EP2299060A1 - Blade fixation with locking device for turbine blades - Google Patents

Abstract

The rotor (1) has a turbine blade and a safety mechanism (7) for axial and radial safety of the turbine blade, where a blade groove and the turbine blade are provided with a turbine blade base (3). The blade groove and the turbine blade base are formed in such a way that the turbine blade base is adapted in the blade groove. The safety mechanism has a shear pin (8), which protrudes into a bore (15) in the turbine blade base.

Description

The invention relates to a rotor comprising at least one turbine blade and a securing device for axial and radial securing of the turbine blade, wherein the rotor comprises a blade groove and the turbine blade comprises a turbine blade root, wherein the blade groove and the turbine blade root are formed such that the turbine blade root is adapted in the blade groove is.

Blade fasteners are typically used to secure blades to a rotor of a turbomachine, particularly a steam turbine. Due to the comparatively fast rotation of the rotor, the blades arranged on the rotor are exposed to high centrifugal forces. The turbine blade root of the turbine blades must therefore withstand high forces and is urged radially outward in the blade groove. In addition to the centrifugal forces, strong vibration loads pose a further problem that can result in mechanical damage, material fatigue, corrosion and migration of the blade root within the blade groove. For fixing the turbine blade root within the blade groove, various solutions such as metal wedges, spring washers or sealing pieces are known. While metal wedges provide locking of the associated blade root within a blade groove both axially and radially, with large blades it is difficult with such metal wedges to produce sufficient holding forces during rotation in the radial direction. Disc springs produce only radial holding forces and require additional effort for a locking in the axial direction of the associated blade groove. Furthermore, complex measurements are required for disc springs during assembly. As sealing pieces always two parts must be provided, In addition, their assembly partly requires the processing of the parts by hand.

The invention has for its object to provide a blade mounting a turbomachine in which over a long period of operation, a precise and firm support of blades, in associated blade holders, is ensured.

This object is achieved by a rotor comprising at least one turbine blade, wherein the rotor comprises a blade groove and the turbine blade comprises a turbine blade root, wherein the blade groove and the turbine blade root are configured such that the turbine blade root is adapted in the blade groove, wherein the securing device has a shear pin which juts into a hole in the turbine blade foot.

Advantageous developments are specified in the subclaims.

The invention is based on the idea that both a radial and an axial securing can be arranged in a blade groove. The shear pin is placed in a corresponding bore in the turbine blade root and is advantageously at an edge on the rotor. As a result, an axial movement of the turbine blade root is not possible. If a shear pin is arranged on both the leading edge and the trailing edge of the turbine blade root, an axial displacement of the turbine blade root in one direction as well as in the other direction is effectively prevented.

The shear pin is in this case installed in a groove arranged in the rotor. The shear pin is installed after the turbine blade has been installed in the rotor in the corresponding blade groove.

In an advantageous development, the securing device has a clamping piece which exerts a radial force from the rotor onto the turbine blade root. The clamping piece is in this case arranged in a groove located in the rotor, wherein the groove may be the same as the groove in which the shear pin is arranged. The size of the clamping piece is chosen such that a force is generated which acts in the radial direction. This means that the turbine blade is pressed against the support flanks of the blade groove. Up to a certain rotational frequency thus a movement of the blades in the groove is effectively prevented. From a certain rotational frequency, the centrifugal forces are so great that a movement is prevented by the concern with the support flanks. However, it is almost inevitable that the turbine blade vibrates despite Fußbefestigung. The attachment according to the invention also prevents a relative movement between the turbine blade root and the blade groove, whereby surface damage is reduced.

Up to this rotational frequency, an axial displacement of the turbine blade is possible. Above the certain rotational frequency, the centrifugal forces are so high that an axial displacement is avoided, since the frictional forces acting as a result of the centrifugal force effectively prevent a displacement of the turbine blade in the blade groove.

In an advantageous development, the clamping piece has an upper leg and a lower leg, wherein the upper leg rests on the turbine blade root and exerts a force against the turbine blade root in the radial direction. The lower leg rests against the rotor.

