阅读说明：本技术 动叶以及具备该动叶的轴流旋转机械 (Rotor blade and axial flow rotating machine provided with same ) 是由 石田智广 贯野敏史 黑崎光 伊藤荣作 于 2020-02-12 设计创作，主要内容包括：本发明提供一种动叶以及具备该动叶的轴流旋转机械。动叶具备呈翼形的叶片体和形成于叶片体的端部的护罩(57)。护罩具有护罩盖和从护罩盖向径向外侧突出、在具有周向的方向分量的方向上延伸的密封翅片。密封翅片的顶端在周向上延伸,密封翅片的基端在具有周向的方向分量的方向上延伸。密封翅片的周向上的一部分形成偏移部。偏移部的基端的轴线方向上的中心位置相对于偏移部的顶端的轴线方向上的中心位置在轴线方向上不同。(The invention provides a rotor blade and an axial flow rotary machine provided with the same. The rotor blade is provided with a blade body having an airfoil shape and a shroud (57) formed at an end of the blade body. The shroud has a shroud cover and a sealing fin projecting radially outward from the shroud cover and extending in a direction having a circumferential direction component. The tip end of the sealing fin extends in the circumferential direction, and the base end of the sealing fin extends in a direction having a direction component of the circumferential direction. A part of the sealing fin in the circumferential direction forms an offset portion. The center position in the axial direction of the base end of the offset portion differs in the axial direction with respect to the center position in the axial direction of the tip end of the offset portion.)

1. A rotor blade mounted on a rotor shaft centered on an axis,

the rotor blade includes:

a blade body extending in a radial direction with respect to the axis, the blade body having an airfoil shape in a cross-sectional shape orthogonal to the radial direction; and

a shroud formed at an end portion of the blade body radially outward with respect to the axis,

the shield has: a shroud cover that extends from the positive pressure surface and the negative pressure surface of the blade body in a direction having a circumferential direction component with respect to the axis; and a sealing fin projecting from the shroud cover to the radially outer side and extending in a direction having the circumferential direction component,

the shroud cover has a gas passage face facing a radially inner side with respect to the axis and an anti-gas passage face facing the radially outer side,

the sealing fin has: a base end having a thickness in an axial direction in which the axis extends, and intersecting the counter gas passage surface; and a tip end having a thickness in the axial direction, located most radially outward,

the tip end extending in the circumferential direction, the base end extending in a direction having a directional component of the circumferential direction,

a part of the sealing fin in the circumferential direction forms an offset portion, a center position in the axial direction of the base end of the offset portion being different in the axial direction with respect to a center position in the axial direction of the tip end of the offset portion.

2. The bucket according to claim 1, wherein,

the offset portion of the seal fin has an inclined portion that tends toward the axial direction as it tends toward the radially inner side.

3. The bucket according to claim 1 or 2, wherein,

the sealing fin has: a front surface facing an axially upstream side, which is a side where a leading edge exists with respect to a trailing edge of the blade body in the axial direction; and a rear surface facing an axis downstream side of a side opposite to the axis upstream side in the axis direction,

the tip has: a forward tip that is the end of the forward surface that is furthest to the radially outer side; and a rear tip end which is the most radially outward end of the rear surface,

the base end has: a front base end intersecting the counter-gas passage surface in the front surface; and a rear base end intersecting with the counter gas passage surface in the rear surface,

the leading base end of the offset portion of the sealing fin is offset to one of the axis upstream side and the axis downstream side with respect to the leading tip end of the offset portion,

the rear base end of the offset portion of the sealing fin is also offset to the one side with respect to the rear tip end of the offset portion.

4. The bucket according to claim 1 or 2, wherein,

the sealing fin has: a front surface facing an axially upstream side, which is a side where a leading edge exists with respect to a trailing edge of the blade body in the axial direction; and a rear surface facing an axis downstream side of a side opposite to the axis upstream side in the axis direction,

the tip has: a forward tip that is the end of the forward surface that is furthest to the radially outer side; and a rear tip end which is the end of the rear surface that is most outward in the radial direction,

the base end has: a front base end intersecting the counter-gas passage surface in the front surface; and a rear base end intersecting with the counter gas passage surface in the rear surface,

the leading base end of the offset portion of the sealing fin is offset to one of the axis upstream side and the axis downstream side with respect to the leading tip end of the offset portion,

the rear base end of the offset portion of the sealing fin is offset toward the other of the axis upstream side and the axis downstream side with respect to the rear tip end of the offset portion.

5. The bucket according to claim 1, wherein,

the thickness of the tip end in the axial direction and the thickness of the base end in the axial direction are thicker than the thickness of an intermediate portion between the tip end and the base end of the sealing fin in the axial direction.

6. The bucket according to claim 1, wherein,

the sealing fin extends from a first outer edge, which is one portion of the outer edge of the counter-gas passing face, across the mean camber line of the blade body to a second outer edge, which is another portion of the outer edge of the counter-gas passing face,

the sealing fin has: a first end portion protruding from the first outer edge to the radially outer side; and a second end portion protruding from the second outer edge toward the radially outer side.

7. The bucket according to claim 6, wherein,

at the first end portion and the second end portion of the sealing fin, a center position in the axial direction of the base end coincides with a center position in the axial direction of the tip end.

8. The bucket according to claim 6, wherein,

the offset portion has a positive pressure side offset portion and a negative pressure side offset portion,

the positive pressure side offset portion is located on a positive pressure side where the positive pressure surface exists with the mean camber line as a reference, the negative pressure side offset portion is located on a negative pressure side where the negative pressure surface exists with the mean camber line as a reference,

a center position in the axial direction of the base end of the positive pressure side offset portion is offset to an axial upstream side with respect to a center position in the axial direction of the tip end of the positive pressure side offset portion,

a center position in the axial direction of the base end of the negative pressure side offset portion is offset to an axial downstream side with respect to a center position in the axial direction of the tip end of the negative pressure side offset portion,

the axial upstream side is a side on which a leading edge exists with respect to a trailing edge of the blade body in the axial direction, and the axial downstream side is a side opposite to the axial upstream side in the axial direction.

9. The bucket according to claim 6, wherein,

the gas passage surface has a transition surface extending gradually to the radially outer side as going toward directions away from the positive pressure surface and the negative pressure surface of the blade body, respectively, in a cross section orthogonal to the camber line,

the counter-gas passage face has a concave surface expanding in the cross section in a manner recessed toward the radially inner side along the transition face,

with respect to the radial height of the sealing fin, the height of an intermediate portion of the sealing fin between the first end portion and the second end portion is higher than the height of the first end portion and the height of the second end portion.

10. The bucket according to claim 1, wherein,

the gas passage surface has a transition surface extending gradually to the radially outer side as going toward directions away from the positive pressure surface and the negative pressure surface of the blade body, respectively, in a cross section orthogonal to a camber line of the blade body,

the counter-gas passage face has a concave surface expanding in the cross section in a manner recessed toward the radially inner side along the transition face.

11. The bucket according to claim 9 or 10, wherein,

said concave surface expanding bilaterally in said cross-section with reference to said mean camber line,

in the cross section, a surface on a positive pressure side of the concave surface with respect to the mean camber line and on which the positive pressure surface exists tends toward the radially inner side as it goes toward a negative pressure side of the concave surface with respect to the mean camber line and on which the negative pressure surface exists, and in the concave surface, a surface on the negative pressure side with respect to the mean camber line tends toward the radially inner side as it goes toward the positive pressure side.

12. An axial flow rotating machine, comprising:

a plurality of buckets according to any one of claims 1 to 11;

the rotor shaft; and

a shell body, a plurality of first connecting rods and a plurality of second connecting rods,

a plurality of the blades arranged in the circumferential direction and attached to the rotor shaft,

the casing covers an outer circumferential side of the rotor shaft and the plurality of blades.

