EP3719258A1 - Rotor blade of a turbomachine - Google Patents

Abstract

A rotor blade (10) of a turbomachine, with a blade (11), which has a flow inlet edge (13), a flow outlet edge (14) and flow guide surfaces (15, 16) for a process medium, with a blade root (12) for fastening the rotor blade to a Hub body, wherein the blade root (12) is formed like a fir tree with at least two projections (17) spaced apart from one another as seen in the radial direction, with an inner shroud (18) which, when seen in the radial direction, is arranged between the blade (11) and the blade root (12), with a cooling channel (20) integrated into the blade (11) and the blade root (12) for a cooling medium, an inlet of the cooling channel (20) being formed radially on the inside at the blade root (12). The inlet of the cooling channel (20) is formed from a first inlet channel section (22) and a second inlet channel section (23), which is arranged behind the first inlet channel section (22) in the axial direction of the blade root (12) and between which a material web (24) extends . The first inlet channel section (22) and the second inlet channel section (24) merge into a union channel section (25) which, viewed in the radial direction, is arranged radially outside of the uppermost projection (17) of the blade root (12) and radially inside of the inner shroud (18). Fig. 1

Description

The invention relates to a rotor blade of a turbomachine.

Fluid flow machines, such as turbines or compressors, have stator-side assemblies and rotor-side assemblies. The rotor-side assemblies of a turbo machine include what is known as the turbo machine rotor, which has a hub body and rotor blades that extend radially outward from the hub body. A rotor blade of a turbomachine has a flow-guiding blade as well as a blade root via which the rotor blade can be fastened in the hub body of the turbomachine. The blade of the turbomachine has a flow inlet edge, a flow outlet edge and flow guide surfaces for a process medium that extend between the flow inlet edge and the flow outlet edge and are also referred to as suction side and pressure side. The blade root, via which the rotor blade can be fastened in the hub body of the turbomachine, is typically configured like a fir tree with at least two projections spaced apart from one another as seen in the radial direction of the rotor blade. A moving blade also has a so-called inner shroud, which is arranged between the airfoil and the blade root, as seen in the radial direction of the moving blade. An outer shroud can optionally adjoin the airfoil radially on the outside. In particular in the area of turbines, in which a hot process medium flows over the turbo machine, blades are used, in which a cooling channel is integrated. The cooling channel extends over both the blade root and the blade. An inlet of the cooling channel is formed radially on the inside at the blade root. An exit of the cooling channel can be formed radially on the outside on the blade or on the radially outer outer shroud or at another point.

Although already cooled rotor blades with a cooling channel which is integrated into the rotor blade are known in principle, there is a need to further improve the cooling of a rotor blade, while at the same time the rotor blade has high strength.

Proceeding from this, the present invention is based on the object of creating a novel rotor blade of a turbomachine which, despite the cooling channel, has high strength.

This object is achieved by a rotor blade according to claim 1.

According to the invention, the inlet of the cooling channel is formed from a first inlet channel section and a second inlet channel section, which is arranged behind the first inlet channel section when viewed in the axial direction of the blade root and between which a material web extends. The first inlet channel section of the cooling channel and the second inlet channel section of the cooling channel merge into a merging channel section of the cooling channel which, viewed in the radial direction, is arranged radially outside or radially above the uppermost or radially outermost projection of the blade root and radially inside or radially below the inner shroud. This is used for effective cooling of the rotor blade while at the same time providing the rotor blade with high strength.

The first inlet channel section and the second inlet channel section preferably run from radially inside to radially outside in a straight line in the radial direction. In that region of the blade root in which the first inlet channel section and the second inlet channel section run in a straight line in the radial direction, an axial thickness of the material web is constant. This is used to effectively cool the rotor blade while at the same time providing the rotor blade with high strength. The first inlet channel section and the second inlet channel section then each run bent or curved in the direction of the merging channel section, specifically in the direction of an upstream or axially front end of the blade root with respect to the process medium flow. In that region of the blade root in which the first inlet channel section and the second inlet channel section each extend in a curved or curved manner, an axial thickness of the material web preferably decreases in the direction of the union channel section. This also serves to effectively cool the rotor blade while at the same time providing the rotor blade with high strength.

