KR102042505B1 - Turbine rotor and steam turbine comprising the same - Google Patents

Abstract

The present invention relates to a turbine rotor capable of centrifugally pressing a turbine blade without anxiety about damage and a steam turbine comprising the same. According to the present invention, the turbine rotor rotated by supplied steam comprises: a disc formed in a stream flowing direction, having a plurality of slots formed on the outer circumferential surface to be spaced apart in a circumferential direction, and having a separation prevention groove formed on the inner wall of the slot; a blade including a root member inserted into the slot and having an air foil installed on the outer end part of the root member with respect to the radial direction of the disc and passing steam; and a pressing unit including a support member installed on the inner end part of the root member, an insertion protrusion installed in the support member and preventing the root member from going out of the support member, and a wedge installed between the support member and the inner wall of the slot and inserted into the separation prevention groove to prevent the root member from going out of the disc.

Description

Turbine rotor and steam turbine comprising the same

The present invention relates to a turbine rotor and a steam turbine comprising the same, and more particularly, to a turbine rotor rotating by the supplied steam and a steam turbine comprising the same.

In general, the steam turbine refers to a device for rotating the shaft through the impulse or reaction by hitting the rotating turbine blades of the high temperature and high pressure steam generated in the boiler. To this end, the steam turbine is provided with a nozzle for converting the thermal energy of the steam into kinetic energy and a turbine blade for converting the kinetic energy of the high-speed steam passing through the nozzle into mechanical work.

The high temperature and high pressure steam supplied from the boiler enters the inlet of the steam turbine through the control valve, and then expands gradually through each stage of the turbine blade. As the turbine blades rotate by the steam passing through the inside, electricity is generated through a generator connected to the shaft of the steam turbine. The steam discharged through the steam turbine outlet is recovered and sent back to the cycle or discarded.

On the other hand, in order to prevent problems such as wear and damage that may occur between the turbine blades and the turbine disk during the low speed rotation of the turbine blade, the inner end of the turbine blade when the turbine blade is based on the radial direction The leaf spring is installed. Accordingly, the leaf spring allows the turbine blade to be pressed against the radial reference outside of the turbine disk to maintain a close contact when the turbine blade rotates at a low speed and the centrifugal force is weakly applied.

At this time, the plate spring used in the conventional steam turbine, there is a problem that is easily broken due to design errors or unexpected vibrations generated in the turbine blades. In addition, the conventional leaf spring, even when the turbine blade is made longer than the conventional along the flow direction of the steam, there is a problem that is easily damaged due to a large moment in the leaf spring during the low speed operation of the turbine blade.

In addition, in the case of the conventional steam turbine, in order to prevent the turbine blade from deviating in the axial direction of the turbine disk, a separate fixing member for securing the turbine blade to the turbine disk must be provided. Therefore, according to the conventional steam turbine, excessive effort and time are required when assembling the product, and excessive cost is required when the product is manufactured.

The present invention has been made to solve the above problems, the turbine blade can pressurize the turbine blade in the centrifugal direction without fear of damage, and the turbine rotor and steam containing the same can be assembled and manufactured more easily and inexpensively The purpose is to provide a turbine.

Turbine rotor according to an aspect of the present invention, in the turbine rotor that is rotated by the supplied steam, a plurality of slots are formed along the flow direction of the steam spaced apart from each other along the circumferential direction is formed on the outer peripheral surface, A disk having a separation preventing groove formed on an inner wall of the slot; A blade including a root member inserted into the slot and an air foil installed at an outer end of the root member when the radial direction of the disk is used, and through which steam passes; And a support member installed at an inner end of the root member, an insertion protrusion installed on the support member to prevent the root member from being separated from the support member, and installed between the support member and an inner wall of the slot. And a pressing portion including a wedge inserted into the prevention groove to prevent the root member from being separated from the disk.

According to another aspect of the present invention, in the steam turbine for generating power for generating power by passing the steam supplied therein, a stator including a casing and vanes installed on the inner circumferential surface of the casing to guide the flow of steam ; And a rotor installed inside the stator and rotating by the flowing steam, wherein the rotor is formed along the flow direction of the steam and is disposed on the outer circumferential surface with a plurality of slots disposed to be spaced apart from each other in the circumferential direction. And an airfoil through which steam passes through a disk having a separation preventing groove formed on an inner wall of the slot, a root member inserted into the slot, and an outer end of the root member based on a radial direction of the disk. A blade, a support member installed at an inner end of the root member, an insertion protrusion installed at the support member to prevent the root member from being separated from the support member, and between the support member and the inner wall of the slot. A web installed in the separation preventing groove to prevent the root member from being separated from the disk. The steam turbine is provided including a pressure containing (Wedge).