The invention is characterized in that the upper leg and the lower leg substantially form a V-shape and by skillful material selection a spring force is exerted, which acts from the rotor to the turbine blade root in the radial direction.

In an advantageous development of the shear pin is on the lower leg.

To avoid accidental release of the clamping piece, a securing element is used, which is designed to secure the clamping piece. For this purpose, the clamping piece is designed as a locking plate and disposed between the clamping piece and the rotor. By bending the locking plate at the edge of the clamping piece a displacement of the clamping piece is avoided, at the same time the locking plate must be arranged in a corresponding groove in the rotor.

An exemplary embodiment of the solution according to the invention will be explained in more detail below with reference to the attached schematic drawings.

Figur 1

eine Seitenansicht eines Rotors mit einer Turbinen- schaufel im eingebauten Zustand;

Figur 2

eine Querschnittsansicht eines Teils eines Rotors mit eingebauter Turbinenschaufel;

Figur 3

eine vergrößerte Darstellung eines Ausschnitts aus Figur 2;

Figur 4

eine vergrößerte Darstellung eines Klemmstückes;

Figur 5

eine perspektivische Darstellung des Klemmstückes;

Figur 6

eine perspektivische Darstellung eines Scherstif- tes;

Figur 7

eine perspektivische Darstellung eines Sicherungs- elementes.

Show it:

FIG. 1

a side view of a rotor with a turbine blade in the installed state;

FIG. 2

a cross-sectional view of a portion of a rotor with built-turbine blade;

FIG. 3

an enlarged view of a section from FIG. 2 ;

FIG. 4

an enlarged view of a clamping piece;

FIG. 5

a perspective view of the clamping piece;

FIG. 6

a perspective view of a shear rod;

FIG. 7

a perspective view of a fuse element.

The FIG. 1 shows a side view of a portion of a rotor 1 with a built-turbine blade 2. The turbine blade 2 has a turbine blade root 3, which is adapted in a corresponding blade groove 4. The turbine blade 2 is inserted in the axial direction 5 in the blade groove 4. The blade groove 4 is formed as Tannenbaumschaufelnut and includes a plurality of support flanks. 6

The turbine blade 2 is secured in the blade groove 4 both in the axial direction 5 and in the radial direction 29. The radial direction 29 substantially corresponds to the longitudinal orientation of the turbine blade 2 and the axial direction 5 substantially corresponds to the axis of rotation which is in the FIG. 1 not shown in detail.

To secure the turbine blade 2, a securing device 7, which is arranged below the turbine blade root 3, realized. The turbine blade root 3 is in this case designed such that it is adapted to the blade groove 4, d. H. in the axial direction 5 can be moved substantially.

In the FIG. 2 is a sectional view through a portion of the rotor 1 shown. The securing device 7 essentially comprises three components. These would be a shear pin 8, a clamping piece 9 and a securing element 10. The securing device 7 is arranged in a corresponding groove 11 in the rotor 1. This groove 11 is formed both at the steam inlet side 12 and at the steam outlet side 13. The installation of at least two securing devices 7, ie both at the steam inlet side 12 and at the steam outlet side 13, offers the advantage that the turbine blade 2 can no longer be displaced in the axial direction 5. The operation and the installation of the securing device 7 are based on the FIG. 3 explained in more detail.

The shear pin 8 is cylindrical and has a length L which is less than the groove height 14 of the groove 11. This allows easy insertion of the shear pin 8 in the groove 11 is possible. The shear pin 8 is placed in a bore 15 which is located in the blade root 3. The bore 15 and the groove 11 are formed such that in the installed state, the shear pin 8 rests against an edge 16 in the rotor 1. A displacement of the turbine blade root 3 in the axial direction 5 is thus no longer possible.