Technical Field

The present invention relates to a rotor blade and an axial flow rotary machine provided with the same.

Background

A gas turbine, which is one type of axial-flow rotary machine, includes a rotor that rotates about an axis and a casing that covers the rotor. The rotor has a rotor shaft and a plurality of buckets mounted to the rotor shaft.

For example, a rotor blade described in the following patent documents includes a blade body having an airfoil shape, a shroud, and a platform. The blade body extends in a radial direction with respect to the axis. Thereby, the blade height direction of the blade body is a radial direction. The shroud is provided at the radially outer end of the blade body. The platform is provided at an end portion of the blade body on the radially inner side. Both the shroud and the platform expand in a direction that is nearly perpendicular to the radial direction. The shroud has a shroud body (or shroud cover) and a sealing fin. The shroud body has a radially outwardly facing counter-gas passing face and a radially inwardly facing gas passing face. The sealing fins project from the shroud body counter-gas through the radially outer facing surface D, extending in a circumferential direction relative to the axis.

Patent document 1: japanese patent laid-open No. 2008-038910

Problems to be solved by the invention

As described above, the shroud is provided at the radially outer end of the blade body. Thus, the increased weight of the shroud may result in increased centrifugal loads experienced by the blade body. Therefore, it is preferable to make the shroud lightweight and reduce the centrifugal load applied to the blade body.

Disclosure of Invention

Accordingly, an object of the present invention is to provide a technique capable of improving the durability of a shroud cover while suppressing an increase in the weight of the shroud.

Means for solving the problems

A rotor blade according to an aspect of the present invention for achieving the above object is a rotor blade attached to a rotor shaft having an axis as a center, and includes: a blade body extending in a radial direction with respect to the axis, the blade body having an airfoil shape in a cross-sectional shape orthogonal to the radial direction; and a shroud formed at a radially outer end portion with respect to the axis in the blade body. The shield has: a shroud cover that extends from a positive pressure surface and a negative pressure surface of the blade body in directions having circumferential direction components with respect to the axis; and a sealing fin protruding from the shroud cover to the radially outer side and extending in a direction having the circumferential direction component. The shroud cover has a gas passage face facing a radially inner side with respect to the axis and an anti-gas passage face facing the radially outer side. The sealing fin has: a base end having a thickness in an axial direction in which the axis extends, and intersecting the counter gas passage surface; and a tip end having a thickness in the axial direction, located most radially outward of the radial direction. The tip end extends in the circumferential direction, and the base end extends in a direction having a directional component of the circumferential direction. A portion of the sealing fin in the circumferential direction forms an offset. A center position in the axial direction of the base end of the offset portion is different in the axial direction with respect to a center position in the axial direction of the tip end of the offset portion.

A large moment acting radially outward may act on a part of the shroud cover due to the influence of a centrifugal force generated by the rotation of the rotor shaft, the influence from another rotor blade that is fitted in the circumferential direction, and the like. In this case, the one portion tends to deform radially outward relative to the other portion. As a method of suppressing the deformation, a method of increasing the thickness of the shroud cover or a method of increasing the thickness of the seal fin from the base end to the tip end may be considered.

In this aspect, the base end of the offset portion of the seal fin is located in the vicinity of the portion of the shroud cover on which a large moment acts radially outward, whereby the portion of the shroud cover on which a large moment acts radially outward can be suppressed from being deformed relative to other portions. In this aspect, instead of increasing the thickness of the shroud cover or increasing the thickness between the base end and the tip end of the seal fin, the base end of the seal fin is offset in the axial direction from the tip end, and the base end is positioned in the vicinity of a portion where a large moment acts radially outward. Thus, in this aspect, the weight increase of the shroud can be suppressed, and the deformation of the shroud cover can be suppressed.

In the rotor blade according to the above aspect, the offset portion of the seal fin may have an inclined portion that is inclined in the axial direction as it goes to the radially inner side.

In the bucket according to any one of the above aspects, the sealing fin may include: a front surface facing an axially upstream side, which is a side where a leading edge exists with respect to a trailing edge of the blade body in the axial direction; and a rear surface facing an axis downstream side which is an opposite side to the axis upstream side in the axis direction. The tip has: a forward tip that is the end of the forward surface that is furthest to the radially outer side; and a rear tip that is the most radially outward end of the rear surface. The base end has: a front base end intersecting the counter-gas passage surface in the front surface; and a rear base end intersecting the counter gas passage surface in the rear surface. In this case, the front base end of the offset portion of the sealing fin is offset to one of the axis upstream side and the axis downstream side with respect to the front tip end of the offset portion, and the rear base end of the offset portion of the sealing fin is also offset to the one side with respect to the rear tip end of the offset portion.

In this aspect, since the thickness of the base end of the offset portion in the axial direction can be suppressed, an increase in weight of the shield can be suppressed.

In the bucket according to any one of the above aspects, the sealing fin may include: a front surface facing an axially upstream side, which is a side where a leading edge exists with respect to a trailing edge of the blade body in the axial direction; and a rear surface facing an axis downstream side which is an opposite side to the axis upstream side in the axis direction. The tip has: a forward tip that is the end of the forward surface that is furthest to the radially outer side; and a rear tip end that is an end of the rear surface that is most outward in the radial direction. The base end has: a front base end intersecting the counter-gas passage surface in the front surface; and a rear base end intersecting the counter gas passage surface in the rear surface. In this case, the front base end of the offset portion of the sealing fin is offset to one of the axis upstream side and the axis downstream side with respect to the front tip of the offset portion, and the rear base end of the offset portion of the sealing fin is offset to the other of the axis upstream side and the axis downstream side with respect to the rear tip of the offset portion.

In this aspect, the stress generated at the base end can be relaxed, and the deformation of the shroud cover can be further suppressed.

In the rotor blade according to any one of the above aspects, a thickness of the tip end in the axial direction and a thickness of the base end in the axial direction may be greater than a thickness of an intermediate portion between the tip end and the base end of the seal fin in the axial direction.

In the bucket according to any one of the above aspects, the sealing fin may extend from a first outer edge, which is one portion of the outer edge of the counter gas passage surface, to a second outer edge, which is another portion of the outer edge of the counter gas passage surface, across a camber line of the blade body. In this case, the sealing fin has: a first end portion protruding from the first outer edge to the radially outer side; and a second end portion protruding from the second outer edge toward the radially outer side.

In the bucket according to the above aspect in which the sealing fin has the first end portion and the second end portion, a center position of the base end in the axial direction may coincide with a center position of the tip end in the axial direction at the first end portion and the second end portion of the sealing fin.

In the rotor blade according to any one of the above aspects in which the sealing fin has the first end portion and the second end portion, the offset portion may have a positive pressure-side offset portion and a negative pressure-side offset portion. In this case, the positive pressure side offset portion is located on the positive pressure side where the positive pressure surface exists with respect to the camber line. The negative pressure side offset portion is located on the negative pressure side where the negative pressure surface exists with respect to the mean camber line. The center position in the axial direction of the base end of the positive pressure side offset portion is offset to the upstream side of the axial line with respect to the center position in the axial direction of the tip end of the positive pressure side offset portion. A center position in the axial direction of the base end of the negative pressure side offset portion is offset to an axial downstream side with respect to a center position in the axial direction of the tip end of the negative pressure side offset portion. The axial upstream side is a side on which a leading edge exists with respect to a trailing edge of the blade body in the axial direction. The axis downstream side is a side opposite to the axis upstream side in the axis direction.

