EP2410131A2 - Rotor of a turbomachine - Google Patents

Abstract

The rotor has a rotor base body and multiple blades, where each blade has a blade base and a turbine blade. Each coupling element segment (10,10',10'') of each rotor blade contours at a side and at another side lying against the former side such that a radial outer edge and a radial inner edge of the respective coupling element segment border two surfaces separated from each other by a separator line (26,27) at the sides. The radial outer edge and radial inner edge extend in axial direction.

Description

The invention relates to a rotor of a turbomachine according to the preamble of claim 1.

A rotor of a turbomachine, in particular a gas turbine or steam turbine, has a rotor base body and a plurality of rotor blades which are fastened to the rotor base body. The blades of such a turbomachinery rotor have a blade root and an airfoil, each blade being secured via its blade root to the rotor body in a groove of the rotor body in a mounting direction defined by the blade roots, and each blade having at least one coupler segment in the region of its airfoil when it is positioned radially outward on the airfoil, is formed as an outer shroud segment. The coupling element segments, in particular outer shroud segments, of all the moving blades of such a turbomachine rotor together form at least one coupling element closed in the circumferential direction, in particular an outer shroud, of the rotor.

As seen in the circumferential direction of a turbomachinery rotor, a width of a coupling element segment, in particular an outer shroud segment, of each blade is defined by edges extending substantially in the axial direction. A depth in the axial direction of the coupling element segment, in particular the outer shroud segment, of each blade is defined by substantially circumferentially extending edges. In addition to the width in the circumferential direction and the depth in the axial direction, a coupling element segment, in particular an outer shroud segment, each blade is also characterized by a thickness in the radial direction.

Turbomachine rotors whose rotor blades have such coupling element segments for forming at least one coupling element can be installed both in the region of a compressor and in the region of a turbine of the turbomachine.

Turbomachinery rotors, on the rotor base body of which rotor blades are fastened, which have a coupling element segment formed radially on the outside of the airfoil as an outer cover band segment, are for example made DE 1 159 965 C , out DE 40 15 206 C1 as well as out US 4,400,915 A and from GB 2 072 760 A known. From the EP 1 134 359 A1 and the DE 1 122 551 C the attachment of the blades on the blade roots on the rotor base body in a groove of the rotor base body in a mounting direction defined by the blade feet is known. The blade feet may be fir-tree-like, hammerhead-like or otherwise contoured. For each blade root, a separate groove may be present on the rotor body. Furthermore, it is possible that all blade roots are mounted in a common groove and threaded into this common groove via a threading and thus mounted on the rotor body.

In particular, the coupling elements of such turbomachinery rotors designed as outer shrouds are exposed to high loads during operation, since they rotate with respect to a rotational axis of the turbomachine rotor to a maximum radius and are therefore exposed to high centrifugal forces. As a result of the centrifugal force, corners or edges of the coupling element segments of the blades can bend outwards, which on the one hand in the coupling element voltage peaks are caused and on the other hand, a desired contact between adjacent coupling element segments adjacent blades is reduced to a punctiform contact or disappears completely. As a result, a desired coupling between adjacent coupling element segments is reduced or eliminated, which ultimately worsens the vibration behavior of the turbomachine rotor.

On this basis, the present invention is based on the problem to provide a rotor of a turbomachine, in which a good coupling of the coupling element segments of the blades is ensured with good mountability of the rotor during operation.

This problem is solved by a rotor according to claim 1. According to the invention, the or each coupling element segment of each blade on a first side, in the circumferential direction, a coupling element segment of a first immediately adjacent blade connects, and at one on one of the first side opposite the second side, seen in the circumferential direction, a coupling element segment a second immediately adjacent blade adjoins, contoured such that on the first side and on the second side of a substantially axially extending radially outer edge and a substantially axially extending radially inner edge of the respective coupling element segment each two separated by a dividing line Limiting surfaces, wherein at at least one circumferential position of the rotor between two directly adjacent blades formed on immediately adjacent sides of the coupling element segments dividing lines of these immediately adjacent In some other circumferential position between two immediately adjacent blades formed on immediately adjacent sides of the coupling element segments dividing lines of this immediately adjacent blade to the mounting direction of the blades on the rotor blades at approximately approximately parallel or rectified to the mounting direction defined by the blade feet Rotor body are tilted.

