EP2090750A1 - Turbomachine rotor, rotor blade for such a turbomachine rotor, supporting strip for such a rotor blade in the turbomachine rotor and corresponding assembling method - Google Patents

Abstract

The rotor (1) has a rotor blade (2) provided with a blade base (4). A rotor disk (16) has a groove (17) in which the blade base is engaged such that the blade is held in the groove in a radial direction in a form-fit manner. Pre-tensioning devices (7-14, 19-28) are supported at the rotor disk and at the blade base, and exert a pre-tensioning force on the blade base in the radial direction. The pre-tensioning devices are designed such that the pre-tensioning force is adjusted when the rotor is in the assembled state. An independent claim is also included for a method for assembling a turbo machine rotor.

Description

The invention relates to a turbomachine rotor having biasing means for biasing a blade, the blade having the biasing means, a backing plate as the biasing means and a method of assembling the turbomachine rotor.

A gas turbine is a thermal turbomachine in which conventionally fossil fuels, such as natural gas, are burned. The gas turbine can be used for example in a gas and steam power plant, which is provided to cover peak loads in a power grid. As a result, the gas turbine is driven in transient operation, whereby the individual components and components of the gas turbine are subjected to transient loads. Due to the high power density of the gas turbine high demands are to be met in terms of the strength of highly loaded components in order to ensure a long service life of these components and long maintenance cycles and a low spare parts requirement.

The gas turbine has a compressor with a compressor rotor and a turbine with a turbine rotor, wherein the compressor rotor and the turbine rotor are rotationally locked together via a shaft. Conventionally, the compressor rotor and / or the turbine rotor are designed in axial construction, that is, on the shaft a plurality of wheel disks are threaded one behind the other. At the outer peripheries of the wheel disks a blade row is attached in each case. Each blade row has a plurality of blades, each having an aerodynamically effective airfoil and a blade root. The blade root is inserted into a groove located on the outer circumference of the wheel disc, see above the blade is held in a form-fitting manner on the blade root, in particular in the radial direction of the gas turbine rotor.

For the positive retention of the blade, the blade root and the groove have corresponding dovetail profiles or fir tree profiles. These profiles are arranged running in the axial direction of the gas turbine rotor, so that for mounting the blade, this is inserted with its blade root in the axial direction of the gas turbine rotor in the groove. Between the blade root and the profile of the groove a game is provided so that the blade root is wear-free inserted into the groove. Caused by the game, the blades may move during operation of the gas turbine resulting in a characteristic rattling of the blade. This is especially true for a large and heavy blade, as provided in particular in the first blade rows of the compressor of the gas turbine with a high performance.

Conventionally, the blade is preloaded in the groove to prevent rattling. However, especially in the case of the large and heavy blade due to the bias voltage assembly can be difficult.

Further, the bias in the wheel disc and the blade root causes a mechanical stress, which is conventionally compensated by a stable and solid design of the wheel disc and the blade root. In the groove, an axial securing plate may be provided, with which the blade is secured against axial displacement and is additionally biased. However, for the large and heavy blades, the axial securing plate may be too weak to form.

The object of the invention is to provide a turbomachine rotor, a blade, a support plate and a method for assembling the turbomachine engine, wherein the turbomachine rotor can be operated without rattling the blades with high strength and efficiency.

The turbomachine rotor comprises a blade having a blade root, a wheel disc having a groove in which the blade root engages so that the blade is positively held in the radial direction with the groove, and biasing means supported on both the wheel disc and the blade root and exerts on the blade root a biasing force in the radial direction, wherein the biasing means is arranged such that the biasing force is adjustable in the assembled state of the turbomachine rotor.

This makes it possible that when assembling the turbomachinery engine, i. during axial insertion of the blade root in the groove, the biasing force is provided as low and in the assembled state of the turbine engine rotor, the biasing force is set to be predetermined high. Thus, the biasing force is advantageous when inserting the blade root in the groove, so that wear on the blade root and in the groove due to the assembly of the blade is prevented.

Further, the force required when inserting the blade root into the groove is advantageously low, so that only slight stress peaks occur in the blade root and in the wheel disk during assembly of the blade. As a result, these stress peaks in the strength design of the blade root and the wheel disc as good as not to be considered and the mounting of the blade in the wheel disc is simple.