At the shroud cover, the rim on the rotationally leading side in the circumferential direction and the rim on the rotationally trailing side in the circumferential direction are in contact with the other shroud covers adjoining in the circumferential direction. The edge of the shroud cover on the front side of rotation receives a load directed radially outward by centrifugal force. The distance between the portion of the edge on the rotation front side on the axis upstream side of the sealing fin and the camber line is larger than the distance between the portion of the edge on the rotation front side on the axis downstream side of the sealing fin and the camber line. Therefore, the moment based on the mean camber line received by the portion of the edge on the rotation front side on the axis upstream side of the sealing fin is larger than the moment based on the mean camber line received by the portion of the edge on the rotation front side on the axis downstream side of the sealing fin. Therefore, a large moment acts radially outward on the portion of the edge on the rotation front side on the axial upstream side of the seal fin.

Further, the edge of the shroud cover on the rotation rear side is also subjected to a load directed radially outward by a centrifugal force. The distance between the portion of the edge on the rotation rear side on the axis downstream side of the sealing fin and the camber line is larger than the distance between the portion of the edge on the rotation rear side on the axis upstream side of the sealing fin and the camber line. Therefore, the moment based on the mean camber line received by the portion of the edge on the rotation rear side on the axis downstream side of the sealing fin is larger than the moment based on the mean camber line received by the portion of the edge on the rotation rear side on the axis upstream side of the sealing fin. Therefore, a large moment acts radially outward on the portion of the edge on the rotation rear side on the axis line downstream side of the seal fin.

As described above, when a large moment acts on a part of the shroud cover radially outward, the part tends to deform radially outward relative to the other part. In this aspect, the proximal end of the offset portion of the seal fin is present in the vicinity of the portion of the shroud cover on which a large moment acts radially outward. Thus, in this aspect, the weight increase of the shroud can be suppressed, and the deformation of the shroud cover can be suppressed.

In the bucket according to any one of the above aspects in which the seal fin has the first end portion and the second end portion, the gas passage surface may have a transition surface that gradually extends radially outward in a direction away from the positive pressure surface and the negative pressure surface of the blade body, in a cross section orthogonal to the mean camber line. In addition, the counter gas passage surface may have a concave surface that expands in the cross section so as to be concave inward in the radial direction along the transition surface. In this case, the height of the sealing fin in the radial direction is higher in an intermediate portion between the first end portion and the second end portion than in the first end portion.

In the rotor blade according to any one of the above aspects, the gas passage surface may have a transition surface that gradually extends radially outward in a direction in which the gas passage surface is separated from the positive pressure surface and the negative pressure surface of the blade in a cross section orthogonal to the camber line of the blade. In addition, the counter gas passage surface may have a concave surface that expands along the transition surface so as to be concave toward the radially inner side in the cross section.

Stresses are generated at the root portion of the shroud cover with respect to the blade body. As a method of alleviating this stress, there is a method of increasing the radius of curvature of the transition surface. The concave surface of this aspect is a surface that expands in such a manner as to be recessed radially inward along the transition surface in the gas passing surface. Therefore, in this aspect, even if the radius of curvature of the transition surface is increased, the distance between the gas passage surface and the counter gas passage surface, that is, the thickness of the lid does not become thick. Therefore, in this aspect, the weight of the shroud cover can be reduced while relaxing the stress generated at the root portion of the shroud cover with respect to the blade body.

In the bucket according to any one of the above aspects having the concave surface, the concave surface may be expanded to both sides with reference to the mean camber line in the cross section. In this case, in the cross section, a surface on a positive pressure side of the concave surface with respect to the camber line on which the positive pressure surface exists tends toward the radially inner side as it goes toward a negative pressure side of the concave surface with respect to the camber line on which the negative pressure surface exists, and in the concave surface, a surface on a negative pressure side of the concave surface with respect to the camber line on which the negative pressure surface exists tends toward the radially inner side as it goes toward the positive pressure side.

In this scheme, the concave surface uses the mean camber line as the benchmark to both sides extension, consequently can lighten the weight of shroud cover more.

An axial flow rotary machine according to an aspect of the present invention for achieving the above object includes the plurality of rotor blades, the rotor shaft, and the casing according to the above aspect. The plurality of blades are arranged in the circumferential direction and attached to the rotor shaft. The casing covers an outer circumferential side of the rotor shaft and the plurality of blades.

ADVANTAGEOUS EFFECTS OF INVENTION

According to one aspect of the present invention, the durability of the shroud cover can be improved while suppressing an increase in the weight of the shroud.

Drawings

Fig. 1 is a schematic sectional view of a gas turbine according to an embodiment of the present invention.

Fig. 2 is a perspective view of a bucket according to a first embodiment of the present invention.

Fig. 3 is a view of the rotor blade according to the first embodiment of the present invention as viewed from the radially outer side.

Fig. 4 is a sectional view taken along line IV-IV in fig. 3, relating to the bucket in the first embodiment of the present invention.

Fig. 5 is a sectional view taken along the line V-V in fig. 3, relating to the bucket in the first embodiment of the present invention.

Fig. 6 is a sectional view taken along line VI-VI in fig. 3, relating to the bucket in the first embodiment of the present invention.

Fig. 7 is a sectional view taken along line VII-VII in fig. 3, relating to a bucket in a second embodiment of the present invention.

Fig. 8 is a sectional view taken along line VIII-VIII in fig. 3, relating to the bucket in the second embodiment of the present invention.

Fig. 9 is a sectional view taken along line IX-IX in fig. 3 in relation to a bucket in a third embodiment of the invention.

Fig. 10 is a sectional view taken along the line X-X in fig. 3, relating to the bucket in the third embodiment of the present invention.

Fig. 11 is a sectional view taken along line XI-XI in fig. 3, relating to a bucket in a fourth embodiment of the invention.

Fig. 12 is a sectional view taken along line XII-XII in fig. 3, relating to the bucket in the fourth embodiment of the present invention.

Fig. 13 is a cross-sectional view along XIII-XIII in fig. 3 relating to a bucket in a fifth embodiment of the invention.

Fig. 14 is a cross-sectional view along the XIV-XIV line in fig. 3 relating to a bucket in a fifth embodiment of the present invention.

Fig. 15 is a sectional view of a rotor blade according to a modification of each embodiment of the present invention.

Description of the reference numerals

10: gas turbine

11: gas turbine rotor

14: middle shell

15: gas turbine casing

20: compressor with a compressor housing having a plurality of compressor blades

21: compressor rotor

22: rotor shaft

23: rotor blade row

25: compressor shell

26: stationary blade row

30: burner with a burner head

40: turbine wheel

41: turbine rotor

42: rotor shaft

43: rotor blade row

45: turbine housing

46: stationary blade row

50. 50a, 50b, 50c, 50 d: moving vane

51: blade body

52: leading edge

53: trailing edge

54: negative pressure surface

55: positive pressure noodle

56 o: outer end

56 i: inner end

57: protective cover

58: platform

59: blade root

60. 60 d: protective cover cap

61: cover main body

62: outer edge part

63: end of the main body

64: main body middle part

65: near the blade

66: gas passing surface

67: transition surface

68. 68 d: counter gas passing surface

69: concave surface

71: first outer edge

72: second outer edge

73: contact surface

80. 80a, 80b, 80 c: sealing fin

81: first end part

82: second end portion

83: base end

83 f: front base end

83 r: rear base end

83 c: central position (of basal end)

84: tip end

84 f: front top end

84 r: rear tip

84 c: (apical) center position

85: front surface

86: rear surface

87: offset part

87 p: positive pressure side offset part

87 f: negative pressure side offset part

88. 88 c: inclined part

89: intermediate section

A: air (a)

F: fuel

G: combustion gas

CL: mean camber line

Ar: axial line

Da: axial direction

And 2, Dau: axial upstream side

And Dad: downstream side of axis

Dc: circumferential direction

Dcf: rotating front side

Dcr: rotating back side

Dr: radial direction

Dri: radially inner side

Dro: radially outside

Dn: negative pressure side

And Dp: positive pressure side

Ds: direction of approach of blade body

And Dt: blade body separation direction.