In the case of the rotor of a turbomachine according to the invention, the contouring of the coupling element segments of the rotor blades ensures optimum support and thus coupling of the coupling element segments forming the or each coupling element with good mountability of the rotor.

As a result, voltage spikes in the or each coupling element of the rotor can be significantly reduced with good mountability of the rotor during operation. Furthermore, this can improve the natural frequency behavior and therefore the vibration behavior of the rotor according to the invention with good mountability thereof.

Fig. 1:

eine schematisierte, ausschnittsweise Draufsicht auf ein als Außendeckband ausgebildetes Koppelelement eines erfindungsgemäßen Rotors einer Turbomaschine in Blickrichtung von radial außen nach einem ersten Ausführungsbeispiel der Erfindung;

Fig. 2:

eine schematisierte Draufsicht auf eine Laufschaufel des Rotors der Fig. 1, nämlich auf ein als Außendeckbandsegment ausgebildetes Koppelelementsegment der Laufschaufel des Rotors der Fig. 1, in Blickrichtung von radial außen;

Fig. 3:

einen perspektivischen Ausschnitt aus der Laufschaufel der Fig. 2 in Umfangsblickrichtung I der Fig. 2 gesehen;

Fig. 4:

einen weiteren perspektivischen Ausschnitt aus der Laufschaufel der Fig. 2 in Umfangsblickrichtung II der Fig. 2 gesehen; und

Fig. 5:

eine schematisierte, ausschnittsweise Draufsicht auf ein als Außendeckband ausgebildetes Koppelelement eines erfindungsgemäßen Rotors einer Turbomaschine in Blickrichtung von radial außen nach einem zweiten Ausführungsbeispiel der Erfindung.

Preferred embodiments of the invention will become apparent from the dependent claims and the description below. Embodiments of the invention will be described, without being limited thereto, with reference to the drawings. Showing:

Fig. 1:

a schematic, fragmentary plan view of a designed as outer shroud coupling element of a rotor according to the invention of a turbomachine in the direction of view from the outside radially to a first embodiment of the invention;

Fig. 2:

a schematic plan view of a rotor blade of the rotor Fig. 1 , Namely on a coupling element segment formed as an outer cover band segment of the rotor blade of the rotor Fig. 1 , in view from radially outside;

3:

a perspective section of the blade of the Fig. 2 in the circumferential direction of the I Fig. 2 seen;

4:

another perspective section of the blade of the Fig. 2 in the circumferential direction II of Fig. 2 seen; and

Fig. 5:

a schematic, fragmentary plan view of a trained as outer shroud coupling element of a rotor of a turbomachine according to the invention in the direction of view from the outside radially to a second embodiment of the invention.

The present invention relates to a rotor of a turbomachine, in particular a rotor of a compressor or a turbine of a turbomachine designed as a gas turbine or steam turbine. However, the invention is not limited to these applications, but the invention can be used in all turbomachinery rotors.

A rotor of a turbomachine basically has a rotor main body and a plurality of rotor blades, which are fastened to the rotor base body via blade feet. In Fig. 1 to 5 the rotor body and the blade roots of blades are not shown in detail since these details are familiar to those skilled in the art. However, it should be noted at this point that each blade is fastened via its blade root on the rotor base body in a groove of the rotor base body in a mounting direction defined by the blade feet. In this case, a separate groove on the rotor base body may be present for each blade or the blade root of each blade. Furthermore, it is possible that all blades are fastened via their blade roots in a common groove and are threaded into this common groove via a threading opening and thus mounted on the rotor base body.

In Fig. 1 and 5 the mounting direction M of the blades on the rotor base body defined by the blade feet is shown schematically in dashed lines. In Fig. 1 and 5 For the blade root of each blade a separate groove on the rotor body is present, in Fig. 1 the mounting direction M rectilinear and in Fig. 5 the mounting direction M is curved. In both cases, as seen in the axial direction A of the rotor, the mounting direction M of the blades is inclined with respect to the axial direction A in a first orientation in the circumferential direction U, wherein the mounting direction M and the axial direction A include a so-called rhomboid angle, which in a curved mounting direction M in the axial direction A changed. In addition to the axial direction A and the circumferential direction U of the rotor, a radial direction R of the same is furthermore shown.