The root member, the insertion groove is formed in the inner end when the radial direction of the disk as a reference, the insertion projection is formed on the outer surface of the support member can be inserted into the insertion groove.

When the surface on the side adjacent to the wedge is the adjacent surface among the surfaces on the downstream side and the upstream side of the disk when the flow direction of the steam is referenced, the wedge is based on the radial direction of the disk. It is installed on the inside of the support member when pressed to press the support member and the root member to the outside, the separation preventing groove is formed to face the inside of the slot from the adjacent surface, the inside of the wedge It may be formed in the inner wall portion of the corresponding slot.

The release preventing groove, the inner wall portion in contact with the inner surface of the wedge may be formed to be inclined relative to the inner end of the root member.

The release preventing groove may be formed such that an inner wall portion in contact with the inner surface of the wedge is inclined toward the radial reference inner side of the disk from the inside of the slot toward the adjacent surface.

When the surface on the side adjacent to the wedge is the adjacent surface among the surfaces on the downstream side and the upstream side of the disk when the flow direction of the steam is a reference, the support member has an edge on the side of the adjacent surface. It may be bent to cover the wedge.

The departure preventing grooves are each formed at a downstream side portion and an upstream side portion of the inner wall of the slot when the flow direction of the steam is a reference, and the pressing portion corresponds to a position where the pair of departure prevention grooves are formed. It may be provided in a pair to make.

According to the turbine rotor and the steam turbine including the same according to the present invention, by providing a pressing portion between the turbine blade and the turbine disk, it is possible to pressurize the turbine blade in the centrifugal direction. Further, according to the turbine rotor and the steam turbine including the same according to the present invention, the pressing portion includes a support member installed inside the blade, and a wedge interposed between the supporting member and the turbine disk, the pressing portion is conventionally plate spring Compared to the one provided in the form, the turbine blade can be pressed in the centrifugal direction without fear of damage.

In addition, according to the turbine rotor and the steam turbine including the same according to the present invention, the wedge is installed so as to be inserted into the separation prevention groove formed in the inner wall of the slot, so that the turbine blade is axially oriented from the turbine disk without having a separate fixing member. It is possible to prevent the departure. Accordingly, according to the turbine rotor and the steam turbine including the same according to the present invention, it is possible to assemble and manufacture the product more easily and inexpensively.

1 is a cross-sectional view showing a schematic structure of a steam turbine to which an embodiment of the present invention is applied.
FIG. 2 is an exploded perspective view illustrating the turbine rotor of FIG. 1.
3 is a view showing a state in which the pressing unit is installed in the turbine rotor shown in FIG.
4 is a bottom view of the root member shown in FIG. 2.
5 is a perspective view showing a pressurization unit of the steam turbine according to the first embodiment of the present invention.
6 is a perspective view illustrating a pressurization unit of a steam turbine according to a second embodiment of the present invention.
7 is a cross-sectional view of the turbine rotor of the steam turbine according to the present invention cut along the flow direction of the steam.

Although the present invention has been described with reference to the embodiments shown in the drawings, this is merely exemplary, and it will be understood by those skilled in the art that various modifications and equivalent other embodiments are possible. Therefore, the true technical protection scope of the present invention will be defined by the technical spirit of the appended claims.

Hereinafter, embodiments of the steam turbine 100 including the turbine rotor 1000 according to the present invention will be described with reference to the drawings.

Referring to FIG. 1, the steam turbine 100 receives a turbine vane 112 and a turbine rotor 1000 inside a turbine casing 111. The turbine vane 112 and the turbine rotor 1000 are arranged in a multi-stage along the flow direction of the steam. At this time, the steam turbine 100 is designed to expand the steam from the inlet to the outlet, the inner space is increased from the front end to the rear end.

The turbine rotor 1000 includes a turbine disk 1100 and a plurality of turbine blades 1200 disposed radially therefrom. Between the turbine blades 1200, a plurality of turbine vanes 112 are provided in an annular manner in the turbine casing 111 when the same stage is used, and the turbine vanes 112 are turbine blades 1200. It guides the flow direction of steam passing through). In this case, the turbine casing 111 and the turbine vane 112 may be defined under the generic name of the turbine stator 110 to distinguish the turbine rotor 1000.

