EP2723991A1

EP2723991A1 - Blade arrangement

Info

Publication number: EP2723991A1
Application number: EP12748427.7A
Authority: EP
Inventors: Uwe Sieber; Sascha Dungs; Elliot Griffin; Markus Paus; Stefan Reichling; Hubertus Michael Wigger; Dirk Wistuba
Original assignee: Siemens AG
Current assignee: Siemens AG
Priority date: 2011-08-24
Filing date: 2012-08-14
Publication date: 2014-04-30
Anticipated expiration: 2032-08-14
Also published as: EP2562356A1; EP2723991B1; BR112014003884A2; BR112014003884B8; JP2014527594A; US20140234111A1; CA2846053A1; CN104053858B; BR112014003884B1; US9708919B2; MX340744B; CN104053858A; KR20140068077A; JP5922237B2; MX2014002130A; WO2013026735A1; TWI606175B; RU2603696C2; RU2014111052A; TW201326537A

Abstract

The invention relates to a blade arrangement (40) having a blade carrier (56) and having a retaining groove (58) arranged in said blade carrier, which retaining groove has projections (62) extending along the side walls (60) thereof so as to form undercuts (64) and into which retaining groove a number of blades (25, 27) are inserted so as to form a blade ring of a turbomachine, wherein each blade (25, 27) has, in addition to a blade airfoil (48) and for fastening purposes, a blade root (50) which engages into the undercuts (64), and each blade is pressed against the projections (62) by an element (46) arranged between a blade root underside (68) and a groove base (70) of the retaining groove (58). To specify a particularly secure, reliable, durable and low-wear fastening which permits particularly simple assembly and disassembly, it is provided that each element (46) is of plate-like form and has, in the projection of the blade airfoil (48) in the direction of the groove base (70), at least one bead (52, 55), arranged beneath the blade airfoil (48), for imparting a pressing action, and in the longitudinal direction of the retaining groove (58), only part of the blade root (50) which said element presses against is covered.

Description

description

vane assembly

The invention relates to a blade arrangement according to the preamble of claim 1.

Such blade arrangements are well known from the widely available prior art. The well-known

Blade assemblies are used for both vanes and blade rows of compressors, with a circumferential groove being provided in a blade carrier for receiving all the blades of the series. The attachment of the

Shoveling in the circumferential groove takes place with the aid of a hammer-shaped or dovetail-like positive connection, in that appropriately designed blade roots engage behind projections projecting from the side walls of the retaining groove. To bring about a backlash-free, wear-resistant and reliable clamping of the blades in the retaining groove, it is known to use Underbench in Ge ^¬ Stalt of keyways, spring elements in the form of a spiral spring or a longitudinally as transversely slotted clamping sleeve between Schaufelfußunterseite and the groove base. This can be in the radial direction existing assembly and manufacturing games between blade and groove kom ^¬ pensieren, which made a simple manufacture and assembly ^¬ light. The problem is that the games in the radial direction can lead to difficulties in ensuring the tolerances in Nutumfangsrichtung. Therefore, it is known that to adjust the radial gap between the blade tip ^¬ tip and one of these immediately opposite channel boundary, the profile ends are ground or made by turning to measure, while the blades mounted in the groove are pressed outwards. Apart from this, there is often the problem of achieving a simple assembly and disassembly of blades and the substructures with low production costs. The object of the invention is therefore to provide a blade arrangement in which a durable and at the same time reliable and secure fastening of the blades in the circumferential groove is ensured with simple assembly and disassembly.

The object is achieved with a blade arrangement according to the features of claim 1. Advantageous embodiments of the invention are specified in the subclaims, which can be combined with one another in any desired manner.

According to the invention, it is provided that each element is plate-shaped, in the projection of the airfoil towards the groove base at least one arranged below the airfoil bead for pressing the blade in the groove ^¬ and in the longitudinal direction of the retaining only partially covered by him pressed blade root is.