Fig. 1 to 4 show different detail views of a rotor according to the invention of a turbomachine according to a first embodiment of the invention, wherein in Fig. 1 3 shows a section of a coupling element designed as an outer cover strip, which is composed of coupling element segments 10, 10 ', 10 "of a plurality of moving blades formed as outer cover tape segments 3 and 4 can be removed, is associated with a radially outer end of a blade 11 of the respective blade. The airfoil 11 has a flow inlet edge 12, a flow outlet edge 13 and a suction side 14 and pressure side 15 extending between the flow inlet edge 12 and the flow outlet edge 13.

The outer shroud segment 10, 10 ', 10 "radially outwardly assigned to the blade 11 of each blade has a width in the circumferential direction U, which is defined by edges extending substantially in the axial direction A. Thus, on two opposite sides 16 and 17 of FIG Outer shroud segment 10, 10 ', 10 "in each case one extending substantially in the axial direction A, radially outer edge 18 and 19 and in each case also extending substantially in the axial direction A, radially inner edge 20 and 21. The distance between this radially outer edge 18 and 19 and this radially inner edge 20 and 21 determined on the sides 16 and 17 in the radial direction R, the thickness of the outer shroud segment 10, 10 ', 10 ".

A depth in the axial direction A of the outer shroud segment 10, 10 ', 10 "of each blade is defined by edges extending substantially in the circumferential direction U, again by radially outer edges 22 and 23 and radially inner edges 24 and 25, respectively The edges 22 and 24 are flow-entry-side edges and edges are flow-exit-edges at the edges 23 and 25. The distance between these edges also determines the thickness of the outer shroud segment 10, 10 ', 10 "in the radial direction R, namely on the flow inlet side and on the flow exit side.

As seen from radially outside, the outer shroud segment 10, 10 ', 10 "of each blade in the region of a first side 16, in which adjoins an outer shroud segment of a first immediately adjacent blade with a second side thereof in the circumferential direction U, contoured such that the radially inward edge 18 of the outer shroud segment 10, 10 ', 10 "extending substantially in the axial direction A, relative to the radially inner edge 20 of the outer shroud segment extending substantially in the axial direction A, the flow inlet side adjacent to the flow inlet edge 12 of the blade 11 of the respective blade 10, 10 ', 10 "protrudes in the circumferential direction U.

On this first side 16 facing the flow outlet on the flow outlet edge 13, the radially inner edge 20 of the outer shroud segment 10, 10 ', 10 "extending substantially in the axial direction A is opposite the radially outer edge 18, which also extends substantially in the axial direction A. Circumferential direction U before.

At the opposite, second side 17 of the outer shroud segment 10, 10 ', 10 ", at which an immediately adjacent, second blade with its outer shroud segment, namely with a first side thereof, followed, the same is contoured such that the flow outlet side adjacent to the flow outlet edge 13 of the airfoil 11 which extends substantially in the axial direction A extending, radially outer edge 19 of the outer shroud segment 10, 10 ', 10 "relative to the also extending substantially in the axial direction A, radially inner edge 21 in the circumferential direction U protrudes.

Facing away from the flow inlet edge 12 on this second side 17, the radially inner edge 21 of the outer shroud segment 10, 10 ', 10 "extends essentially in the axial direction A, relative to the radially outer edge 19 which also extends essentially in the axial direction A. Circumferential direction U before.

On the first side 16 of the outer shroud segment 10, 10 ', 10 ", which faces the flow inlet edge 12 of the blade 11 and facing away from the flow outlet edge 13 thereof, as well as on the second side 17 of the outer shroud segment 10, 10', 10", the The flow inlet edge 13 of the blade 11 facing and facing away from the flow inlet edge 12, limit the extending substantially in the axial direction A, radially outer edges 18 and 19 together with the respective also extending substantially in the axial direction A, radially inner edges 20 and 21 in each case two surfaces separated from one another by a dividing line 26 or 27, namely in each case one surface 28 or 29 concealed in the viewing direction from radially outside and one surface 30 or 31 visible in the viewing direction from radially outside.

