EP1703079A1 - Rotational solid for fixing of blades of a turbo-machine - Google Patents

Abstract

The invention relates to a rotary body (30) for fastening rotor blades (15) of a turbomachine, having an axis of rotation (34) and having a peripheral surface (36) provided between a first front side surface (32) and a second front side surface (32) and along the circumferential surface (36) evenly distributed, between the two end-side side surface (32) ersteckenden retaining grooves (38),
wherein each retaining groove (38) has at least one circumferentially extending undercut (20) for forming a corresponding tooth (22). In order to specify a rotational body (30) with a prolonged service life, it is proposed that a relief slot (26, 28), which is arranged in the area of the tooth (22), be provided in at least one end-side side surface (32).

Description

The invention relates to a rotary body for fastening rotor blades of a turbomachine, with an axis of rotation and with a provided between a first front side surface and a second end side surface peripheral surface and with uniformly distributed along the peripheral surface, extending between the two end side surfaces holding grooves, each retaining groove has at least one circumferentially extending undercut.

A generic device is for example from the WO 2003/036049 A1 known. In a rotor disk axially extending and in cross-section fir-tree-shaped retaining grooves for blades are distributed along the circumference. Each blade has a corresponding to the retaining groove formed on the blade root, so that they can each be inserted and secured in one of the retaining grooves. To form the Christmas tree shape, each retaining groove has at its two side walls in the circumferential direction extending teeth and intervening undercuts, which produce with the corresponding recesses and teeth of the blade root teeth, with which the blade is held on the rotor disk. During operation of the turbine, the rotor disk rotates as part of the rotor at a predetermined speed, so that the blades attached thereto strive under the action of centrifugal force to the outside and bear against the toothed disk formed by Nuthinterschneidungen on the rotor disk.

The mechanical loads occurring during operation of the turbine in the rotor disk lead to material stresses which are located near the surface both in the front side surfaces of the rotor disk teeth and also deeper in the material Create cracks and accelerate their growth. This in advance indeterminable wear affects the life of the rotor disk, so that it must be tested to ensure safe operation of the turbine after a predetermined and possibly unnecessarily short operating time prophylactic to the aforementioned defects. If the result of a checked rotor disk shows a crack which exceeds an impermissible crack length, or whose crack length could increase to the impermissible crack length during the next planned operating interval, a reliable and safe operation of the turbine equipped therewith is not guaranteed. The rotor disk classified as defective in this case must be replaced by a faultless rotor disk with the expenditure of additional repair time and other costs. This reduces the disposal time of the gas turbine and thus increases their service lives.

The object of the invention is to provide a rotary body for fastening blades of a turbomachine whose life is extended.

The object is achieved by a rotary body having the features of patent claim 1. The invention proposes a generic rotary body in whose frontal side surface a relief slot arranged in the region of the tooth is provided.

The invention is based on the recognition that the position of the maximum occurring in the region of the tooth of the rotating body and caused by the outwardly aspiring blade during operation voltage can be displaced locally from a critical area in a non-critical area by a discharge slot. This maximum stress was previously on each front side surface, on the contour of the tooth and thus on the contour of the retaining groove on which rests the blade root. Due to the relief slot, this maximum stress no longer occurs directly at the contour of the Tooth or the retaining groove, but in a second remote therefrom, in which the emergence or presence of a crack or defect for the operation of the turbomachine is not critical.

Consequently, due to the relief slot, the critical stresses arising at the contour of the retaining groove in the region of the frontal side surface are lowered, so that at this point the material of the rotary body is subjected to less stress. Likewise, the resulting stresses occur at this point in an uncritical for the material used size. Cracking can thus be significantly reduced at this point; Crack growth is delayed. In particular, the short-cycle fatigue strength (LCF fatigue strength) of the rotary body can thereby be improved, as a result of which the overall service life of the latter is prolonged.

In addition, due to the discharge slot, the crack inspection is substantially simplified, since an improved possibility of checking for cracks or other indications, for example defects, with known test methods is possible due to the relief slot machined into the rotary body.

Advantageous embodiments of the invention are specified in the subclaims.

A particularly advantageous reduction in stress in the material close to the surface near the surface of the rotational body can be achieved if the relief slot is provided only partially between the undercut and the peripheral surface when viewed in the radial direction. The other part of the discharge slot is thus provided in a section which lies between two adjacent retaining grooves. By this measure, the previously particularly high mechanical, occurring at the contour of the retaining tensions are also displaced in the section between two adjacent retaining grooves lies. As a result, the material stresses which occur directly on the retaining groove, ie in the tooth or in the teeth, are lowered.