According to an advantageous development, the first inlet channel section is curved in the direction of the upstream or axially front end of the blade root with a first radius of curvature. The second inlet channel section is curved with a second radius of curvature in the direction of the upstream or axially front end of the blade root. The first radius of curvature is at least as large, preferably larger, than the second radius of curvature. These features also serve to ensure effective cooling while at the same time providing the rotor blade with high strength.

According to an advantageous further development, the cooling channel initially extends radially outwards in the direction of a radially outer deflecting channel section after the union channel section. Subsequent to the radially outer deflection channel section, the cooling channel extends radially inward in the direction of a radially inner deflection channel section. Following the radially inner deflection channel section, the cooling channel extends radially outward in the direction of a cooling channel outlet. The radially inner deflection channel section is arranged in the radial direction above or radially outside the uppermost or radially outermost projection of the blade root and below or radially inside the inner shroud. This also serves to effectively cool the rotor blade while maintaining its high strength.

According to an advantageous development, the first inlet channel section and the second inlet channel section have the same flow cross-sections. This ensures effective cooling of the rotor blade.

Fig. 1

eine Seitenansicht einer erfindungsgemäßen Laufschaufel einer Strömungsmaschine;

Fig. 2

eine perspektivische Vorderansicht der erfindungsgemäßen Laufschaufel;

Fig. 3

ein Detail der erfindungsgemäßen Laufschaufel im Bereich eines Schaufelfußes;

Fig. 4

Konturen eines Kühlkanals der erfindungsgemäßen Laufschaufel;

Fig. 5

den Ausschnitt V der Fig. 4;

Fig. 6

den Ausschnitt V der Fig. 4 mit geometrischen Größen;

Fig. 7

den Ausschnitt V der Fig. 4 mit weiteren geometrischen Größen.

Preferred developments of the invention emerge from the subclaims and the following description. Embodiments of the invention are explained in more detail with reference to the drawing, without being restricted thereto. It shows:

Fig. 1

a side view of a rotor blade according to the invention of a turbomachine;

Fig. 2

a perspective front view of the blade according to the invention;

Fig. 3

a detail of the rotor blade according to the invention in the area of a blade root;

Fig. 4

Contours of a cooling channel of the rotor blade according to the invention;

Fig. 5

the section V of the Fig. 4 ;

Fig. 6

the section V of the Fig. 4 with geometric sizes;

Fig. 7

the section V of the Fig. 4 with further geometric sizes.

Figs. 1 and 2 show views of a rotor blade 10, wherein the rotor blade 10 comprises a flow-guiding blade 11 and a blade root 12. The flow-guiding blade 11 serves to guide the flow of a process medium, in particular process gas, which flows through the turbomachine, the blade 11 having a flow inlet edge 13 for the process medium, a flow outlet edge 14 for the process medium and flow guide surfaces 15 extending between the flow inlet edge 13 and the flow outlet edge 14 , 16 for the process medium. The flow guide surfaces 15, 16 form a suction side and a pressure side.

The blade root 12 is used to fasten the rotor blade 10 in a hub body, not shown, of the turbomachine. The blade root 12 is configured like a fir tree with at least two projections 17 spaced apart from one another as seen in the radial direction of the rotor blade 10. In the exemplary embodiment shown, three such projections 17 are spaced apart from one another in the radial direction of the rotor blade 10. The fir tree profile of the blade root 12 tapers between adjacent projections 17. One projection 17 and the tapering section of the fir tree profile arranged directly above the respective projection 17 each define a so-called tooth of the fir tree profile.

The rotor blade 10 also has an inner shroud 18 which, viewed in the radial direction of the rotor blade 10, is arranged between the blade blade 11 and the blade root 12 of the rotor blade 10. The inner shroud 18 delimits a flow guide channel for the process medium radially on the inside. In the exemplary embodiment shown, the rotor blade 10 also has an outer shroud 19. The outer shroud 19 delimits the flow guide channel for the process medium radially on the outside.

A cooling channel 20 for a cooling medium, in particular cooling air, is integrated into the rotor blade 10. In Fig. 1 contours of the cooling channel 20 are shown in dashed lines. Also in Fig. 3 contours of the cooling channel 20 are shown in sections in dashed lines. Fig. 4, 5 , 6 and 7 show only the contours of the cooling channel 20 without the actual rotor blade 10.