On the first side 16 of the outer shroud segment 10, 10 ', 10 ", the surface 28, which is concealed from the outside, is positioned on the flow inlet side and the surface 30, which is visible from the radial outside, is positioned on the outlet side in the region of the opposite, second side 17 of the outer shroud segment 10, 10', 10 on the other hand, the surface 29, which is concealed radially from the outside, is positioned on the flow exit side and the surface 31, which is visible from the radial outside, is positioned on the flow inlet side.

According to the invention, at at least one circumferential position of the rotor between two immediately adjacent moving blades, the parting lines 26, 27 of these immediately adjacent moving blades extend approximately directly parallel or rectified to the mounting direction M defined over the blade roots of the rotor blades at the rotor base body, whereas at each other circumferential position between two directly adjacent rotor blades the separating lines 26, 27 of these immediately adjacent blades are inclined to the mounting direction M on immediately adjacent sides of the respective coupling element segments 10, 10 'and 10 ".

As already stated, the mounting direction M of the rotor blades on the rotor base body, viewed in the axial direction A of the rotor, is inclined relative to the axial direction A in a first orientation in the circumferential direction U by the so-called rhomboid angle. At the or each circumferential position of the rotor at which the dividing lines 26, 27 formed on the immediately adjacent blades extend approximately parallel or rectified to the mounting direction M of the blades on the rotor base defined by the blade feet, the parting lines 26, 27 in FIG same first orientation as the mounting direction relative to the axial direction A in the circumferential direction U inclined. In contrast, at the or any other circumferential position of the rotor between two directly adjacent blades, the dividing line 26, 27 inclined in a direction opposite to the first orientation second orientation as the mounting direction M relative to the axial direction in the circumferential direction.

The above contouring of the coupling element segments 10, 10 'and 10 "of the rotor blades ensures optimal support and thus coupling of the coupling element segments forming the or each coupling element with good mountability of the rotor Coupling element segments 10, 10 'and 10 "are inclined to the mounting direction M, an optimal support and thus coupling of the coupling element segments. The dividing lines 26 and 27, which extend approximately directly parallel to or parallel to the mounting direction M on immediately adjacent sides of the coupling element segments 10 'and 10 ", allow a good mountability, in particular of the last rotor blade to be mounted on the rotor blade single circumferential position of the rotor between two immediately adjacent blades on approximately immediately adjacent sides of the respective coupling element segments 10 'and 10 "formed dividing lines 26, 27 in approximately approximately parallel or rectified to the mounting direction M of the blades run on the rotor body. This can be the case for improving the vibration behavior but also at a plurality of circumferential positions of the rotor.

By virtue of the above contouring of the coupling element segments 10, 10 'and 10 "of the rotor blades, in the case of good mountability of the rotor during operation, voltage peaks in the or each coupling element of the rotor can be significantly reduced become.

At the or each circumferential position of the rotor, on which the dividing lines 26, 27 formed on the coupling element segments 10, 10 'and 10 "directly approximately parallel to the mounting direction M of the blades defined on the blade feet on the rotor main body, close the parting lines 26, 27 with the mounting direction M an angle of not more than 10 °, preferably of at most 5 °, a.

In the same orientation as the parting lines 26, 27, the radially outer edges 18, 19, which extend essentially in the axial direction A, and the radially inner edges 20, 21, which also extend essentially in the axial direction A, preferably run together with the dividing lines 26, 27, the surfaces 28, 29, 30 and 31 limit.

Then, when a parting line 26 and 27 is approximately approximately parallel or rectified to the mounting direction M of the blades, the respective edges 18, 20 and 19, 21 extend approximately parallel or rectified to the mounting direction M.

Then, when a parting line 26 and 27 are inclined with respect to the mounting direction M of the blades, the respective edges 18, 20 and 19, 21 are inclined to the mounting direction M, in the same orientation as the respective parting line 26 and 27th ,

The dividing lines 26 and 27 which separate the surfaces 28 and 30 and the surfaces 29 and 31 from each other on the first side 16 and on the second side 17 are executed according to a preferred embodiment of the invention without turning points, wherein the same in the embodiment of Fig. 1 to 4 straight and in Fig. 5 curved. This allows a particularly simple production. Likewise, the substantially extending in the axial direction A edges 18, 19, 20 and 21 are executed without turning points.