With the aid of the element according to the invention, it is possible that this has a particularly suitable shape, which allows a locally resilient substructure and at another local point a rigid-looking substructure. On the one hand, the element is particularly easy to manufacture and, on the other hand, it is particularly easy to assemble and disassemble. The stiffening effect is generated by a bead or several beads. The ease of assembly and disassembly is achieved by the fact that in the longitudinal direction of the holding ^¬ groove the element in question is only partially covered by the pressed by him blade root. Thus, always a portion of the element stands out, which is particularly easy to reach for a disassembly tool. Furthermore, the plate-shaped geometry of the element allows a space-saving design and blade arrangement.

Particularly preferred is the embodiment in which in the retaining groove between each two blades, a one-piece or multi-piece intermediate piece is inserted, which is pressed by the not covered by the blade root part of the element to the projections. In this case, there are identical number of blades, intermediate pieces and elements, wherein the elements have a longitudinal extent which is equal to the longitudinal extent of blade root and intermediate piece. The assembly of the elements is offset with respect to spacers and blades, so that the element - viewed in the longitudinal direction of the retaining - extends completely under the blade root and each partially extends below the two, the blade root adjacent spacers. Thus, each intermediate piece of two elements is pressed against the projections of the retaining groove.

Preferably, the elements are designed such that the respective intermediate pieces are pressed against the projections with less force than the pressed by the respective element to the projections blade root. In particular, different stiffnesses of the element can be used particularly advantageously for different requirements. For the assembly of the intermediate pieces a lower spring force of the element is in fact desirable and not Benö ^¬ Untitled, since no high forces are applied in operation to the intermediate ^¬ tee. In contrast, the blades clamped in the blade carrier are exposed to flow forces during operation. This requires a more reliable attachment of the blades to the blade carrier, which requires a larger contact force. The higher contact pressure is achieved by the locally higher rigidity of the element. This will be caused by the bead (s) arranged in the element.

In the case of a stiffer substructure of the blade, advantageously different working principles can be used for assembly and subsequent operation. On the one hand, the local material plasticization of the bead is provided to compensate for manufacturing tolerances during assembly. On the other hand, a use of the residual elasticity is provided to then absorb the operating forces. For this purpose, a material for the element which is characterized by a relatively high aspect ratio of the code number for the maximum tensile strength (Rmax) to yield (RP0.2) is advantageous ^¬ adhesive used, characterized (Index Rmax / Rp0.2> 1.5), whereby with material choice the yield strength at the same time still sufficiently large enough for the operating force must be. The locally more rigid region of the element is preferably designed as a bead. Particularly advantageous is the design of the bead in a manner in which a kinked Kenn ^¬ line results in force- ^displacement relationship. As a result, a residual elasticity for absorbing the operating forces is ensured over a wide range. This can be achieved with a first Si ^¬ ckengeometrie, wherein the element is a wall ^¬ strength S and the bead, in cross section, a bead width b so ^¬ as two convex portions having a radius R2, and a da ^¬ between arranged concave portion with a radius R having a chord length A, for which:

R1> 1.5S,

3 * R2> Rl <0, 7R2 and

10b to 1, 7b> a. A second bead geometry with similar properties is achieved when R1> 5S, 3 * R2> R1 and a <0.9b.

A third bead geometry as a combination of the first two bead geometries with similar properties leads to a double bead called a double bead, which has a ^further enlarged elastic range.

Preferably, the beads in the element are located such that they are arranged in the projection of the blade in the direction of the groove base below the blade. With walls ^¬ ren words are located as the elements along the peripheral groove always offset from the blades, the beads are arranged principally in the interior of the element or at the edge thereof. This allows easy assembly and disassembly of the elements.

More preferably, the element in its non-covered by the review ^¬ felfuß area on at least one aperture. In this opening can engage a disassembly hook or tool to disassemble it from its operating position.

A simple mountability of the element can be achieved if a groove extending along the retaining groove is located in the groove base of the retaining groove or in the blade ^root bottom side as a dismantling groove. During disassembly, a slide hammer can be comparatively easily attached there and during assembly, the insertion / compression of the element between the blade and the groove is simplified by means of a plunger.