The cooling channel 20 has an inlet or cooling channel inlet 21 which is formed radially on the inside on the blade root 12. The cooling channel 20 also has an outlet or cooling channel outlet 31, which is formed in particular radially on the outside on the blade 11 or on the outer shroud 19. The cooling channel outlet 31 can also be psotionized at another point.

Fig. 3 , 5 , 6 and 7 show details of the inlet or cooling channel inlet 21 of the cooling channel 20.

The inlet or cooling channel inlet 21 of the cooling channel 20 comprises a first inlet channel section 22 and a second inlet channel section 23. As best Fig. 1 can be removed, the first inlet channel section 22, viewed in the axial direction, is positioned at the front in relation to the flow of the process medium, i.e. closer to an end of the blade root 12 which is upstream or axially forward in relation to the process medium flow than the second inlet channel section 23.

The second inlet channel section 23 is arranged behind the first inlet channel section 22 as seen in the axial direction of the blade root 12.

As already stated, the blade root 12 is not used to guide the process medium but only to fasten or assemble the rotor blade 10 on the hub body. Nevertheless, the blade root 12 has two opposite axial ends, namely an upstream or axially front end in relation to the process medium flow and an end which is downstream or axially rear in relation to the process medium flow.

The first inlet channel section 22 is arranged between the upstream or axially front end of the blade root 12 and the second inlet channel section 23.

The second inlet channel section 23 is arranged between the first inlet channel section 22 and the downstream or axially rear end of the blade root 12.

A material web 24 extends between the two inlet channel sections 22 and 23, which are spaced apart from one another in the axial direction of the blade root 12. This material web 24 stiffens the rotor blade 10 in the area of its blade root 12.

The first inlet channel section 22 and the second inlet channel section 23 of the cooling channel 20 merge into a connecting channel section 25.

This connecting channel section 25 is arranged or formed above or radially outside of the uppermost or radially outermost projection 17 and below or radially inside of the inner shroud 18, as seen in the radial direction of the rotor blade 10.

From this it follows that the material web 24 extends from radially inside to radially outside into a section of the blade root 12 which is arranged above or radially outside of the radially outermost and thus uppermost projection 17 of the blade root 12, whereby the strength of the rotor blade 10 in the Area of the blade root 12 can be adjusted particularly advantageously. The material web 24 preferably extends into the region of the narrowest cross section of the radially outermost and thus uppermost tooth of the fir tree profile of the blade root 12.

The first inlet channel section 22 defines a first flow inlet opening radially on the inside at the blade root 12 and the second inlet channel section 23 defines a second flow inlet opening radially on the inside at the blade root 12. These, like the inlet channel sections 22, 23 themselves, are positioned one behind the other as seen in the axial direction of the blade root 12 and are spaced apart from one another via the material web 24.

The first flow inlet opening and thus the first inlet channel section 22 has a defined axial distance .DELTA.x from the upstream or axially front end of the blade root 12 in relation to the process medium flow. The defined axial distance Δx between the first inlet channel section 22 and thus the first flow inlet opening and the upstream or axially front end of the blade root 12 is preferably between 10% and 30%, in particular between 15% and 25%, of the axial length L of the blade root 12.

How best Fig. 4, 5 , 6 and 7 can be removed, the first inlet channel section 22 and the second inlet channel section 23, starting from their respective flow inlet opening, that is, starting from radially inside, initially run in a straight line in the radial direction radially outwards. In this area, in which the two inlet channel sections 22, 23 run in a straight line in the radial direction, the material web 24 has a constant thickness in the axial direction. The axial distance Δx defined above between the first inlet channel section 22 and the upstream end of the blade root 12 relates to the area of the first inlet channel section 22 that extends in a straight line radially outward in the radial direction. Subsequent to that area in which the two inlet channel sections 22, 23 in the radial direction run in a straight line, the two inlet channel sections 22, 23 run bent or curved in the direction of the connecting channel section 25. The distance Δx defined above changes in the area of this curvature. The curvature of the inlet channel sections 22, 23 between the rectilinear areas thereof and the connecting channel section 25 is directed in the direction of the upstream or axially front end of the blade root 12 or in the direction of the flow inlet edge 13 of the rotor blade 11. In this area, in which the two inlet channel sections 22, 23 separated from one another by the material web 24 run bent or curved, the axial thickness of the material web 24 preferably decreases in the direction of the union channel section 25. The material web 24 tapers in this area. Alternatively, the axial thickness of the material web 24 can also be constant in this area.