It is preferred that the biasing means comprises at least one adjusting screw, by means of which by applying a predetermined tightening torque, the biasing force in the assembled state of the turbomachine rotor is adjustable.

By means of the adjusting screw is the setting of the predetermined biasing force on the specification of a torque of the screw allows. As a result, the preload force can be applied to the blade via the tightening torque. Preferably, the set screw is provided with a fine thread, so that an accurate power transmission of the screw is made possible by the tightening torque on the biasing force.

Furthermore, disassembly of the blade by loosening the screw is made possible by the provision of the screw, so that the disassembly of the blade is easy. Thus, a material-friendly and quick reassembly of the blade is possible.

In addition, it is preferred that in the blade root at least one threaded hole is provided, which opens at the bottom of the blade root facing the groove in the groove, wherein at least one screw is screwed into the at least one threaded hole so that it protrudes on the blade root with its screw end and supported on the groove bottom.

As a result, the adjusting screw penetrates the blade root through the threaded hole and is fixed therein, so that the biasing force is applied by the support of the screw end against the groove bottom on the blade root in the radial direction.

Preferably, the biasing means comprises a support plate which is arranged on the groove base at least in the region of an adjusting screw, so that the adjusting screw and the support plate are in touching contact.

The support plate is located directly on the groove bottom in the groove, so that no additional groove needs to be provided in the groove base for the support plate.

Furthermore, the groove base is covered by the support plate in the area of the adjusting screw, so that the groove base only in the indirect Contact via the support plate with the screw end of the adjusting screw. Thus, it is prevented that the end of the screw screw, especially when turning the screw damaged the groove bottom.

Furthermore, it is preferable for the at least one threaded hole with its end remote from the blade root underside to open outward on one of the front sides of the blade root, so that the threaded hole is inclined at an acute angle away from the longitudinal axis of the turbomachine rotor.

As a result, the threaded hole on the front side of the blade root is accessible, so that from there the adjusting screw can be adjusted to the wheel disc after assembly of the blade. Further, since the threaded hole extends from the end face of the blade root toward the blade root, the threaded hole penetrates the blade root in a mechanically little loaded area. This is little affected by the provision of the threaded hole in the blade root in its strength.

Due to the inclination of the adjusting screw around the acute angle, the biasing force applied by the adjusting screw has an axial and a radial component. This is advantageous because it applies both the radial preload force and an axial force for locking the blade in the wheel disc. As a result, both a radial and an axial attachment of the blade is ensured. On the degree of inclination of the screw, the division of the force transmitted through the screw force can be divided into the axial and radial attachment.

It is preferred that the support plate has at least one offset with a flat edge, which is shaped such that the end of the screw of the screw abuts the end face of the flat edge. Preferably, the end face of the screw end of the adjusting screw is also formed flat, so that when flat concerns of the screw end on the flank the surface pressure is low. As a result, an extreme mechanical load on the support plate is prevented by the screw, whereby an undesirable rejection of the support plate due to the action of the screw does not occur, so that jamming the screw is prevented.

It is preferred that the blade root has the first threaded hole with the first set screw and the second threaded hole with the second set screw, wherein the first threaded hole at one end side and the second threaded hole at the other end side of the blade root opens outwards, so that the first threaded hole at a first acute angle and the second threaded hole is inclined away from the longitudinal axis of the turbomachinery rotor at a second acute angle.

As a result, the two setscrews are mutually oppositely inclined, so that the force applied to the support plate axial force components counteract each other. As a result, a stable attachment of the blade root in the groove can advantageously be achieved, with little or no resulting axial force acting on the blade root.

In addition, it is preferred that the support plate has the first offset with the first flank on which abuts the screw end of the first screw, and the second crank with the second flank against which abuts the screw end of the second screw.

Thus, the blade is locked at its blade root via the screws on the flanks of the cranks of the support plate in the axial direction positively.

It is preferred that the first angle and the second angle have the same amount.

Thereby, the biasing means in the plane perpendicular to the axial direction of the turbomachine rotor is formed symmetrically, so that the distribution of the biasing forces in the biasing means is symmetrical. Thus, the biasing device, the blade root and the wheel are claimed balanced.