Conveniently, the element in the projection of the airfoil towards the groove bottom (radial line of sight) a externa ^¬ ßere contour which is substantially rectangular. In this projection, the element in question is only half covered by the blade pressed by it. Such contoured elements are particularly inexpensive and easily establishes ^¬ adjustable. Particularly advantageous is the embodiment in which a longitudinal edge of the member is angled at least ^¬ abutting biased to the corresponding thereto shaped blade roots. If intermediate pieces are used in the blade arrangement, the angled longitudinal edges can also be prestressed against the correspondingly shaped intermediate pieces. This configuration makes it possible for the blades not to be aligned solely on the basis of the groove geometry and the blade root geometry, but also to align themselves on the basis of the respective neighboring component-vane or intermediate piece. This feature is used to vorteilhaf ^¬ th reducing contact wear.

Further advantageously, the element on at least one edge at least one further bead for local reinforcement and for guiding the element in a guide groove. This further bead on the edge, preferably the transverse edge, can simplify the assembly, since at the local stiffening a ram for driving / pushing the element between Schaufelfußunter- side and groove base can be applied without the element bends locally during closing ^¬ driving.

Particularly preferred is the embodiment in which the bead is configured as an inner bead which is located in a ^¬ this to at least partly surrounding the outer bead is. This is also referred to as a double bead embodiment made light ^¬ a further enlargement of the elastic range of the element. Likewise, the use of 3-fold beads or even n-fold beads is conceivable in which a corresponding number of beads from the inside to the outside is virtually stacked or arranged hierarchically.

Particularly preferred is the embodiment in which the show ^¬ felanordnung is used in an axially flow-through compressor of a gas turbine, either for a blade ring and / or for a vane ring. This ensures a reliable, secure and more efficient operation of the gas turbine, as with this embodiment, the Radi alspalte ^¬ can be made small between the blade tips and the channel lying opposite wall of the flow passage of the compressor be ^¬ Sonders.

The invention will be explained in more detail in the following description of the figures with reference to several embodiments, wel ^¬ che not limit the invention. In this case, further features and other advantages are given. Show it:

1 shows a longitudinal section through a gas turbine, FIG 2, the plan view of a section of a

Blade assembly according to a first embodiment,

3 shows a cross section through the blade arrangement according to FIG. 2 according to section line III-III, FIG. 4 shows the longitudinal section through the cutout of

Vane arrangement according to FIG 2 along section line IV-IV ^¬, Figures 5, 6, the cross sections of a blade arrangement similar to the section line IV-IV of a second and third embodiment,

7 is a plan view of a portion of a

Blade assembly according to a fourth embodiment (without spacers),

8, 9 show two variants of the fourth embodiment according to FIG

7 in cross section along section line III-III,

10 is a plan view of a portion of a

Blade assembly according to a fifth embodiment (without spacers),

FIG 11, FIG 12 shows two variants of the fifth embodiment according to

7 in cross section ^along section line III ^¬ III, FIG 13 is a force-elasticity diagram,

FIG 14, FIG 15 shows the cross-section of an element with different union under ^¬ geometries of beads and FIG 16 shows the cross section through a bead geometry in

Shape of a double bead.

In the figures, identical features with the same reference numbers are provided ^¬ Be.

1 shows a stationary gas turbine 10 in a longitudinal ^¬ partial section. The gas turbine 10 has inside a by one Rotation axis 12 rotatably mounted rotor 14, which is also referred to as a turbine runner. Along the rotor 14 follow one another an intake housing 16, an axial turbo compressor 18, a toroidal annular combustion chamber 20 with a plurality of rotationally symmetrical mutually arranged burners 22, a turbine unit 24 and an exhaust housing 26.