In the embodiment of Fig. 1 to 4 the dividing line 26 of the first side 16 is visible from radially outside, whereas the dividing line 27 of the second side 17 is hidden from the outside when viewed radially. According to 3 and 4 The dividing lines 26 and 27 of the two sides 16, 17, starting from the flow inlet-side edges to flow-outlet-side edges, run in each case from radially outside to radially inside.

In the region of the first side 16 of the outer shroud segment 10 and the opposite, second side 17 of the outer shroud segment 10 are seen in the direction along the respective parting line 26 and 27 viewed from radially outside surfaces 28 and 29 and the visible from radially outside surfaces 30th or 31 each with respect to the radial direction R inclined at an angle. In this case, the surfaces 28 and 29, which are concealed radially from the outside, are inclined by a first angle relative to the radial direction R and the surfaces 30 and 31, which are visible from the radially outside, are inclined by a second angle relative to the radial direction R. On the first side 16 and on the second side 17, preferably the first angle and the second angle are equal in magnitude, but have different signs. This is particularly advantageous in terms of manufacturing technology. In contrast to this, however, it is also possible for the first angle and the second angle to be different in magnitude on the first side 16 and on the second side 17, but in turn have different signs.

According to a development of the invention, both on the first side 16 of the outer shroud segment 10 and on the second side 17 of the outer shroud segment 10, the radially outwardly hidden surface 28 and 29 and the radially outwardly visible surface 30 and 31, respectively, an area ratio of 1 : 1 1, which means that on both sides 16 and 17 of the radially outer concealed surface 28 and 29 and the radially outwardly visible surface 30 and 31 are the same size. It should be noted that on the first side 16 and on the second side 17, these surfaces can also be different in size. Thus, it is possible that on the first side 16 and / or on the second side 17 of the radially outer concealed surface 28 and 29 and the radially outwardly visible surface 30 and 31, an area ratio of up to 1: 5 or up to 5: 1, in particular an area ratio of up to 1: 3 or of up to 3: 1. With the targeted enlargement or reduction of the area ratio between the radially outwardly hidden surface 28 and 29 and the radially outwardly visible surface 30 and 31 on the sides 16 and 17, it is possible to optimally adapt the desired coupling between outer shroud segments 10 adjacent blades , This can also be done via the already mentioned above angles, which include these surfaces with the respective dividing line 26 and 27, respectively.

How best Fig. 1 can be removed, as viewed from radially outside both on the first side 16 and on the second side 17 of the outer shroud segment 10 extending substantially in the axial direction A, radially outer edge 18 and 19 and which are substantially in the axial direction A extending, radially inner edge 20 and 21 congruent only at an axial position.

According to Fig. 1 to 4 are formed on the sides 16 and 17 of the outer shroud segment 10 surfaces 28 and 29 and the surfaces 30 and 31 respectively formed as a three-dimensional contoured, spatially radially curved. Essentially radially extending edges 32 bounding the outer shroud segment 10 together with the edges 18, 19, 20, 21, 22, 23, 24, and 25 are then curved.

In contrast, it is also possible that these surfaces 28, 29, 30 and 31 are designed as two-dimensionally contoured, flat surfaces. Essentially radially extending edges 32 bounding the outer shroud segment 10 together with the edges 18, 19, 20, 21, 22, 23, 24 and 25 are then straight.

As already stated, the embodiment differs from the Fig. 5 from the embodiment of Fig. 1 to 4 only in that the mounting direction M of the blades is not rectilinear but curved. With regard to the remaining details, the embodiment of the Fig. 5 with the embodiment of Fig. 1 to 4 match, so that reference is made to the above statements.