Furthermore, it is preferred that the support plate between the two cranks has a back portion which faces the blade root with its convex side.

Preferably, the support plate is made of an elastic material. Caused by the biasing forces exerted by the set screws on the flanks of the cranks, they are pressed in the direction of the groove bottom. As a result, the back portion is curved, so that the back portion presses with its convex side on the blade root underside. As a result, the biasing forces that exert the set screws on the support plate, transferred to the blade root. Thus, the bias of the blade is increased.

In addition, it is preferable that the back portion is pre-curved prior to its mounting, so that the back portion in the assembled state of the turbomachine engine presses on the blade root lower side.

As a result, the support plate has a spring action in the direction of the blade root lower side, whereby a Vorspannreserve in the case of setting, ie, when enlarged in operation, the distance between the Schaufelfußunterseite and the groove bottom created. Furthermore, the pre-curvature of the back portion in the assembled state allows a good adhesion over the surface contact formed with the set screws. About the stiffness and the thickness of the support plate, the Vorspannreserve can be predefined. By adjusting the set screws, the preload reserve in the assembled state can still be varied.

It is preferred that the support plate has at the first offset a first leg portion extending away from the back portion and at the second crank a second leg portion extending away from the back portion.

This ensures that the support plate is supported flat and so with low surface pressure on the groove bottom.

Preferably, the first leg section has a first projection and the second leg section has a second projection, wherein the projections protrude out of the groove beyond the edge plate.

As a result, the support plate is in the assembled state from the outside tangible with the supernatants, so that disassembly and reassembly of the blade is easy to carry out.

Furthermore, it is preferred that the projections are arranged at an angle to the leg portions, so that the wheel disc is in engagement with the support plate and thereby retained in the axial direction of the turbomachine rotor.

As a result, the support plate is fixed to the wheel disc in the axial direction, in particular, even when the rotor blade is not yet inserted into the groove of the wheel disc during assembly of the turbomachine rotor. Thus, when assembling the turbomachinery rotor, the support blade placed in the groove on the groove bottom need not be retained from the outside when the blade root is inserted into the groove. Preferably, the supernatant can be bent or rolled over.

It is preferred that the at least one adjusting screw is secured against unintentional rotation by a securing means.

This prevents the adjusting screw from being accidentally released during operation of the turbomachine rotor. The securing means may preferably be an adhesive. Alternatively or additionally, the set screw can be caulked with a grain impact in the blade.

The geometric dimensions of the support plate, the set screws and the tightening torque must be adapted to the mass of the blade.

The blade according to the invention has a blade root with two oppositely disposed end faces and a blade root lower side perpendicular to the longitudinal axis of the blade root, the blade root having a first threaded hole and a second threaded hole, with the two threaded holes opening outward at the blade root bottom, and the first threaded hole at one end face and the second threaded hole at the other end face the blade root open to the outside, so that the first threaded hole is inclined at a first acute angle and the second threaded hole at a second acute angle from the longitudinal axis of the turbomachine rotor.

The support plate according to the invention for biasing a blade of a turbomachinery rotor has a longitudinal direction and has along this two opposing cranks, between which the support plate has a back portion.

The method of assembling a turbomachinery rotor according to the invention comprises the steps of: providing the turbomachine rotor having the wheel disc with the groove, the blade and the support plate; Inserting the blade into the groove, so that the blade root engages in the groove and so the blade is held in the groove form-fitting in the radial direction; Inserting the support plate in the groove between the blade root bottom and the groove bottom; Screw in the first set screw into the first threaded hole and the second set screw into the second threaded hole until the set screws contact their corresponding cranks; Tightening the two set screws with a predetermined tightening torque to bias the blade in the radial direction with a predetermined biasing force in the groove.

In the following, a preferred embodiment of a turbomachinery rotor according to the invention and a support plate according to the invention will be explained with reference to the accompanying schematic drawings.

Figur 1

einen Querschnitt durch den Turbomaschinenrotor im Bereich eines Schaufelfußes,

Figur 2

einen Längsschnitt des Turbomaschinenrotors im Bereich des Schaufelfußes,

Figur 3

eine Abstützplatte im Nichteinbauzustand,

Figur 4

die Abstützplatte im Einbauzustand.