Subsequent to the connecting channel section 25, the cooling channel 20 extends in the illustrated embodiment with a further section 26 first radially outwards in the direction of a radially outer deflection channel section 27, then after the radially outer deflection channel section 27 with a further section 28 radially inwards in the direction of a inner deflecting channel section 29 and then to this radially inner deflecting channel section 29 with a further section 30 radially outward in the direction of the cooling channel outlet 31. The sections 26, 28 and 30 of the cooling channel 20 extend inside the blade 11. There are also other courses of the Cooling channel 20 downstream of the connecting channel section 25 possible.

The radially inner deflection channel section 29 is arranged above or radially outside of the uppermost or radially outermost projection 17 of the blade root 12 and below or radially inside of the inner shroud 18, seen in the radial direction, in the axial direction opposite the inlet channel sections 22, 23 axially rearward in the direction of the downstream or axially rear end of the blade root 12 offset.

The upper or radially outer deflection channel section 27 can extend into the region of the outer shroud 19.

In the case of the rotor blade 10 according to the invention, cooling medium accordingly flows into the cooling channel 20 via the flow inlet openings of the inlet channel sections 22, 23, this coolant flowing through the two inlet channel sections 22, 23 being combined in the area of the merging channel section 25. This takes place in the area of the blade root 12. Subsequently, the cooling medium is guided via the channel sections 26, 27, 28, 29 and 30 in the direction of the cooling channel outlet 31.

The duct sections 26, 28 and 30 extending in the radial direction extend over the radial extent of the blade 11. Between the duct sections 26, 28 and between the duct sections 28 and 30, a flow deflection takes place via the deflecting duct sections 27 and 29.

Figures 6 and 7 show geometric parameters of the flow channel 20 in the area of the cooling channel inlet 21. So can Fig. 6 it can be seen that the first inlet channel section 22 is curved with a first radius of curvature R1 and the second inlet channel section 23 is curved with a second radius of curvature R2 in the direction of the upstream axial end of the blade root 12. The first radius of curvature R1 is at least as large as the second radius of curvature R2, R1 is preferably greater than R2.

Fig. 7 visualize the flow cross-sections of the inlet channel sections 22 and 23. Fig. 7 it can be seen that the two inlet channel sections 22 and 23 have the same flow cross-sections A, specifically over their entire radial extent up to the union channel section 25.

In the case of the rotor blade 10 according to the invention, cooling medium can enter the cooling duct 20 in the radial direction in the region of the inlet duct sections 22, 23, whereby an effective entry of the cooling medium into the cooling duct 20 is possible. Viewed in the axial direction, the inlet channel sections 22, 23, which are spaced apart from one another in the axial direction, are at a defined axial distance from the upstream end of the blade root 12. Furthermore, the inlet channel sections 22, 23 are spaced apart from one another in the axial direction by the material web 24. This serves to provide a high strength of the rotor blade 10 in the area of the blade root 12. The web 24 extends in the radial direction above or radially outward of the uppermost or radially outermost projection 17 of the fir tree-like blade root 12. This ensures optimal strength in the area of the blade root 12.

In the radial area of the blade root 12, in which the two inlet channel sections 22 and 23 merge into the merging duct section 25, the radially inner deflecting duct section 29 is also arranged axially spaced from the merging duct section 25. This radially inner deflection channel section 29 extends into the blade root 12, but ends at a distance from the radially outermost projection 17 of the fir tree-like blade root 12 radially outside or radially above the web 24. The rotor blade 10 according to the invention allows optimal cooling with high strength. It is used in particular in gas turbines.

List of reference symbols

10

Blade

11

Shovel blade

12

Blade root

13

Flow leading edge

14th

Flow trailing edge

15th

Flow guide surface

16

Flow guide surface

17th

head Start

18th

Inner shroud

19th

Outer shroud

20th

Cooling duct

21st

Cooling duct inlet

22nd

first inlet channel section

23

second inlet channel section

24

Material bar

25th

Union channel section

26th

Channel section

27

Deflection channel section

28

Channel section

29

Deflection channel section

30th

Channel section

31

Cooling duct outlet

Claims (13)