Detailed Description

The embodiments and various modifications of the present invention will be described in detail below with reference to the accompanying drawings.

< embodiment of axial-flow rotary machine >

An embodiment of an axial flow fluid machine according to the present invention is described with reference to fig. 1.

The axial flow rotary machine of the present embodiment is a gas turbine 10. The gas turbine 10 includes a compressor 20 that compresses air a, a combustor 30 that burns fuel F in the air a compressed by the compressor 20 to generate combustion gas G, and a turbine 40 that is driven by the combustion gas G.

The compressor 20 includes a compressor rotor 21 that rotates about an axis Ar, a compressor casing 25 that covers the compressor rotor 21, and a plurality of vane rows 26. The turbine 40 includes a turbine rotor 41 that rotates about an axis Ar, a turbine casing 45 that covers the turbine rotor 41, and a plurality of vane rows 46. In the following, the direction in which the axis Ar extends is referred to as an axis direction Da, the circumferential direction around the axis Ar is simply referred to as a circumferential direction Dc, and the direction perpendicular to the axis Ar is referred to as a radial direction Dr. One side in the axial direction Da is an axial upstream side Dau, and the opposite side is an axial downstream side Dad. Further, a side closer to the axis Ar in the radial direction Dr is a radially inner side Dri, and an opposite side is a radially outer side Dro.

The compressor 20 is disposed on the axial upstream side Dau of the turbine 40. The compressor rotor 21 and the turbine rotor 41 are located on the same axis Ar, and are connected to each other to form the gas turbine rotor 11. A rotor of the generator GEN, for example, is connected to the gas turbine rotor 11. The gas turbine 10 further includes an intermediate casing 14, and the intermediate casing 14 is disposed between the compressor casing 25 and the turbine casing 45. A burner 30 is mounted to the intermediate housing 14. The compressor housing 25, the intermediate housing 14, and the turbine housing 45 are connected to each other to form the gas turbine housing 15.

The compressor rotor 21 includes a rotor shaft 22 extending in the axial direction Da about the axis Ar, and a plurality of rotor blade rows 23 attached to the rotor shaft 22. The plurality of rotor blade rows 23 are aligned in the axial direction Da. Each of the rotor blade rows 23 is formed of a plurality of rotor blades arranged in the circumferential direction Dc. Any one of the plurality of stationary blade rows 26 is disposed on the downstream side Dad of each axis of the plurality of rotor blade rows 23. Each of the vane rows 26 is provided inside the compressor casing 25. Each of the vane rows 26 is formed of a plurality of vanes arranged in the circumferential direction Dc.

The turbine rotor 41 includes a rotor shaft 42 extending in the axial direction Da about the axis Ar, and a plurality of rotor blade rows 43 attached to the rotor shaft 42. The plurality of rotor blade rows 43 are aligned in the axial direction Da. Each of the rotor blade rows 43 is formed of a plurality of rotor blades 50 arranged in the circumferential direction Dc. Any one of the plurality of stator blade rows 46 is disposed on the axially upstream side Dau of each of the plurality of rotor blade rows 43. Each stationary blade row 46 is provided inside the turbine casing 45. Each of the vane rows 46 is formed of a plurality of vanes arranged in the circumferential direction Dc.

The compressor 20 sucks air a and compresses it. The compressed air, i.e., compressed air, flows into the combustor 30 via the intermediate housing 14. The fuel F is supplied to the combustor 30 from the outside. The combustor 30 combusts fuel F in the compressed air to generate combustion gas G. The combustion gas G flows into the turbine housing 45, and rotates the turbine rotor 41. The generator GEN generates power by the rotation of the turbine rotor 41.

Various embodiments of the rotor blade described above will be described below.

< first embodiment of bucket >

Referring to fig. 2 to 6, a bucket according to a first embodiment of the present invention will be described.

As shown in fig. 2, the rotor blade 50 of the present embodiment includes an airfoil-shaped blade body 51, a shroud 57, a platform 58, and a blade root 59. The blade body 51 extends in the radial direction Dr. The blade body 51 has a wing-like cross-sectional shape. The cross section is a cross section of the blade body 51 perpendicular to the radial direction Dr. The shroud 57 is provided at an outer end 560 that is an end of the radially outer side Dro of the blade body 51. The platform 58 is provided at the inner end 56i, which is an end of the radially inner side Dri of the blade body 51. The blade root 59 is disposed radially inward Dri of the platform 58.

The platform 58 expands in a direction having a directional component perpendicular to the radial direction Dr. The blade root 59 is configured to attach the bucket 50 to the rotor shaft 42.

The shroud 57 has a shroud cover 60 and a sealing fin 80. The shroud cap 60 expands in a direction having a directional component perpendicular to the radial direction Dr. The sealing fin 80 is disposed radially outward Dro of the shroud cover 60.

As shown in fig. 2 and 3, the blade body 51 has a leading edge 52, a trailing edge 53, a negative pressure surface (back surface) 54, and a positive pressure surface (ventral surface) 55, the negative pressure surface (back surface) 54 being a convex surface, and the positive pressure surface (ventral surface) 55 being a concave surface. The leading edge 52 and the trailing edge 53 exist at the connecting portion of the negative pressure surface 54 and the positive pressure surface 55. The leading edge 52, trailing edge 53, suction surface 54, and positive pressure surface 55 all extend in a direction having a directional component in the radial direction Dr. The leading edge 52 is located on the axis upstream side Dau with respect to the trailing edge 53.

The shroud cover 60 has contact surfaces 73 on both sides in the circumferential direction Dc. The contact surface 73 of the shroud cover 60 is in opposed contact with the contact surface 73 of the shroud cover 60 of another bucket 50 adjacent to the bucket 50 having the shroud cover 60 in the circumferential direction Dc.

As shown in fig. 4 to 6, the shroud cover 60 is expanded in the blade separation direction Dt in a cross section perpendicular to the camber line CL of the blade 51. It is noted that fig. 4 is a sectional view taken along line V-IV of fig. 3, fig. 5 is a sectional view taken along line V-V of fig. 3, and fig. 6 is a sectional view taken along line VI-VI of fig. 3. These cross-sectional views are all cross-sectional views at a cross-section orthogonal to the camber line CL of the blade body 51. In these cross-sectional views, components existing on the back side of the cross-sectional view are not depicted. The blade body separation direction Dt is a direction perpendicular to the radial direction Dr and is a direction away from the blade body 51. The blade approaching direction Ds is a direction perpendicular to the radial direction Dr and is a direction toward the blade 51. Thereby, the blade approaching direction Ds is opposite to the blade separating direction Dt. The blade separating direction Dt of the negative pressure side Dn on which the negative pressure surface 54 is present with respect to the camber line CL is opposite to the blade separating direction Dt of the positive pressure side Dp on which the positive pressure surface 55 is present with respect to the camber line CL. Further, the blade approaching direction Ds on the negative pressure side Dn with respect to the camber line CL is opposite to the blade approaching direction Ds on the positive pressure side Dp with respect to the camber line CL.

The shroud cover 60 has a cover main body 61 and an outer edge portion 62 connected to the cover main body 61. The outer edge portion 62 is located closer to the blade body separating direction Dt than the cover main body 61 in a cross section perpendicular to the camber line CL. In other words, the cover main body 61 is located closer to the blade approaching direction Ds than the outer edge portion 62 in the cross section orthogonal to the camber line CL. The outer edge portion 62 protrudes in the radial direction Dr with respect to the cover main body 61. In the present embodiment, the outer edge portion 62 protrudes radially outward Dro with respect to the cover main body 61. The contact surface 73 is formed in a part of the outer edge 62.