There are further modifications of the invention possible. Thus, it is possible that in addition the radially outer edges 18 and 19 and the radially inner edges 20 and 21 which extend substantially in the axial direction A and define the width of the outer shroud segment 10 in the circumferential direction U, on both opposite sides 16 and 17th as well as the dividing lines 26, 27 each have a curved contour or a curved, but without turning point course. Furthermore, it is possible that a rotor according to the invention not only has a coupling element designed as outer cover tape 10 but additionally also has a coupling element designed as an inner coupling element. In this case, then the outer shroud segments and inner coupling element segments are formed as described above. Furthermore, it is possible that a rotor according to the invention has no outer shroud segment but exclusively at least one coupling element segment embodied as an inner coupling element segment. Furthermore, it is possible for the parting line 26 of the first side 16 to be concealed from radially outside, whereas the parting line 27 of the second side 17 is visible from radially outside.

LIST OF REFERENCE NUMBERS

10, 10 ', 10 "

Coupling element segment / outer shroud segment

11

airfoil

12

Strömungseinrittskante

13

Flow edge ride

14

suction

15

pressure side

16

first page

17

second page

18

radially outer edge

19

radially outer edge

20

radially inner edge

21

radially inner edge

22

flow inlet side radially outer edge

23

flow outlet side radially outer edge

24

flow inlet side radially inner edge

25

flow outlet side radially inner edge

26

Building a proper division

27

Building a proper division

28

of radially outwardly hidden surface

29

of radially outwardly hidden surface

30

surface visible radially outwards

31

surface visible radially outwards

32

edge

Claims (15)