The Axialturboverdichter 18 includes a ring-shaped compressor duct with cascading successively ^¬ ing compressor stages of Laufschaufei- and Leitschaufel ^¬ wreaths. The rotor blades 14 arranged on the blades 27 lie with their free-ending blade tips 29 of an outer channel wall 42 of the compressor passage opposite. Also protrude vanes 25 which are secured to the outer duct wall 42 or to a Verdichterleitschaufelträger. The compressor duct discharges via a compressor outlet diffuser 36 in a plenum 38. The annular combustion chamber 20 is provided with its combustion chamber 28, which communicates with an annular hot gas duct 30 of the turbine unit 24. In the turbine unit 24 four successive turbine stages 32 are arranged. On the rotor 14, a generator or a working machine (each not shown) is ^¬ coupled. During operation of the gas turbine 10, the axial turbocompressor sucks

18 through the suction housing 16 as a medium to be compressed Um ^¬ ambient air 34 and compresses them. The compressed air is guided through the compressor outlet diffuser 36 into the plenum 38, from where it flows into the burner 22. Fuel also passes into the combustion space 28 via the burners 22. There, the fuel is burned to a hot gas M with the addition of the compressed air. The hot gas M flows to ^¬ closing in the hot gas channel 30 where it perform work on the turbine blades of the turbine unit 24th During which the energy released is removed from the rotor 14 on the one hand, and ^¬ for driving the Axialturboverdichters 18 and on the other hand for driving a working machine or the electric generator used. 2 shows a plan view of a detail of a blade arrangement 40 in which only two blades 25, 27 with an intermediate piece 44 located therebetween and two elements 46 arranged therebelow are shown schematically. The vanes 25, 27 comprise a schematically indicated blade 48 and a blade root 50. The top ^¬ view takes place in the direction of the radial direction of the gas turbine 10, that is, from the blade leaf in the direction of blade 50. In Figure 2, not shown of the blade carrier, and means disposed in the carrier retaining groove. The elements 46 have a rectangular outer contour and are plate-shaped forms ^¬ out. Colloquially, they are also referred to as sheet-shaped. In the first embodiment (FIG 2), the blade roots 50 and the blades 25, 27 of the Schaufelanord ^¬ voltage with respect to a longitudinal extension of the retaining groove and a circumferential direction U are arranged obliquely. This job is typical for running. Each element 46 has two beads 52 and two Publ ^¬ voltages 54th The elements 46 are in the circumferential direction U as long as the blade root 50 and spacer 44 together. However, the elements 46 are arranged centrally below the respective blade 25, 27, so that two adjacent elements 46 each end centrally with their opposite ends below the intermediate pieces 44.

FIG 3 shows the cross section according to section line III-III through the blade root 50 of the blade 25, 27 and ger a Schaufelträ- 56. The airfoil is (in FIG 3 and in the Figu ^¬ ren 5, 6, 8, 9, 11 and 12) not shown. In Schaufelträ ^¬ ger 56 extends a retaining groove 58 in which the show ^¬ blades 25, 27, in detail, the blade roots 50 of the blades 25, 27, are positively inserted. To form the formations, the side walls 60 of the retaining grooves 58 have longitudinally extending projections 62 for forming undercuts 64. Correspondingly executed, hammer-shaped foot regions 66 engage in the undercut 64. Between a blade root bottom 68 and a groove bottom 70 of the retaining groove 58, the element 46 is braced. In addition, a further, along the retaining groove 58 erstre ^¬ ckende disassembly groove 72 is provided in the groove bottom 70. The further groove 72 serves for the access of a disassembly tool, for example a slide hammer.

The wall thickness S of the element 46 (FIG. 14) is less than the gap between the blade root lower side 68 and the groove bottom 70. The beads 52 produced in the element 46 by deep-drawing or press-fitting enlarge the height H of the element 46 beyond the gap dimension, so that the blade root 50 is pressed against the projections 62. This leads to a Unambiguous ^¬ gen defined position of the blades 25, 27 in the holding 58th

4 shows the longitudinal section through the embodiment according to FIG 2 along the section line IV-IV. The embodiment of the blade arrangement 40 illustrated in FIGS. 2, 3 and 4 is a section of a rotor blade ring of a compressor 12 of the gas turbine 10. Accordingly, the blade carrier 56 is formed by a rotor disk and the blades 25, 27 as Laufschaufein trained.