Both the cover main body 61 and the outer peripheral portion 62 have a gas passage surface 66 and a counter gas passage surface 68. The gas passage surface 66 is a surface exposed to the outside of the rotor blade 50 toward the radially inner side Dri. The counter gas passage surface 68 is a surface exposed to the outside of the rotor blade 50 toward the radial outer side Dro.

The gas passage surface 66 has a transition surface 67 that gradually extends radially outward Dro toward the blade body separation direction Dt in a cross section orthogonal to the camber line CL. The transition surface 67 is curved. The back gas passage surface 68 has a concave surface 69 that expands so as to be recessed toward the radially inner side Dri and toward the radially inner side Dri as the blade body approaches the direction Ds, in a cross section orthogonal to the camber line CL. In other words, the concave surface 69 is a surface that extends so as to be recessed radially inward Dri along the transition surface 67 of the gas passage surface 66. The concave surface 69 extends to both sides with respect to the mean camber line CL. Therefore, in a cross section orthogonal to the camber line CL, a part of the concave surface 69 is located on the negative pressure side Dn with reference to the camber line CL, and the remaining part of the concave surface 69 is located on the positive pressure side Dp with reference to the camber line CL. A part of the concave surface 69 on the negative pressure side Dn is inclined toward the positive pressure side Dp as it goes toward the radially inner side Dri, and the remaining part of the concave surface on the positive pressure side Dp is inclined toward the negative pressure side Dn as it goes toward the radially inner side Dri. Thus, the inclination directions of a part of the concave surface 69 on the negative pressure side Dn and the rest of the concave portion on the positive pressure side Dp are opposite.

The cover main body 61 has a main body end portion 63, a main body intermediate portion 64, and a blade vicinity portion 65. The main body intermediate portion 64 is a portion of the cover main body 61 corresponding to an intermediate portion of the transition surface 67 in the blade body approaching direction Ds in a cross section orthogonal to the camber line CL. The blade vicinity portion 65 is a portion of the cover main body 61 located closer to the blade approaching direction Ds than the main body intermediate portion 64 in a cross section orthogonal to the camber line CL. The main body end portion 63 is a portion of the cover main body 61 located closer to the blade body separating direction Dt than the main body intermediate portion 64, and is a portion continuous with the outer edge portion 62. Concave surfaces 69 are formed at the body end portion 63, the body intermediate portion 64, and the blade vicinity portion 65.

Here, the distance between the gas passage surface 66 and the counter gas passage surface 68 is set as the cover thickness. In each of the cross sections shown in fig. 4 to 6, the cover thicknesses t1a, t1b of the outer edge portion 62 are thicker than the cover thicknesses t2a, t2b of the body end portion 63. The cover thicknesses t3a, t3b of the body middle portion 64 are thicker than the cover thicknesses t2a, t2b of the body end portion 63. The cover thicknesses t4a, t4b of the blade vicinity portion 65 are also thicker than the cover thicknesses t2a, t2b of the body end portion 63. That is, the cover thicknesses t2a, t2b of the body end 63 in all cross-sections are thinnest.

As shown in fig. 3 to 6, the seal fin 80 protrudes radially outward Dro from the back gas passage surface 68 of the shroud cover 60. The sealing fin 80 extends from a first outer edge 71, which is one portion of the outer edge of the reaction-gas passing surface 68, to a second outer edge 72, which is another portion of the outer edge of the reaction-gas passing surface 68, in a direction having a circumferential Dc component, across a camber line CL of the blade body 51. The first outer edge 71 is an outer edge of the counter gas passage surface 68 on the rotation front side Dcf (see fig. 3) in the circumferential direction Dc. Further, the second outer edge 72 is an outer edge of the rotation rear side Dcr in the circumferential direction Dc, of the outer edges of the counter gas passage surface 68. The rotation front side Dcf is one of both sides of the circumferential direction Dc on which the rotor shaft 42 (see fig. 1) rotates. The rotation rear side Dcr is the opposite side of the two sides in the circumferential direction Dc from the rotation front side Dcf.

The seal fin 80 has a base end 83 intersecting the counter gas passage surface 68, a tip end 84 located most radially outward Dro, a front surface 85 facing the axis upstream side Dau, and a rear surface 86 facing the axis downstream side Dad. The base end 83 has a front base end 83f, which is the end of the front surface 85 closest to the radially inner side Dri, and a rear base end 83r, which is the end of the rear surface 86 closest to the radially inner side Dri. The front base end 83f is a portion where the counter gas passage surface 68 intersects with the front surface 85. In addition, the rear base end 83r is a portion where the counter gas passage surface 68 intersects the rear surface 86. The tip 84 has an end of the front surface 85 that is most radially outward Dro, i.e., a front tip 84f, and an end of the rear surface 86 that is most radially outward Dro, i.e., a rear tip 84 r.

Further, the sealing fin 80 has: a first end portion 81 (see fig. 3) projecting radially outward Dro from the first outer edge 71 of the counter gas passage surface 68; a second end portion 82 protruding radially outward Dro from the second outer edge 72 of the counter gas passage surface 68; and a shift portion 87 that shifts a center position 83c of the base end 83 in the axial direction Da with respect to a center position of the tip end 84 in the axial direction Da. An offset 87 exists between the first end 81 and the second end 82. The offset portion 87 has an inclined portion 88 that goes toward the axial direction Da as going toward the radially inner side Dri. In the present embodiment, the inclined portion 88 is formed in a region not including the distal end 84 but including the proximal end 83. In addition, the offset portion 87 has a positive pressure side offset portion 87p and a negative pressure side offset portion 87n (see fig. 3). The positive pressure side offset portion 87p is located on the positive pressure side Dp with reference to the camber line CL. The negative pressure side offset portion 87n is located on the negative pressure side Dn with reference to the camber line CL.

In the present embodiment, as shown in fig. 3 and 4, the front base end 83f of the positive pressure side offset portion 87p is offset toward the axial upstream side Dau with respect to the front tip end 84f of the positive pressure side offset portion 87 p. In the present embodiment, the rear base end 83r of the positive pressure side offset portion 87p is offset toward the axial upstream side Dau with respect to the rear tip end 84r of the positive pressure side offset portion 87 p. Therefore, in the positive side offset portion 87p of the present embodiment, the center position 83c of the base end 83 in the axial direction Da is offset toward the axial upstream side Dau with respect to the center position 84c of the tip end 84 in the axial direction Da.

In the present embodiment, as shown in fig. 3, 5, and 6, the front base end 83f of the negative pressure side offset portion 87n is offset toward the axial downstream side Dad with respect to the front tip end 84f of the negative pressure side offset portion 87 n. In the present embodiment, the rear base end 83r of the negative pressure side offset portion 87n is offset toward the axis line downstream side Dad with respect to the rear tip end 84r of the negative pressure side offset portion 87 n. Therefore, in the negative pressure side offset portion 87n of the present embodiment, the center position 83c of the base end 83 in the axial direction Da is offset toward the axial downstream side Dad with respect to the center position 84c of the tip end 84 in the axial direction Da.

As shown in fig. 3, the first end portion 81 of the seal fin 80 needs to be opposed to the second end portion 82 of the seal fin 80 of another bucket 50 adjacent to the bucket 50 having the seal fin 80 on the rotation front side Dcf in the circumferential direction Dc between the base end 83 and the tip end 84. The second end 82 of the seal fin 80 needs to be opposed to the first end 81 of the seal fin 80 of another bucket 50 adjacent to the bucket 50 having the seal fin 80 on the post-rotation side Dcr in the circumferential direction Dc between the base end 83 and the tip end 84. Therefore, in the first end portion 81 and the second end portion 82 of the seal fin 80, the center position 83c in the axial direction Da of the base end 83 coincides with the center position 84c in the axial direction Da of the tip end 84.