Rotor blade (10) of a turbomachine, with a blade (11) which has a flow inlet edge (13), a flow outlet edge (14) and flow guide surfaces (15, 16) for a process medium that extend between the flow inlet edge (13) and the flow outlet edge (14), with a blade root (12) for fastening the rotor blade to a hub body of the turbomachine, the blade root (12) being designed like a fir tree with at least two projections (17) spaced apart from one another as seen in the radial direction, with an inner shroud (18) which, viewed in the radial direction, is arranged between the blade (11) and the blade root (12), with a cooling channel (20) integrated into the blade (11) and the blade root (12) for a cooling medium, an inlet (21) of the cooling channel (20) being formed radially inward on the blade root (12), characterized in that the inlet of the cooling channel (20) is formed from a first inlet channel section (22) and a second inlet channel section (23), which is arranged behind the first inlet channel section (22) in the axial direction of the blade root (12) and between which a material web (24) extends , the first inlet channel section (22) of the cooling channel (20) and the second inlet channel section (23) of the cooling channel (20) merge into a union channel section (25) of the cooling channel (20) which, viewed in the radial direction, is radially outward or radially above the uppermost or radially outermost Projection (17) of the blade root (12) and radially inwardly or radially below the inner shroud (18) is arranged. Rotor blade according to claim 1, characterized in that
the first inlet channel section (22) of the cooling channel (20) defines a first flow inlet opening and the second inlet channel section (23) of the cooling channel (20) defines a second flow inlet opening which is positioned behind the first flow inlet opening as seen in the axial direction of the blade root (12). Rotor blade according to Claim 1 or 2, characterized in that
the first inlet channel section (22) and thus the first flow inlet opening has a defined axial distance (Δx) from an upstream or axially front end of the blade root (12) in relation to the process medium flow. Rotor blade according to claim 3, characterized in that
the defined axial distance (Δx) between the first inlet channel section (22) and thus the first flow inlet opening and the upstream or axially front end of the blade root (12) is between 10% and 30% of the axial length (L) of the blade root (12). Rotating blade according to one of Claims 1 to 4, characterized in that the first inlet channel section (22) of the cooling channel (20) and the second inlet channel section (23) of the cooling channel (20) initially run in a straight line in the radial direction from radially inside to radially outside, the first inlet channel section (22) and the second inlet channel section (23) then extend in the direction of the union channel section (25) of the cooling channel (20) in each case bent or curved, namely in the direction of an upstream or axially front end of the process medium flow Blade root (12). Rotating blade according to claim 5, characterized in that
in the area in which the first inlet channel section (22) and the second inlet channel section (23) run in a straight line in the radial direction, an axial thickness of the material web (24) is constant. Rotor blade according to claim 5 or 6, characterized in that,
in the region in which the first inlet channel section (22) and the second inlet channel section (23) are each bent or curved, an axial thickness of the material web (24) decreases in the direction of the union channel section (25). Rotor blade according to claim 5 or 6, characterized in that,
in the region in which the first inlet channel section (22) and the second inlet channel section (23) each extend in a bent or curved manner, an axial thickness of the material web (24) is constant. Rotating blade according to one of Claims 5 to 8, characterized in that the first inlet channel section (22) is curved in the direction of the upstream or axially front end of the blade root (12) with a first radius of curvature (R1), the second inlet channel section (23) is curved in the direction of the upstream or axially front end of the blade root (12) with a second radius of curvature (R2), the first radius of curvature (R1) is at least as large, preferably greater than the second radius of curvature (R2). Blade according to one of Claims 1 to 9, characterized in that
the cooling channel (20) then extends radially outwards to the union channel section (25). Rotating blade according to one of Claims 1 to 10, characterized in that the cooling channel (20) then extends radially outwardly towards a radially outer deflecting channel section (27) following the union channel section (25), the cooling channel (20) then extends radially inward in the direction of a radially inner deflecting channel section (29), the cooling channel then extends radially outward in the direction of a cooling channel outlet (31). Rotating blade according to claim 11, characterized in that the radially inner deflection channel section (27) is arranged in the radial direction radially outside or radially above the uppermost or radially outermost projection (17) of the blade root (12) and radially inside or radially below the inner shroud (18) . Rotating blade according to one of Claims 1 to 12, characterized in that the first inlet channel section (22) of the cooling channel (20) and the second inlet channel section (23) of the cooling channel (20) have the same flow cross-sections (A).

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