The elements 46 are substantially planar and thus do not follow the curvature of the retaining groove 58. As a result, the elements 46 with their central region, in which the beads 52 are arranged, press with greater force blade foot ^¬ bottom 68 and groove bottom 70 apart , The adjacent to the transverse edges 82 portions of the element 46 are due to the planar configuration of the elements 46 and the curved retaining groove 58 then with less force resiliently against the undersides of the intermediate pieces 44. Consequently, the element 46 presses the intermediate pieces 44 and the blades 25, 27 against the projections 62 of the retaining groove 58 due to locally different stiffnesses with different degrees of force. A second embodiment of a blade arrangement 40 is shown in FIG. FIG 5 shows the cross section according to FIG 3. In this case ^¬ 5 are provided to FIG 3 identical features having identical reference numerals in FIG substantially. For description of FIG 5 reference is largely made to the description of FIG 3. According to the second embodiment, however, the longitudinal edges 74 of the element 46 are bent to the groove opening of the retaining groove 58 out. The bent-over longitudinal edges 74 (see FIG. 2) are prestressed on bevels 76 arranged on blade bottom side. Since the spacers 44 are formed in an analogous manner to the blade roots 50 of the blades 25, 27, are also located below the intermediate part 44 to gesiedelte ^¬ portions of the longitudinal edges 74 of the element 46 pre-tensioned to ^¬ at corresponding chamfers. The bent longitudinal edges 74 of the element 46 and the biased contact of the elements 46 on the blade roots 50 and spacers 44, a frictional coupling of the adjacent Bau ^¬ parts - blade root 50 and spacer 44 - caused, which improves their orientation and see contact wear between reduced the components.

A third embodiment of a blade arrangement 40 is shown schematically in FIG. FIG. 6 also largely shows the same cross section as FIG. 3, so that identical features are provided with the same reference numerals in FIG. 6 to FIG. In contrast to the embodiment according to FIG. 3, the third embodiment according to FIG. 6 has a comparatively wide but only a small depth, on the blade foot lower side 68, extending in the longitudinal direction of the retaining groove 58. The groove 78 serves to receive the element 46, so that the groove depth of the groove 78 substantially corresponds to the wall thickness S of the element 46. The longitudinal edges 74 of the element 46 (see FIG 2) abut against the inclined side walls of the groove 78. To the same extent as the blade root 50, a groove 78 arranged on the underside thereof is also provided in the intermediate pieces 44 according to the third embodiment, so that the longitudinal edges 74 of the element 46 are also provided on the side walls of the groove arranged on the intermediate piece 44 78 are present. By the simultaneous contact of the elements 46 on blade 25, 27 and intermediate piece 44, a coupling of the adjacent blade ring components is brought about, which reduces wear, in particular contact wear. Both in the second embodiment according to FIG. 5 and the third embodiment according to FIG. 6 of the blade arrangement 40 according to the invention, the blades are designed as rotor blades 27. FIGS. 8 and 9 show in a manner analogous to the cross section according to FIG. 3 a cross section through a blade arrangement 40 according to a fourth embodiment. In contrast to the aforementioned embodiments, the arrangements shown in FIGS. 7, 8 and 9 are configured as vane rings and not as rotor blade rings. As a result, the cross-sectional contours of the retaining groove 58 and the blade root 50 differ only slightly. Another difference from the previously described embodiments is that no intermediate pieces 44 are provided between adjacent guide vanes 25. Accordingly, the blades 25 are, as shown in the illustration of FIG 7, flat and without employment of the blade roots 50 together. In this case, the Ele ^¬ elements 46 are each arranged in half by a pair of adjacent acting ^¬ feln 25th It follows that the stiffening beads 52 are not located in the interior of the element 46, but on two opposite transverse edges 82 of the elements 46. Otherwise, the first variant of the fourth embodiment of FIG 8 is constructed in an analogous manner as the second embodiment according to FIG 5 with the angled off longitudinal edges 74 of the element 46. a second variant of the fourth embodiment shown in FIG 9, corresponds structurally to substantially the third embodiment of Figure 6, in which the element 46 in a blade at the bottom ^¬ 68 arranged groove 78 is largely sunk.