The distance from the tip 84 of the seal fin 80 to the axis Ar is constant regardless of the position in the circumferential direction Dc. However, the fin height at the position of the middle portion of the first end portion 81 and the second end portion 82 is higher than the fin height of the first end portion 81 (see fig. 3) of the sealing fin 80 and the fin height of the second end portion 82 of the sealing fin 80. This is because the counter-gas passage face 68 has a concave face 69. Note that the fin height is the distance from the counter-gas passing surface 68 to the tip 84 of the sealing fin 80.

As described above, in the present embodiment, since the counter gas passage surface 68 has the concave surface 69 recessed toward the radially inner side Dri, the weight of the shroud cover 60 can be reduced.

Stress is generated in the root portion of the shroud cover 60 with respect to the blade body 51. As a method of alleviating this stress, there is a method of increasing the radius of curvature of the transition surface 67. The concave surface 69 of the present embodiment is a surface that extends along the transition surface 67 of the gas passage surface 66 so as to be recessed radially inward Dri. Therefore, in the present embodiment, even if the radius of curvature of the transition surface 67 is increased, the cover thickness, which is the distance between the gas passage surface 66 and the counter gas passage surface 68, is not increased. Therefore, in the present embodiment, the stress generated at the root portion of the shroud cover 60 with respect to the blade body 51 can be relaxed, and the weight of the shroud cover 60 can be reduced. In the present embodiment, the concave surface 69 extends to both sides with respect to the camber line CL, and therefore the weight of the shroud cover 60 can be further reduced.

In the present embodiment, since the outer edge portion 62 is provided to protrude in the radial direction Dr with respect to the cover main body 61, it is possible to suppress an increase in weight of the shroud cover 60 and to improve rigidity of the outer edge of the shroud cover 60.

In the present embodiment, the cover thicknesses t2a, t2b of the body end 63 located in the region farther from the mean camber line CL than the body intermediate portion 64 are the thinnest in the shroud cover 60. Therefore, in the present embodiment, the rigidity of the outer edge of the shroud cover 60 is improved by the outer edge portion 62, and an increase in the moment received by the shroud cover 60 with respect to the camber line CL can be suppressed.

In the present embodiment, the mutual size relationship between the cover thicknesses t1a, t1b of the outer edge portion 62, the cover thicknesses t3a, t3b of the main body intermediate portion 64, and the cover thicknesses t4a, t4b of the blade vicinity portion 65 is not limited.

As shown in fig. 3, the contact surface 73 on the forward side Dcf of the shroud cover 60 contacts the contact surface 73 on the backward side Dcr of the shroud cover 60 of another bucket 50 adjacent to the bucket 50 having the seal fin 80 on the forward side Dcf. The edge of the shroud cover 60 on the rotation front side Dcf receives a load toward the radial outer side Dro due to a centrifugal force. The distance between the portion of the edge of the rotation front side Dcf on the axis upstream side Dau of the sealing fin 80 and the camber line CL is greater than the distance between the portion of the edge of the rotation front side Dcf on the axis downstream side Dad of the sealing fin 80 and the camber line CL. Therefore, the moment based on the camber line CL received by the portion 75u of the edge of the rotation front side Dcf on the axis line upstream side Dau of the sealing fin 80 is larger than the moment based on the camber line CL received by the portion of the edge of the rotation front side Dcf on the axis line downstream side Dad of the sealing fin 80. Therefore, a large moment acts radially outward Dro on the portion 75u of the edge of the rotation front side Dcf on the axial upstream side Dau of the seal fin 80.

Further, the contact surface 73 on the rotationally trailing side Dcr of the shroud cover 60 contacts the contact surface 73 on the rotationally leading side Dcf of the shroud cover 60 of the other bucket 50 adjacent to the bucket 50 having the seal fin 80 on the rotationally trailing side Dcr. The edge of the shroud cover 60 on the rotation rear side Dcr receives a load toward the radial outer side Dro due to a centrifugal force. The distance between the portion of the edge of the rotation rear side Dcr on the axis line downstream side Dad of the sealing fin 80 and the camber line CL is greater than the distance between the portion of the edge of the rotation rear side Dcr on the axis line upstream side Dau of the sealing fin 80 and the camber line CL. Therefore, the moment based on the camber line CL received by the portion 75d of the edge of the post-rotation Dcr on the axis downstream side Dad of the sealing fin 80 is larger than the moment based on the camber line CL received by the portion of the edge of the post-rotation Dcr on the axis upstream side Dau of the sealing fin 80. Therefore, a large moment toward the radial outer side Dro acts on the portion 75d of the edge of the rotation rear side Dcr on the axial downstream side Dad of the seal fin 80.

As described above, when a large moment acts on the portions 75u and 75d of the shroud cover 60 toward the radial outer side Dro, the portions 75u and 75d tend to deform toward the radial outer side Dro with respect to the other portions. As a method of suppressing the deformation, a method of increasing the thickness of the shroud cover 60, and a method of increasing the thickness between the base end 83 and the tip end 84 of the seal fin 80 may be considered.

In the present embodiment, the proximal end 83 of the offset portion 87 of the seal fin 80 is present in the vicinity of the portions 75u, 75d of the shroud cover 60, on which a large moment acts on the radially outer side Dro. Thus, in the present embodiment, the deformation of the portions 75u and 75d of the shroud cover 60, on which a large moment acts on the radially outer side Dro, with respect to the other portions can be suppressed. In the present embodiment, instead of increasing the thickness of the shroud cover 60 or increasing the thickness between the base end 83 and the tip end 84 of the seal fin 80, the base end 83 of the seal fin 80 is offset in the axial direction Da with respect to the tip end 84, and the base end 83 is positioned in the vicinity of the portions 75u and 75d on which a large moment acts on the radially outer side Dro. Thus, in the present embodiment, the seal fin 80 has the offset portion 87, and thus the weight increase of the shroud 57 can be suppressed, and the deformation of the shroud cover 60 can be suppressed.

As described above, in the present embodiment, since the counter gas passage surface 68 of the shroud cover 60 has the concave surface 69 and the seal fin 80 has the offset portion 87, it is possible to suppress an increase in weight of the shroud 57 and to improve durability of the shroud cover 60.

< second embodiment of bucket >

Referring to fig. 3, 7, and 8, a bucket according to a third embodiment of the present invention will be described.

As shown in fig. 7 and 8, the bucket 50a of the present embodiment is a bucket having a shape that is changed from the shape of the sealing fin 80 of the bucket 50 of the first embodiment, and the other configurations are the same as those of the bucket 50 of the first embodiment. Fig. 7 is a sectional view taken along line VII-VII of fig. 3, and fig. 8 is a sectional view taken along line VIII-VIII of fig. 3. In the description of the bucket 50a of the present embodiment, fig. 3 showing the bucket 50 of the first embodiment is added for convenience, and the seal fin 80 of the first embodiment is depicted in fig. 3. However, the shape of the seal fin 80a when the bucket 50a of the present embodiment is viewed from the radially outer side Dro is different from the shape of the seal fin 80 shown in fig. 3.

As shown in fig. 7 and 8, the seal fin 80a of the present embodiment also protrudes radially outward Dro from the back gas passage surface 68 of the shroud cover 60, similarly to the seal fin 80 of the first embodiment. This sealing fin 80a is also the same as the sealing fin 80 of the first embodiment, extending from a first outer edge 71 (see fig. 3), which is one portion of the outer edge of the reaction-gas passing surface 68, across the camber line CL of the blade body 51, to a second outer edge 72, which is another portion of the outer edge of the reaction-gas passing surface 68, in a direction having the circumferential Dc component.

The sealing fin 80a also has a base end 83, a tip end 84, a front surface 85, and a rear surface 86, as in the sealing fin 80 of the first embodiment. In addition, the base end 83 has a front base end 83f and a rear base end 83 r. The tip 84 has a front tip 84f and a rear tip 84 r.