In a further embodiment, the discharge slot is kidney-shaped or U-shaped. It has been found that in particular the kidney shape and / or the U-shape in each case can bring about a particularly great reduction in the material tension and a significant local displacement of the maximum of the tension. Accordingly, the material of the rotary body can be effectively spared with such a relief slot.

As a result of the relief slot, the maximum material tension occurring is displaced out of the region immediately adjacent to the retaining groove and into the second region in which the relief slot is arranged, in a further advantageous development at least the material surrounding the two ends of the relief slot Surface-hardened rotating body. In this way, a particularly durable rotary body can be produced, since in this case cracking is further reduced in the second area remote from the holding groove or the tooth and crack growth continues to be delayed.

Conveniently, the relief slot has a penetration depth of 1 mm to 25 mm, preferably from 5 mm to 20 mm. This penetration depth leads to a particularly effective relief of the material. In addition, the retaining grooves may be formed in fir-tree cross section, hammer-shaped or dovetailed in cross section. In the case of a hammer or dovetail shape, each retaining groove has an undercut on both sides, ie in the circumferential direction, so that the rotational body has one tooth for each undercut, one provided on the respective side wall of the retaining groove and extending into it. Depending on the number of branches of a fir tree-shaped retaining groove, this two, three or four on each side wall of the Holding groove arranged teeth which protrude into the retaining groove and each one on the respective tooth radially inwardly adjacent (groove) undercut form, to which a correspondingly designed blade root can rest. Each tooth formed on the retaining groove serves during operation of the turbomachine as an abutment for a correspondingly configured tooth provided on the blade root.

Since in the surrounding the retaining material of the rotating body in the area adjacent to the undercut, i. In the tooth, mechanical stress peaks can occur on both end faces, for each tooth or each undercut an associated relief slot or its associated relief slot can be provided on each side face. The forces acting on the blade centrifugal loads are transmitted via the teeth of the blade root with the retaining groove in the teeth of the rotating body and displaced due to the disposed in both side surfaces relief slots in the remote from the contour of the retaining second area.

Alternatively, if a plurality of radially spaced undercuts are provided, only the radially outer undercuts may have an associated relief slot and the radially inner undercuts not. This embodiment is based on the knowledge that especially at the radially outer undercuts, the largest mechanical stress in the material of the rotating body, caused by the centrifugal force loads of the blade and the rotating body occur. According to the invention, these maximum mechanical stress loads are displaced out of the area directly forming the retaining groove by the relief slots. At the radially inner undercuts occur no unacceptable material stresses, so that, if necessary, can be dispensed with relief slots here.

The rotary body may be formed on the one hand as a rotor disk or as a welded rotor rotor, for example, are provided on the provided in a shaft collar, extending in the axial direction retaining grooves for turbine blades or compressor blades. Accordingly, the meaning of the invention is independent of the selected embodiment of the rotor and used for both embodiments.

A turbomachine equipped with this rotary body advantageously has an increased service life and reduced service life due to the extended service life.

FIG 1

eine Gasturbine in einem Längsteilschnitt und

FIG 2

einen Rotationskörper mit Haltenuten und einem Entlastungsschlitz.

The invention will be explained below with reference to a drawing. Show it:

FIG. 1

a gas turbine in a longitudinal section and

FIG. 2

a rotating body with holding grooves and a relief slot.

1 shows a gas turbine 1 in a longitudinal partial section. It has inside a rotatably mounted about a rotation axis 2 rotor 3, which is also referred to as a turbine runner. Along the rotor 3 successive an intake 4, a compressor 5, a toroidal annular combustion chamber 6 with a plurality of rotationally symmetrical to each other arranged burners 7, a turbine unit 8 and an exhaust housing 9. The annular combustion chamber 6 forms a combustion chamber 17 which communicates with an annular hot gas channel 18. There four successive turbine stages 10 form the turbine unit 8. Each turbine stage 10 is formed of two blade rings. Viewed in the flow direction of a hot gas 11 produced in the annular combustion chamber 6, follows in the hot gas channel 18 in each case one row of vanes 13 a formed of blades 15 row 14. The vanes 12 are attached to the stator, whereas the blades 15 of a row 14 means a turbine disk are mounted on the rotor 3. On the rotor 3, a generator or a working machine (not shown) is coupled.

2 shows a detail of a rotary body 30, which may be formed as a rotor disk 19 or as a shaft collar of a rotor rotor. The rotary body 30 has two end-side side surfaces 32, which are connected to each other by a peripheral surface 36. Along the circumference uniformly distributed retaining grooves 38 are provided, in which in the axial direction, based on the axis of rotation 34, not shown in FIG 2 blades for an axial flow machine, such as a gas turbine 1, a compressor 3 or a steam turbine, are inserted. The retaining grooves 38 have a fir-tree-shaped contour in the illustrated cross-section. This results in each retaining groove 38 four circumferentially extending undercuts 20. Accordingly, the rotational body 30 to form each undercut 20 each have a radially outwardly adjacent to the undercut 20 and also protruding in the circumferential direction tooth 22 whose radially inner part surface as an abutment for Blades not shown is used so that they are held by the rotary body 30 during operation of the turbomachine.