A fifth embodiment of the blade assembly 40 is shown in a top view according to FIG 10, to the two Vari ^¬ distinctive, a first cross-section in FIG 11 and a second in Cross section in FIG 12, are shown. The fifth embodiment Darge ^¬ presented in FIG 5 is essentially based on the embodiment shown in FIG 2 the first embodiment. However, in addition to the beads 52 arranged in the inner region of the element 46, further beads 86 are provided at the transverse edges 82-in a manner analogous to the fourth embodiment shown in FIG. By using the further beads 86 on the edge, bending or buckling of the element 46 can be reliably avoided when the element 46 is driven in between the blade footer bottom 68 and groove base 70. At the same time, the further beads 86 engage either in the dismounting groove 72 (FIG. 11) or in a groove 78 (FIG. 12) arranged on the underside of the blade for aligning or guiding the elements 46. FIGS. 14 and 15 each show an embodiment of the invention

Elements 46 in cross-section along the section line III-III of FIG 2. In contrast to the element 46 shown in FIG 2, only one bead 52 and not two beads 52 are shown in Figures 14, 15. Each bead 52 comprises two convexly bent portions X and a concave portion V arranged therebetween. The convex portions X each have a radius R2 and the concave portions V have a radius R1. The concave portion V also has a chord length a, wherein the bead 52 includes a bead width b. In order to obtain the bead 52 itself with a range of plastic deformation for higher loading force and higher spring rate as well as for a range with elastic deformation with low spring rate, two embodiments of the element are proposed. The first embodiment is achieved when

R1> 1.5 * S, 3 * R2> R1> 0.7 * R2 and 10 * b to l, 7 * b> a. By way of example, the parameters may have the following dimensions: Rl = 2 mm; R2 = 2 mm; S = 1 mm; a = 3.5 mm and b = 10 mm.

The second embodiment of an element 46 provides that Rl> 5 * S,

3 * R2 <Rl and a <0, 9 * b.

By way of example, the parameters may have the following dimensions: Rl = 20 mm; R2 = 2 mm; S = 1 mm; a = 6 mm and b = 10 mm.

With the aid of the illustrated embodiment, it is possible that the portion V represents the area of plastic deformation with the higher loading force and higher spring rate, and the portions X the areas for the elastic deformation with low spring rate, which is also FIG.

16 shows the cross section through a special bead geometry. The special bead geometry is a multiple bead 55 in which an inner bead 55i is surrounded by one or more beads 55a. The beads 55i, 55a of the multiple bead 55 are quasi stacked or hierar ^¬ chically arranged with a common center M. The multiple bead 55 shown in FIG. 16 is a 2-fold bead, also called a double bead. Double bead here means that in principle a concave portion of a first Va (in which case outer) bead 55a (then inner) Si is located ^¬ blocks 55i a second. This Sick combination has against ^¬ on the aforementioned geometries, which can be referred to as a 1-fold-beads, a further increased elasticity, whereby greater manufacturing tolerances for the blade roots 50, if necessary, intermediate pieces 44 and retainer groove 58 allowed who can ^¬. Dimensions for the bead geometry according to FIG. 16 are then, for example:

R20 = 20 mm; Rl .2 = 2 mm; R2 = 2 mm; ba = 11 mm, aa = bi = 7.4 mm, R3 = 2 mm and ai = 3.2 mm.