As shown in fig. 3, the sealing fin 80a also includes, similarly to the sealing fin 80 of the first embodiment: a first end portion 81 projecting radially outward Dro from the first outer edge 71 of the counter gas passage surface 68; a second end portion 82 protruding radially outward Dro from the second outer edge 72 of the counter gas passage surface 68; and a shift portion 87 that shifts a center position 83c of the base end 83 in the axial direction Da with respect to a center position 84c of the tip end 84 in the axial direction Da. An offset 87 exists between the first end 81 and the second end 82. The offset portion 87 has an inclined portion 88 that goes toward the axial direction Da as going toward the radially inner side Dri. The offset portion 87 includes a positive pressure side offset portion 87p and a negative pressure side offset portion 87 n.

As shown in fig. 7, in the present embodiment, the front base end 83f of the positive pressure side offset portion 87p is offset toward the axial upstream side Dau with respect to the front tip end 84f of the positive pressure side offset portion 87 p. In the present embodiment, the rear base end 83r of the positive pressure side offset portion 87p is offset toward the axial upstream side Dau with respect to the rear tip end 84r of the positive pressure side offset portion 87 p. Therefore, in the positive side offset portion 87p of the present embodiment, as in the positive side offset portion 87p of the first embodiment, the center position 83c of the base end 83 in the axial direction Da is offset toward the axial upstream side Dau with respect to the center position 84c of the tip end 84 in the axial direction Da.

As shown in fig. 8, in the present embodiment, the front base end 83f of the negative pressure side offset portion 87n is offset to the axial line downstream side Dad with respect to the front tip end 84f of the negative pressure side offset portion 87 n. In the present embodiment, the rear base end 83r of the negative pressure side offset portion 87n is offset toward the axis line downstream side Dad with respect to the rear tip end 84r of the negative pressure side offset portion 87 n. Therefore, in the negative pressure side shifting section 87n of the present embodiment, as in the negative pressure side shifting section 87n of the first embodiment, the center position 83c of the base end 83 in the axial direction Da is shifted toward the downstream side Dad of the axis with respect to the center position 84c of the tip end 84 in the axial direction Da.

The structure of the sealing fin 80a of the present embodiment described above is the same as that of the sealing fin 80 of the first embodiment.

However, in the present embodiment, the amount of displacement of the front base end 83f of the positive pressure side displacement portion 87p toward the axial upstream side Dau with respect to the front tip end 84f of the positive pressure side displacement portion 87p is larger than the amount of displacement of the rear base end 83r of the positive pressure side displacement portion 87p toward the axial upstream side Dau with respect to the rear tip end 84r of the positive pressure side displacement portion 87 p. Therefore, the thickness tf3 (see fig. 7) in the axial direction Da of the base end 83 of the positive side offset portion 87P of the present embodiment is thicker than the thickness in the axial direction Da of the base end 83 of the positive side offset portion 87P of the first embodiment. In the present embodiment, the amount of displacement of the rear base end 83r of the negative pressure side displacement portion 87n toward the axis downstream side Dad from the rear tip end 84r of the negative pressure side displacement portion 87n is larger than the amount of displacement of the front base end 83f of the negative pressure side displacement portion 87n toward the axis downstream side Dad from the front tip end 84f of the negative pressure side displacement portion 87 n. Therefore, the thickness tf3 (see fig. 8) in the axial direction Da of the base end 83 of the negative-side shifting portion 87n of the present embodiment is thicker than the thickness in the axial direction Da of the base end 83 of the negative-side shifting portion 87n of the first embodiment.

As described above, the bucket 50a of the present embodiment is a bucket in which the shape of the sealing fin 80 of the bucket 50 of the first embodiment is changed, and the other configurations are the same as those of the bucket 50 of the first embodiment. Thus, the counter gas passage surface 68 of the present embodiment also has a concave surface 69 recessed radially inward Dri, similarly to the counter gas passage surface 68 of the first embodiment. Therefore, in the present embodiment as well, as in the first embodiment, it is possible to alleviate the stress generated in the root portion of the shroud cover 60 with respect to the blade body 51, and to reduce the weight of the shroud cover 60.

Further, the seal fin 80a of the present embodiment has the offset portion 87 that offsets the center position 83c in the axial direction Da of the base end 83 from the center position 84c in the axial direction Da of the tip end 84, similarly to the seal fin 80 of the first embodiment, in the axial direction Da, and therefore can suppress an increase in the weight of the shroud and suppress deformation of the shroud cover 60.

Further, since the thickness of the base end 83 of the offset portion 87 of the present embodiment in the axial direction Da is larger than the thickness of the base end 83 of the offset portion 87 of the first embodiment in the axial direction Da, it is possible to alleviate stress generated in the base end 83 and to suppress deformation of the shield cover 60 more than in the first embodiment.

< third embodiment of bucket >

A rotor blade according to a third embodiment of the present invention will be described with reference to fig. 3, 9, and 10.

As shown in fig. 9 and 10, the bucket 50b of the present embodiment is a bucket in which the shape of the sealing fin 80 of the bucket 50 of the first embodiment is changed, and the other configurations are the same as those of the bucket 50 of the first embodiment. It should be noted that fig. 9 is a sectional view taken along line IX-IX of fig. 3, and fig. 10 is a sectional view taken along line X-X of fig. 3. In describing the bucket 50b of the present embodiment, fig. 3 showing the bucket 50 of the first embodiment is added for convenience, and the seal fin 80 of the first embodiment is depicted in fig. 3. However, the shape of the seal fin 80b when the bucket 50b of the present embodiment is viewed from the radially outer side Dro is different from the shape of the seal fin 80 shown in fig. 3.

The sealing fin 80b of the present embodiment also protrudes radially outward Dro from the back gas passage surface 68 of the shroud cover 60, as shown in fig. 9 and 10, similarly to the sealing fin 80 of the first embodiment. This sealing fin 80b is also the same as the sealing fin 80 of the first embodiment, extending from a first outer edge 71 (see fig. 3), which is one portion of the outer edge of the reaction-gas passing surface 68, across the camber line CL of the blade body 51, to a second outer edge 72, which is another portion of the outer edge of the reaction-gas passing surface 68, in a direction having the circumferential Dc component.

The sealing fin 80b also has a base end 83, a tip end 84, a front surface 85, and a rear surface 86, as in the sealing fin 80 of the first embodiment. In addition, the base end 83 has a front base end 83f and a rear base end 83 r. The tip 84 has a front tip 84f and a rear tip 84 r.

The sealing fin 80b is also similar to the sealing fin 80 of the first embodiment, and as shown in fig. 3, includes: a first end portion 81 projecting radially outward Dro from the first outer edge 71 of the counter gas passage surface 68; a second end portion 82 protruding radially outward Dro from the second outer edge 72 of the counter gas passage surface 68; and a shift portion 87 that shifts a center position 83c of the base end 83 in the axial direction Da with respect to a center position 84c of the tip end 84 in the axial direction Da. An offset 87 exists between the first end 81 and the second end 82. The offset portion 87 includes a positive pressure side offset portion 87p and a negative pressure side offset portion 87 n.

In the present embodiment, as shown in fig. 9, the front base end 83f of the positive pressure side offset portion 87p is offset toward the axial upstream side Dau with respect to the front tip end 84f of the positive pressure side offset portion 87 p. In the present embodiment, as shown in fig. 10, the front base end 83f of the negative pressure side offset portion 87n is offset toward the axis line downstream side Dad with respect to the front tip end 84f of the negative pressure side offset portion 87 n.

The structure of the sealing fin 80b of the present embodiment described above is the same as that of the sealing fin 80 of the first embodiment.