In the teeth 22 and in the areas adjacent thereto, d. H. their root areas, due to the centrifugal forces acting on the blade, stresses in the form of mechanical stresses that can cause the material of the rotating body 30 wear at this point by cracking and crack growth. So far, the maximum mechanical loads and stresses M occurred near the surface-relative to the side surfaces 32-along the contour 24 of the retaining grooves 38 in the region of the undercuts 20.

In order to shift this maximum load away from the retaining groove 38 or the contour 24, the invention proposes that in one or both front side surfaces 32 to the undercuts 20 adjacent relief slots 26, 28 are provided, the respective contour or contour describes, for example, a kidney shape or a U-shape.

The relief slot 26, 28 is located in the root region of the tooth 22, slightly displaced radially inwardly to the undercuts 20, into which projects the corresponding tooth 22 of the blade root, which transmits the load of the blade for each tooth 22. The orientation of the slightly curved relief slot 26, 28 is chosen so that its ends preferably point away from the retaining groove 38.

Due to the, possibly also filled with a soft material, relief slot 26, the maximum occurring stress N in the material of the rotating body 30 is displaced from the contour 24 to the relief slot 26.

The material directly surrounding the retaining grooves 38 of the rotating body 30 is thus still charged during operation of the turbomachine by the blades held in the retaining grooves 38, but occurs a lower maximum stress in the material at a displaced location in the vicinity of the discharge slot 26, thereby the life of the rotating body 30 improved in a decisive way. Accordingly, a more uniform loading of the material, seen both in the axial direction and in the radial and circumferential direction, is achieved overall.

The relief slots 26 are provided in the radial direction partially between the undercut 20 and the peripheral surface 36 and have an axially extending penetration depth E in the order of 1 mm to 25 mm, but preferably from 5 mm to 20 mm.

In this case, alternatively, each undercut 20 at one or each end-side side surface 32 associated with it Relief slot 26, 28 have. Alternatively, if the retaining groove 38 is formed as a fir-tree shape, only only the radially outermost undercuts 22 can each have a discharge slot 28 assigned to them.

In particular, if at least the material surrounding the two ends 31 of the relief slots 26 of the rotational body 30 has been provided with surface hardening, the stress maximum in the material displaced away from the contour profile 24 can advantageously lead to a life extension.

A particular advantage of the present invention is also due to the fact that the relief slots 26, 28 can act as a crack stopper. If defects occur in the form of cracks adjacent to the tearstoppers, they can possibly leak into the relief slots 26, 28 without these exceeding a critical crack length.

Claims (9)

Rotary body (30) for fastening rotor blades (15) of a turbomachine,
with a rotation axis (34) and
with a peripheral surface (36) provided between a first front-side side surface (32) and a second front-side side surface (32), and
with retaining grooves (38) extending uniformly along the peripheral surface (36) and extending between the two end-side lateral surfaces (32),
wherein each retaining groove (38) has at least one circumferentially extending undercut (20) for forming a corresponding tooth (22),
characterized in that
in at least one of the two end-side side surfaces (32) a relief slot (26, 28) is provided, which is arranged in the region of the tooth (22). A rotary body (30) according to claim 1,
in which the relief slot (26, 28) seen in the radial direction is partially provided between the undercut (20) and the peripheral surface (36). Rotary body (30) according to claim 1 or 2,
in which the relief slot (26, 28) is kidney-shaped or U-shaped. Rotary body (30) according to one of claims 1 to 3,
wherein at least the material surrounding the two ends (31) of the relief slot (26, 28) of the rotating body (30) is surface-hardened. Rotary body (30) according to one of claims 1 to 4,
in which the relief slot (26, 28) has a penetration depth (E) of 1 mm to 25 mm, preferably 5 mm to 20 mm. Rotary body (30) according to one of claims 1 to 5, wherein the retaining grooves (38) are formed in cross-section fir-tree-shaped, hammer-shaped or dovetailed. The rotary body (30) according to any one of claims 1 to 6, wherein each tooth (22) has a relief slot (26, 28) associated therewith. A rotary body (30) according to any one of claims 1 to 6, wherein the radially outer tooth (22) provided has a relief slot (26, 28) associated therewith. Rotary body (30) according to one of claims 1 to 8, which is designed as a rotor disk (19) or as a rotor rotor.

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