Overall, the invention relates to a bucket assembly 40 with a blade carrier 56 and disposed therein Hal- tenut 58 which longitudinally erstre ^¬ ADORABLE projections 62 to form undercuts 64 has on its side walls 60, and in which a number of blades 25, 27 for Forming a blade ring of a turbomachine used is, wherein each blade 25, 27 next to a blade 48 for fastening a hammer-shaped, in the undercuts 64 64 engages 64 and 64 is pressed by between a Schaufelfußunterseite 68 and a groove bottom 70 of the retaining groove 58 disposed member 46 to the projections 62. In order to provide a particularly safe, reliable, long ^¬-lived and low-wear fixture that is enables be ^¬ Sonders easy assembly and disassembly pre ^¬ seen that each element is plate-shaped 46, in the projection of the airfoil 48 in the direction of groove bottom

70 has at least one arranged below the airfoil 48 bead 52 for pressing and in the longitudinal direction of the retaining groove 58 is only partially covered by the pressed him blade root 50.

Claims

claims

1. blade arrangement (40),

with a blade carrier (56) and disposed therein

Retaining groove (58) having on its side walls (60) longitudinally extending projections (62) for forming undercuts (64) and in which a number of blades (25, 27) used to form a blade ring of a turbo machine is

wherein each blade (25, 27) adjacent to an airfoil (48) for attachment in the undercuts (64) engaging blade root (50) and by a between a Schaufelfußunterseite (68) and a groove bottom (70) of the retaining groove (58) arranged element (46) on the pre ^¬ cracks (62) is pressed,

characterized in that

each element (46)

- is plate-shaped,

- Has at least one bead (52, 55) for pressing and

- In the longitudinal direction of the retaining groove (58) is only partially covered by the pressed him from the blade root (50).

2. blade assembly (40) according to claim 1,

in which in the retaining groove (58) between two blades (25,

27) an intermediate piece (44) is inserted, which is pressed by the by the blade root (50) not covered part of the ele ^¬ ment (46) to the projections (62). 3. blade assembly (40) according to claim 2,

in which the element (46) presses the relevant intermediate piece (44) against the projections (62) with less force than the relevant blade root (50).

4. blade assembly (40) according to claim 3,

in which the area of the element (46) covered by the blade root (50) is made somewhat stiffer than the remaining part of the relevant element (46)

5. blade assembly (40) according to any one of the preceding claims,

in which the element (46) has at least one opening for disassembly in its area not covered by the relevant blade root (50).

6. blade assembly (40) according to any one of the preceding claims,

in the groove base (70) of the retaining groove (58) or in the blade root lower side (68) has a longitudinally extending groove

(72, 78) is arranged.

7. vane assembly (40) according to any one of the preceding claims,

wherein the element (46) in a projection an outer

Contour which is substantially rectangular.

Blade assembly (40) according to claim 7,

wherein at least one longitudinal edge (74) of the element (46) is angled, which abuts the corresponding thereto out ^¬ shaped blade roots (50) biased.

9. vane assembly (40) according to claim 2 and 7,

is in the at least one longitudinal edge (74) of the element (46) is angled, on said corresponding thereto out ^¬ shaped blade root (50) and at the corresponding thereto shaped intermediate piece (44) rests pretensioned.

10. vane assembly (40) according to claim 7 or 8,

wherein at least one edge of the element (46) at ^¬ least one further bead (86) is provided. 11. blade assembly (40) according to any one of the preceding claims,

wherein the element (46) has a wall thickness (s) and the bead (52, 55, 86) in cross-section a bead width (b) and two convex portions (X) with a radius (R2) and a concave portion (V ) with a

Radius (Rl) having a chord length (a),

for the following applies:

Rl> l, 5 * s,

3 * R2> Rl <0, 7 * R2 and

10 * b to 1, 7 * b> a or

Rl> 5 * s,

3 * R2 <Rl and

a <0, 9 * b.

12. blade assembly (40) according to any one of claims 1 to 11,

in which the bead is designed as a multiple bead.

13. blade assembly (40) according to claim 12,

wherein the multiple bead (55) comprises an inner bead (55i) located in at least one outer bead (55a) at least partially surrounding it.

14. An axial compressor for a gas turbine (10) with a blade ring and / or a vane ring formed as a blade assembly (40) according to any one of the preceding claims.