ring (24).
13. Jet engine in accordance with Claim 10 or 12, characterized in that the tensioning means (37) simultaneously retains a radially inner bearing ring (26) of a tie-rod bearing (25).
14. Jet engine in accordance with one of the Claims 1 to 13, characterized in that at least one vortex reducer (38) of the tubular type is attached to the rotor disk (9) provided with releasable rotor blades (5) and adjoining the blisks (6) on the downstream side.
15. Method for the retention of bladed rotor disks (4, 6, 9) by means of a jet engine in accordance with one of the Claims 1 to 8 or 9 to 14, with the blisks (6) being releasably retained by means of the tie-rod (12, 47), and the rotor disks (4, 9) provided with releasable rotor blades (5) being firmly connected to each other, separately and independently of the tie-rod (12, 47).
16. Method in accordance with Claim 15, characterized in that the blisks (6) are retained by means of the tie-rod (12, 47) between a first arrangement (27, 30) disposed upstream of the blisks (6) and a second arrangement (28, 32) disposed downstream of the blisks (6) and connected to the rotor disk (9) provided with releasable rotor blades (5), with the rotor disk (9) adjoining the blisks (6) on the downstream side.
17. Method in accordance with Claim 16, characterized in that the tie-rod (47) is tensioned from the first arrangement (30) disposed upstream of the blisks (6).
18. Method in accordance with Claim 16, characterized in that the tie-rod (12) is tensioned from the second arrangement (28) disposed downstream of the blisks (6).

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