It shows:

FIG. 1

a cross section through the turbomachine rotor in the region of a blade root,

FIG. 2

a longitudinal section of the turbomachine rotor in the region of the blade root,

FIG. 3

a support plate in the non-installed state,

FIG. 4

the support plate in the installed state.

As it is from the Figures 1 and 2 As can be seen, a turbine engine rotor 1 has a plurality of rotor blades 2 and a wheel disk 16. The rotor blades 2 are attached to the circumference of the wheel disc 16, so that a rotor stage of the turbomachine rotor 1 is formed.

The blade 2 is made in one piece and has an airfoil 3 and a blade root 4. The blade 3 is aerodynamically effective, for example in a compressor or a turbine of a turbomachine. The blade root 4 serves for fastening the blade 3 to the wheel disc 16.

The blade root 4 has in a plane which is perpendicular to the axis of rotation of the turbomachine rotor, a fir-tree profile-shaped cross-section and in a plane in which the axis of rotation of the turbomachine rotor is located, a rectangular cross-section. The rectangular cross-section of the blade root 4 is formed by a longitudinal side, adjacent to the blade 3, two mutually remote end faces, each perpendicular to the axis of rotation of the turbomachine rotor 1, and a Schaufelfußunterseite 15, which is substantially parallel to the axis of rotation of the turbomachinery rotor 1 and the airfoil 3 is arranged averted. In the corner regions of the blade root 4, which lie in the region of the edges formed by the end faces and the blade root underside 15, the blade root 4 has regions 5 and 6 which are under little mechanical loading.

The first mechanically little loaded area 5 of the blade root 4 is of a first threaded hole 7 and the second mechanically little loaded area 6 of the blade root 4 is penetrated by a second threaded hole 8, wherein the two threaded holes 7, 8 open at the blade root bottom 15 to the outside and the first threaded hole 7 open at the one end face of the blade root 4 and the second threaded hole 8 at the other end face of the blade root 4 to the outside. In the first threaded hole 7 is a first screw 9 and in the second threaded hole 8, a second screw 10 is screwed. The first adjusting screw 9 has a first screw end 11 and the second adjusting screw 10 has a second screw end 12, wherein the screw ends 11, 12 are each located on the blade root bottom side 15 outside of the blade root 4.

The two threaded holes 7, 8 and the two adjusting screws 9, 10 are arranged pivoted against each other, so that the first threaded hole 7 with the axis of rotation of the turbomachine rotor 1 a first angle 13 and the second threaded hole 8 with the axis of rotation of the turbomachine rotor 1 includes a second angle 14 , The two threaded holes 7, 8 are mutually arranged such that the two screw ends 11, 12 of the two adjusting screws 9, 10 are arranged facing each other. In each case, the first angle 13 and the second angle 14 are acute angle and the same amount.

The wheel disc 16 has a groove 17 with a groove bottom 18, which is in engagement with the blade root 4. The shape of the groove 17 is formed such that it encloses the longitudinal sides of the blade root 4 and the blade root bottom 15 in a form-fitting manner, so that the rotor blade 2 is held in a form-fitting manner in the groove 17 in the groove 17 in the radial direction and in the circumferential direction of the turbomachinery rotor 1 by means of the fir tree profile of the blade root 4. The groove 17 and the blade root 4 are formed such that during assembly of the turbomachine rotor, the blade 2 with its blade root 4 substantially in the axial direction of the turbomachine rotor 1 is inserted. In the assembled turbomachine rotor 1, the end faces of the blade root 4 are substantially flush with the end faces of the wheel disc 16.

The groove 17 is dimensioned such that between the groove bottom 18 and the blade root bottom 15 a gap is formed. In the gap, a support plate 19 is inserted, which has in its center a back portion 20 which is formed by a first crank 21 and a second crank 22. A first leg section 25 adjoins the first offset 21 and a second leg section 26 adjoins the second offset 22, wherein the leg sections 25, 26 rest against the groove base 18 and the back section 20 rests against the underside of the blade foot 15. The back portion 20 and the leg portions 25, 26 are arranged in alignment with each other.