However, in the present embodiment, as shown in fig. 9, the rear base end 83r of the positive pressure side offset portion 87p is offset toward the axis downstream side Dad rather than the axis upstream side Dau with respect to the rear tip end 84r of the positive pressure side offset portion 87 p. In the present embodiment, the amount of displacement of the rear base end 83r of the positive pressure side displacement portion 87p toward the axis downstream side Dad with respect to the rear tip end 84r of the positive pressure side displacement portion 87p is smaller than the amount of displacement of the front base end 83f of the positive pressure side displacement portion 87p toward the axis upstream side Dau with respect to the front tip end 84f of the positive pressure side displacement portion 87 p. Therefore, the positive pressure side shifting section 87p of the present embodiment is also the same as the positive pressure side shifting sections 87p of the above embodiments, and the center position 83c in the axial direction Da of the base end 83 is shifted to the axial upstream side Dau with respect to the center position 84c in the axial direction Da of the tip end 84.

In the present embodiment, as shown in fig. 10, the front base end 83f of the negative pressure side offset portion 87n is offset toward the axial upstream side Dau rather than the axial downstream side Dad with respect to the front tip end 84f of the negative pressure side offset portion 87 n. In the present embodiment, the amount of displacement of the front base end 83f of the negative pressure side displacement portion 87n toward the axial upstream side Dau with respect to the front tip end 84f of the negative pressure side displacement portion 87n is smaller than the amount of displacement of the rear base end 83r of the negative pressure side displacement portion 87n toward the axial downstream side Dad with respect to the rear tip end 84r of the negative pressure side displacement portion 87 n. Therefore, the negative pressure side offset portion 87n of the present embodiment is also offset axially downstream from the center positions 83c, 84c of the base end 83 in the axial direction Da with respect to the center positions 83c, 84c of the tip end 84 in the axial direction Da, similarly to the negative pressure side offset portions 87n of the above embodiments.

As described above, the bucket 50b of the present embodiment is a bucket in which the shape of the sealing fin 80 of the bucket 50 of the first embodiment is changed, and the other configurations are the same as those of the bucket 50 of the first embodiment. Thus, the counter gas passage surface 68 of the present embodiment also has a concave surface 69 recessed radially inward Dri, similarly to the counter gas passage surface 68 of the first embodiment. Therefore, in the present embodiment as well, as in the first embodiment, the stress generated at the root portion of the shroud cover 60 with respect to the blade body 51 can be relaxed, and the weight of the shroud cover 60 can be reduced.

Further, the seal fin 80b of the present embodiment has the offset portion 87 that offsets the center position 83c in the axial direction Da of the base end 83 from the center position 84c in the axial direction Da of the tip end 84, similarly to the seal fin 80 of the first embodiment, in the axial direction Da, and therefore can suppress an increase in the weight of the shroud and suppress deformation of the shroud cover 60.

The thickness of the base end 83 of the offset portion 87 of the present embodiment in the axial direction Da is larger than the thickness of the base end 83 of the offset portion 87 of the first and second embodiments in the axial direction Da. Therefore, in the present embodiment, as compared with the first and second embodiments, the stress generated at the base end 83 can be relaxed and the deformation of the shroud cover 60 can be further suppressed.

< fourth embodiment of bucket >

A rotor blade according to a third embodiment of the present invention will be described with reference to fig. 3, 11, and 12.

As shown in fig. 11 and 12, the bucket 50c of the present embodiment is a bucket in which the shape of the sealing fin 80 of the bucket 50 of the first embodiment is changed, and the other configurations are the same as those of the bucket 50 of the first embodiment. Fig. 11 is a sectional view taken along line XI-XI of fig. 3, and fig. 12 is a sectional view taken along line XII-XII of fig. 3. In the description of the bucket 50c of the present embodiment, fig. 3 showing the bucket 50 of the first embodiment is applied for convenience, and the seal fin 80 of the first embodiment is depicted in fig. 3. However, the shape of the seal fin 80c when the bucket 50c of the present embodiment is viewed from the radially outer side Dro is different from the shape of the seal fin 80 shown in fig. 3.

As shown in fig. 11 and 12, the sealing fin 80c of the present embodiment differs from the sealing fin 80 of the first embodiment only in the configuration of the inclined portion 88c of the offset portion 87. The inclined portion 88c of the present embodiment also goes toward the axial direction Da as going toward the radially inner side Dri, similarly to the inclined portion 88 of the first embodiment. However, in the inclined portion 88c of the present embodiment, the almost entire area from the tip end 84 to the base end 83 of the offset portion 87 forms an inclined portion. Therefore, the front surface 85 and the rear surface 86 of the offset 87 of the present embodiment extend substantially linearly from the tip 84 to the base end 83.

As described above, the inclined portion of the offset portion 87 may be formed in a part of the distal end 84 to the base end 83 of the offset portion 87, or may be formed in almost the entire portion of the distal end 84 to the base end 83 of the offset portion 87.

Although this embodiment is a modification of the first embodiment, the offset portion 87 of the second embodiment may have an inclined portion, which is similar to this embodiment, and may be formed almost entirely from the distal end 84 to the proximal end 83 of the offset portion 87.

< fifth embodiment of bucket >

A rotor blade according to a fifth embodiment of the present invention will be described with reference to fig. 3, 13, and 14.

As shown in fig. 13 and 14, the bucket 50d of the present embodiment is a bucket in which the shape of the shroud cover 60 of the bucket 50 of the first embodiment is changed, and the other configurations are the same as those of the bucket 50 of the first embodiment. It should be noted that fig. 13 is a sectional view taken along line XIII-XIII in fig. 3, and fig. 14 is a sectional view taken along line XIV-XIV in fig. 3.

The back gas passage surface 68 of the shroud cover 60 of each of the above embodiments has a concave surface recessed radially inward Dri. On the other hand, the counter gas passage surface 68d of the shroud cover 60d of the present embodiment is not a concave surface, but a flat surface.

As described above, the bucket 50d of the present embodiment is a bucket in which the shape of the shroud cover 60 of the bucket 50 of the first embodiment is changed, and the other configurations are the same as those of the bucket 50 of the first embodiment. Thus, the sealing fin 80 of the present embodiment also has the offset portion 87, similarly to the sealing fin 80 of the first embodiment. Therefore, in the present embodiment as well, as in the first embodiment, the weight increase of the shroud can be suppressed, and the deformation of the shroud cover 60d can be suppressed.

The present embodiment is a modification of the first embodiment, but the shroud cover of the second to fourth embodiments may have the same shape as that of the present embodiment.

< other modification example >

The thickness of the tip 84 of the sealing fin 80 shown in fig. 5 is substantially the same as the thickness of the intermediate portion between the tip 84 and the base end 83. The thickness of the base end 83 is greater than the thickness of the tip end 84 and the thickness of the intermediate portion. However, as shown in fig. 15, the thickness tfl of the tip 84 and the thickness tf3 of the base end 83 may be thicker than the thickness tf2 of the intermediate portion 89. By making the thickness tf3 of the base end 83 thicker than the thickness tf2 of the intermediate portion 89 in this way, the rigidity of the base end 83 of the sealing fin can be increased, and the sealing fin can be made lighter. In addition, the thickness tf2 of the middle portion 89 may be thicker than the thickness tfl of the tip 84, and the thickness tf3 of the base end 83 may be thicker than the thickness tf2 of the middle portion 89. As described above, the thickness of the seal fin at each position in the radial direction Dr can be appropriately changed. Further, the thickness of each position in the radial direction Dr of the seal fin may be appropriately changed at each position in the circumferential direction Dc of the seal fin.

The rotor blade having the structure described in the above embodiment is a rotor blade of a gas turbine. However, the rotor blade having the structure described in the above embodiment is not limited to the rotor blade of the gas turbine, and may be another axial flow rotary machine, for example, a rotor blade of a steam turbine.