Another element of the securing device 7 forms the clamping piece 9. In the FIGS. 4 and 5 is a perspective and enlarged view of the clamping piece 9 can be seen. In essence, the clamping piece 9 with a base body 17 which is cuboid-shaped and an upper leg 18 and a lower leg 19 executed. Between the upper leg 18 and the lower leg 19, a gap 20 is formed. The dimensions of the clamping piece 9 are chosen such that the height 21 of the clamping piece 9 is less than the groove height 14. An insertion of the clamping piece 9 in the blade groove 4 is therefore easily possible. The dimensions are further chosen such that in the installed state, the upper leg 18 presses a force which resembles a spring force against the turbine blade root 3. The upper leg 18 has for this purpose a projection 22 which is approximately one third of the length of the clamping piece 9. Both the upper leg 18 and the lower leg 19 are designed wedge-shaped, ie from the main body 17 in the direction of legs 18, 19, the upper leg 18 and the lower leg 19 are tapered.

The FIG. 6 shows a perspective view of the shear pin 8. A third element of the securing device 7 is the securing element 10, which is designed as a locking plate. The fuse element 10 is based on the FIG. 7 explained in more detail. In essence, the securing element 10 is formed as an elongated sheet metal piece, which is once folded completely at its tip 23, whereby a Lead 28 is created. When installed, this projection 28 abuts in a corresponding securing groove 24. As in FIG. 3 illustrated, thereby an axial displacement of the securing element 5 10 is effectively avoided. Furthermore, the securing element 10 has an end piece 26 which is bent perpendicular to the bending point 27 in relation to a main piece 25.

The safety device 7 is now installed as follows: first, the turbine blade 2 is introduced into the corresponding blade groove 4. Subsequently, the shear pin 8 is adjusted in the corresponding hole 15. The securing element 10 is inserted in the unbent state and has at the tip 23 a projection 28 which is arranged in a corresponding securing groove 24. The clamping piece 9 is pushed onto the securing element 10 in the groove 11 such that the shear pin 8 rests on the lower leg 19. Falling out of the shear pin 8 from the bore 15 is thereby avoided. The securing element 10 is inserted in the unbent state and has at the tip 23 a projection 28 which is arranged in a corresponding securing groove 24. The securing element 10 is finally bent at the bending point 27, whereby falling out of the clamping piece 9 from the groove 11 is effectively avoided.

Claims (10)

Rotor (1),
comprising at least one turbine blade (2) and a securing device (7) for the axial and radial securing of the turbine blade (2),
wherein the rotor (1) comprises a blade groove (4) and the turbine blade (2) comprises a turbine blade root (3),
wherein the blade groove (4) and the turbine blade root (3) are designed such that the turbine blade root (3) in the blade groove (4) is adapted,
wherein the securing device (7) has a shear pin (8) which projects into a bore (15) in the turbine blade root (3). Rotor (1) according to claim 1,
wherein the rotor (1) has an edge (16) against which the shear pin (8) abuts. Rotor (1) according to claim 1 or 2,
wherein the securing device (7) has a clamping piece (9) which exerts a radial force from the rotor (1) on the turbine blade root (3). Rotor (1) according to claim 3,
wherein the clamping piece (9) is arranged in a groove (11) located in the rotor (1). Rotor (1) according to claim 3 or 4,
the clamping piece (9) having an upper leg (18) and a lower leg (19),
wherein the upper leg (18) rests against the turbine blade root (3) and exerts a force in the radial direction (29) against the turbine blade root (3),
wherein the lower leg (19) rests against the rotor (1) and exerts a force against the rotor (1) in the radial (6) direction. Rotor (1) according to claim 3, 4 or 5,
wherein the upper (18) and the lower (19) legs are V-shaped. Rotor (1) according to one of claims 3 to 6,
wherein the shear pin (8) rests on the lower leg (19). Rotor (1) according to one of the preceding claims 3 to 6,
wherein the securing device (7) has a securing element (10) for securing the clamping piece (9). Rotor (1) according to claim 8,
wherein the securing element (10) as between the clamping piece (9) and the rotor (1) arranged locking plate is formed. Rotor (1) according to claim 8 or 9,
wherein the securing element (10) has a projection (28) which is arranged in a locking groove (24) arranged in the rotor (1).

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