The first offset 21 has a first flank 23 and the second offset 22 has a second flank 24, the first screw end 11 abutting the first crank 21 and the second screw end 12 abutting the second crank 24. Both the first end of the screw 11 and the first edge 23 and the second end of the screw 12 and the second edge 24 are formed flat, so that the contact between the screws 10, 11 and the support plate 19 is made via a contact surface.

The two screws 9, 10 are screwed in their threaded holes 7, 8 and tightened with a predetermined torque, so that each of the set screws 9, 10 on the flanks 23, 24 and thus on the support plate 19 a predetermined force is applied. The force has a radial component and an axial component, wherein when the two setscrews 9, 10 are tightened with the same tightening torque, the axial components cancel each other. The radial components form a predetermined biasing force with which the blade root 4 is pre-biased in the groove 17 predetermined.

On the first leg portion 25, a first projection 27 and on the second leg portion 26, a second projection 28 is provided, wherein the projections 27, 28 extend out of the groove 17 on the wheel disc 16 away. The two projections 27, 28 are arranged angled towards the center of the turbomachine rotor 1 to the leg portions 25, 26, so that with the projections 27, 28, the support plate 19 is arranged fixed on the groove bottom 18 in the axial direction of the turbomachine rotor 1.

In FIGS. 3 and 4 the support plate 19 is shown, wherein the first projection 27 as an extension of the first leg portion 25 and the second projection 28 are arranged as an extension of the second leg portion 26.

In FIG. 3 is the support plate 19 in the unmounted state and in FIG. 4 shown in the assembled state. The support plate 19 is pre-curved, so that the support plate 19 in the unassembled state has a convex contour. Is the support plate 19, as it is in the FIG. 4 is shown inserted into the groove 17 together with the blade root 4, Thus, the support plate 19 is pressed straight, so that the support plate 19 exerts a spring force on the blade root 4 due to spring properties.

In a method for assembling the turbine engine rotor 1, the blade 2 is inserted into the groove 17 substantially in the axial direction of the turbomachine rotor until the end faces of the blade root 4 are aligned with the end faces of the wheel disc 16. In the gap formed between the blade root lower side 15 and the groove bottom 18, the support plate 19 according to the in FIG. 3 shown embodiment pushed until the two projections 27 and 28 project from the wheel disc 16. Then, the first screw 9 is screwed into the first threaded hole 7 and the second screw 12 in the second threaded hole 8 until the first end of the screw 10, the first edge 23 and the second end of the screw 12, the second edge 24 touch. In the following, the screws 9, 10 are tightened with the predetermined torque. Then, the projections 27 and 28 are bent in the direction of the center of the wheel disc 16, so that the projections 27, 28 abut against the wheel disc.

Claims (19)