Rotor of a turbomachine, having a rotor body and with a plurality of blades, each blade having a blade root and an airfoil, each blade being attached via its blade root to the rotor base in a groove of the rotor body in a mounting direction defined by the blade roots, each blade in the region its blade has at least one coupling element segment, and wherein in the circumferential direction a width of the or each coupling element segment of each blade is defined by substantially axially extending edges, characterized in that the or each coupling element segment (10, 10 ', 10 ") of each Blade on a first side (16), in the circumferential direction, a coupling element segment of a first immediately adjacent blade connects, and on one of the first side (16) opposite the second side (17), in the circumferential direction seen a coupling element segment of a second immediately adjacent blade connects, is contoured such that on the first side (16) and on the second side (17) extending substantially in the axial direction radially outer edge (18, 19) and in the substantially axially extending radially inner edge (20, 21) of the respective coupling element segment in each case delimit two surfaces separated by a dividing line (26, 27), wherein on at least one circumferential position of the rotor between two immediately adjacent moving blades the directly adjacent sides (16, 17) of the coupling element segments (10 ', 10 ") formed separating lines (26, 27) of these immediately adjacent blades in approximately approximately parallel or rectified to the defined via the blade roots assembly direction of the blades on the rotor main body, whereas at each other circumferential position between two directly neighboring Lau the vanes formed on immediately adjacent sides of the coupling element segments (10, 10 ', 10 ") separating lines (26, 27) of these immediately adjacent blades are inclined to the mounting direction. Rotor according to claim 1, characterized in that at the or each circumferential position of the rotor, on which the dividing lines (26, 27) formed on the immediately adjacent blades in approximately approximately parallel or rectified to the mounting direction of the blades defined on the blade roots on the rotor body run, the dividing lines (26, 27) with the mounting direction an angle of not more than 10 °. Rotor according to claim 2, characterized in that at the or each circumferential position of the rotor, on which the dividing lines formed on the immediately adjacent blade (26, 27) approximately approximately parallel or rectified to the mounting direction of the blades on the rotor base body defined via the blade roots run, the dividing lines (26, 27) with the mounting direction an angle of no more than 5 °. Rotor according to one of claims 1 to 3, characterized in that the mounting direction of the rotor blades on the rotor body in the axial direction is inclined relative to the axial direction in a first orientation in the circumferential direction, wherein at the or each circumferential position of the rotor, to which at the immediately adjacent Blades formed dividing lines (26, 27) in approximately approximately parallel or rectified to the defined via the blade roots mounting direction of the blades on the rotor main body, the dividing lines (26, 27) are inclined in the same orientation as the mounting direction relative to the axial direction in the circumferential direction, whereas at the or each other circumferential position of the rotor between two immediately adjacent blades, the dividing lines (26, 27) are inclined circumferentially in a direction opposite to the first orientation, like the mounting direction relative to the axial direction. Rotor according to one of claims 1 to 4, characterized in that in the viewing direction from radially outside the or each coupling element segment (10, 10 ', 10 ") of each blade on the first side (16) is contoured such that the flow inlet side adjacent to a Flow inlet edge (12) of the respective blade extending in the axial direction extending radially outer edge (18) relative to the substantially axially extending radially inner edge (20) in the circumferential direction, whereas on this first side (16) facing away from a flow outlet side A flow outlet edge (13) of the respective blade which projects in a substantially axially extending radially inner edge (20) opposite to the substantially axially extending radially outer edge (18) in the circumferential direction, and in that the or each coupling element segment (10, 10 ', 10 ') of each blade on the second side (17) is contoured so that the flow outlet side adjacent to the flow outlet edge (13) of the respective blade the substantially axially extending radially outer edge (19) relative to the substantially axially extending radially inner edge (21) protrudes in the circumferential direction, whereas at this the second side (17) facing away from the flow inlet edge (12) of the respective blade substantially radially extending in the axial direction inner edge (21) relative to the substantially axially extending radially outer edge (19) projects in the circumferential direction. Rotor according to one of claims 1 to 5, characterized in that on the first side (16) and on the second side (17) each in the viewing direction of radially outwardly hidden surface (28, 29) and in each case one in the direction of radially outward visible surface (30, 31) is formed, wherein at the first side (16) of the radially outer concealed surface (28) flow inlet side and the radially outwardly visible surface (30) is positioned downstream of the flow, and wherein on the second side (17 ) the radially outwardly hidden surface (29) is positioned on the outlet side and the surface (31) visible from the radial outside is positioned on the flow inlet side. Rotor according to one of claims 1 to 6, characterized in that on the first side (16) and on the second side (17) of the respective coupling element segment, the separating lines (26, 27) which on the first side (16) and on the second side (17) separated from the radially outer surface (28, 29) and the radially outwardly visible surface (30, 31) separate from each other, is formed without a dot. Rotor according to one of claims 1 to 7, characterized in that on the first side (16) and on the second side (17) of the respective coupling element segment viewed in the direction along the parting lines (26, 27) the surface (28 , 29) relative to the radial direction by a first angle and the radially outwardly visible surface (30, 31) relative to the radial direction is inclined by a second angle. Rotor according to claim 8, characterized in that on the first side (16) and on the second side (17) of the respective Koppeleiementsegments the first angle and the second angle are equal in magnitude and have different signs or the first angle and the second angle in terms of magnitude are different in size and have different signs. Rotor according to one of claims 1 to 9, characterized in that on the first side (16) and on the second side (17) of the respective coupling element segment of the radially outwardly hidden surface (28, 29) and the radially outwardly visible surface (30 , 31) are the same size and accordingly have an area ratio of 1: 1. Rotor according to one of claims 1 to 9, characterized in that on the first side (16) and on the second side (17) of the respective coupling element segment of the radially outwardly hidden surface (28, 29) and the radially outwardly visible surface ( 30, 31) have different sizes and preferably have an area ratio of up to 1: 5 or of up to 5: 1, in particular an area ratio of up to 1: 3 or of up to 3: 1. Rotor according to one of claims 1 to 11, characterized in that on the first side (16) and on the second side (17) of the respective coupling element segment of the radially outwardly hidden surface (28, 29) and the radially outwardly visible surface ( 30, 31) are in each case two-dimensionally contoured, flat surfaces or three-dimensionally contoured, spatially curved surfaces. Rotor according to one of claims 1 to 12, characterized in that on the first side (16) and / or on the second side (17) of the respective Koppetelementsegments in the direction from radially outside the substantially axially extending radially outer edge (18 , 19) and the radially extending in the axial direction radially inner edge (20, 21) are congruent at only one axial position. Rotor according to one of claims 1 to 13, characterized in that each blade has in the region of its blade radially outward a formed as outer shroud segment coupling element segment. Rotor according to one of claims 1 to 14, characterized in that each blade has at least one coupling element segment designed as an inner coupling element segment in the region of its blade.

Images