Turbomachinery rotor,
comprising a blade (2) with a blade root (4), a wheel disc (16) with a groove (17), in which the blade root (4) engages, so that the blade (2) in the groove (17) positively in the radial direction is held,
and biasing means (7-14, 19-28) supported on both the wheel disc (16) and the blade root (4) and exerting on the blade root (4) a biasing force in the radial direction,
wherein the biasing means (7-14, 19-28) is arranged such that the biasing force in the assembled state of the turbomachine rotor (1) is adjustable. Turbomachine rotor according to claim 1,
wherein the biasing means (7-14, 19-28) comprises at least one set screw (10, 11) adapted to adjust the biasing force in the assembled state of the turbomachine rotor (1) by applying a predetermined tightening torque. Turbomachine rotor according to claim 2,
wherein in the blade root (4) at least one threaded hole (7, 8) is provided which opens at the bottom of the blade root (15) facing the groove bottom (18) of the groove (17), and
wherein the at least one adjusting screw (9, 10) is screwed into the at least one threaded hole (7, 8) so that it protrudes on the blade root (4) with its screw end (11, 12) and is supported on the groove base (18) , Turbomachine rotor according to claim 3,
wherein the biasing means (7-14, 19-28) comprises a support plate (19) which is arranged on the groove base (18) at least in the region of an adjusting screw (9, 10), so that the adjusting screw (9, 10) Support plate (19) are in touching contact. Turbomachine rotor according to claim 3 or 4,
wherein the at least one threaded hole (7, 8) with its end remote from the blade root bottom (15) opens outward at one of the end sides of the blade root (4), so that the threaded hole (7, 8) at an acute angle (13, 14) is inclined away from the longitudinal axis of the turbomachine rotor. Turbomachine rotor according to claim 5,
wherein the support plate (19) has at least one offset (21, 22) with a flank (23, 24) which is shaped in such a way that the screw end (11, 12) of the set screw (9, 10) bears flat against the flank ( 23, 24) is present. Turbomachine rotor according to claim 5 or 6,
the blade root (4) having the first threaded hole (7) with the first adjusting screw (9) and the second threaded hole (8) with the second adjusting screw (10),
wherein the first threaded hole (7) at one end face and the second threaded hole (8) at the other end side of the blade root (4) opens outwards, so that the first threaded hole (7) at a first acute angle (13) and the second Threaded hole (8) is inclined at a second acute angle (14) from the longitudinal axis of the turbomachinery rotor (1). Turbomachine rotor according to claim 7,
wherein the support plate (19) has the first offset (21) with the first edge (23) against which the screw end (11) of the first set screw (9), and the second crank (22) with the second edge (24) , on which the screw end (12) of the second adjusting screw (10) rests. Turbomachine rotor according to claim 7 or 8,
wherein the first angle (13) and the second angle (14) have the same amount. Turbomachine rotor according to claim 9,
wherein the support plate (19) between the two cranks (21, 22) has a back portion (20) facing with its convex side the blade root (4). Turbomachine rotor according to claim 10,
wherein the back portion (20) is pre-curved prior to its mounting, so that the back portion (20) in the assembled state of the turbomachine rotor (1) presses on the blade root lower side (15). Turbomachine rotor according to claim 10 or 11,
wherein the support plate (19) has at the first offset (21) a first leg portion (25) extending away from the spine portion (20) and at the second spine (22) a second leg portion (26) extending from the spine portion (20) , Turbomachine rotor according to claim 12,
wherein the first leg section (25) has a first projection (27) and the second leg section (26) has a second projection (28),
wherein the projections (27, 28) protrude from the groove (17) over the wheel disc (16). Turbomachine rotor according to claim 13,
wherein the projections (27, 28) are angled away from the leg portions (25, 26) such that the wheel disc (16) engages the support plate (19) and is thereby retained in the axial direction of the turbomachine rotor (1). Turbomachine rotor according to one of claims 2 to 14,
wherein the at least one adjusting screw (9, 10) is secured with a securing means against unintentional rotation. Blade with a blade root (4) with two oppositely arranged and arranged perpendicular to the longitudinal axis of the blade root end faces and a blade root lower side (15),
the blade root (4) having a first threaded hole (7) and a second threaded hole (8),
wherein the two threaded holes (7, 8) open outward at the blade root lower side (15) and the first threaded hole (7) at one end face and the second threaded hole (8) at the other end face of the blade root (4) open to the outside, then in that the first threaded hole (7) is inclined at a first acute angle (13) and the second threaded hole (8) is inclined away from the longitudinal axis of the turbomachinery rotor by a second acute angle (14). Blade according to claim 16,
wherein the first angle (13) and the second angle (14) have the same amount. Support plate for biasing a blade (2) of a turbomachinery rotor (1),
wherein the support plate (19) has a longitudinal direction and along this arranged two opposing cranks (21, 22), between which the support plate (19) has a back portion (20). A method of assembling a turbomachinery rotor, comprising the steps of: - Providing a turbomachinery rotor (1), comprising a wheel disc (16) having a groove (17), a blade (2) according to claim 16 or 17 and a support plate (19) according to claim 19; - Inserting the blade (2) in the groove (17), so that the blade root (4) engages in the groove (17) and so the blade (2) in the groove (17) positively held in the radial direction of the turbomachine rotor (1) is; - Insertion of the support plate (19) in the groove (17) between the Schaufelfußunterseite (15) and the groove bottom (18); Screwing a first adjusting screw (10) into the first threaded hole (7) and a second adjusting screw (10) into the second threaded hole (8) until the adjusting screws (9, 10) touch their corresponding cranks (21, 22); - Tightening the two screws (9, 10) with a predetermined torque to bias the blade (2) in the radial direction with a predetermined biasing force in the groove (17).

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