Referring to FIG. 2, the turbine disk 1100 has a disk shape and a plurality of turbine disk slots 1110 are formed on an outer circumferential surface thereof. The turbine blade 1200 is installed outside the radial direction R of the turbine disk 1100, and includes a root member 1210 inserted into the turbine disk slot 1110 and the turbine of the root member 1210. The disk 1100 includes a platform 1230 coupled to the outside of the radial direction R, and an airfoil 1220 coupled to the outside of the platform 1230 and rotating by steam.

The platform 1230 is disposed at a central portion of the turbine blade 1200 to fix the air foil 1220 to the root member 1210. In addition, the platform 1230 serves to maintain the distance between the turbine blades 1200 in contact with the adjacent platform 1230 and the side thereof. In this case, although the platform 1230 is illustrated as having a planar shape in FIG. 2, this is only an embodiment of the present invention, and the shape of the platform 1230 may be variously formed.

The bottom surface of the platform 1230 is provided with a root member 1210 that is fastened to the disk slot 1110. The root member 1210 is formed to correspond to the shape of the curved surface formed in the disk slot 1110, which may be selected according to the required structure of the commercially available steam turbine 100, commonly known dovetail or fir It may have a form (Fir-tree).

A fastening method of the root member 1210 may include a tangential type inserted into the turbine disk slot 1110 along a tangential direction of an outer circumferential surface of the turbine disk 1100, and the turbine disk slot 1110. Is an axial type inserted along the axial direction of the turbine disk 1100. In some cases, the turbine blade 1200 may be fastened to the turbine disk 1100 using a fastener such as a key or a bolt other than the above-described configuration.

An airfoil 1220 is provided on an upper surface of the platform 1230. The air foil 1220 is formed to have an airfoil optimized according to the specifications of the steam turbine, the leading edge disposed on the upstream side and the trailing edge disposed on the downstream side based on the flow direction of the steam (Trailing) edge).

Hereinafter, the pressurizing unit 1300 and the configuration corresponding to the pressurizing unit 1300 included in the turbine rotor 1000 (hereinafter, referred to as a rotor) according to the present invention will be described in detail with reference to FIGS. 3 to 8. . In this case, the turbine disk 1100 (hereinafter referred to as a disk), the turbine blade 1200 (hereinafter referred to as a blade) and the pressing unit 1300 are based on the radial direction R of the disk 1100. In each case, a side far from the center of the disk 1100 is referred to as an outer side, and a side close to the center of the disc 1100 is defined as an inner side. In addition, the disk 1100 is a wedge 1330 which will be described later, among the surfaces on the downstream side and the upstream side of the disk 1100 when the flow direction G of the steam is a reference. The side of the side adjacent to Wedge is defined as the adjacent surface 1120.

Referring to FIG. 3, the pressing unit 1300 is installed between an inner end of the root member 1210 and an inner wall of the turbine disk slot 1110 (hereinafter referred to as a slot). The pressing unit 1300 presses the root member 1210 to the outside to firmly fix the root member 1210 in the outward direction. Accordingly, the pressurizing unit 1300 may wear out the inner wall and the wear of the slot 1110 as the root member 1210 vibrates along the inner-outer direction during the low speed operation of the steam turbine 100. To prevent it.

On the inner wall of the slot 1100, a departure prevention groove 1130 is formed. The departure preventing groove 1130 is formed to face an interior part of the slot 1110 from the adjacent surface 1120. The departure preventing groove 1130 is formed at an inner wall portion of the slot 1100 facing the inner end of the root member 1210.

Referring to FIG. 4, the root member 1210 may have a pair of insertion grooves 1211 formed at an inner end thereof. The pair of insertion grooves 1211 may be arranged to be spaced apart from each other along the flow direction (G) of the steam. The pair of insertion grooves 1211 may be formed to be adjacent to the surface on the downstream side and the surface on the upstream side of the root member 1210 when the flow direction G of the steam is a reference. .

The pressing unit 1300 may be provided in a pair to correspond to a position where the pair of insertion grooves 1211 are formed. In addition, the separation preventing grooves 1130 may also be provided in pairs, each formed in the inner wall portion of the slot 1110 at the position where the pressing unit 1130 is installed. In this case, the pair of pressing parts 1300 may be disposed to be symmetrical with respect to each other based on a radial direction R of the disk 1100 penetrating the center portion of the slot 1110.

The pressing unit 1300 is installed in the separation preventing groove 1130 to prevent the root member 1210 from being separated in the axial direction of the disk 1100 and is inserted into the insertion groove 1211. It is installed to prevent the root member 1210 from being separated in the axial direction of the disk 1100 from the pressing portion 1300. To this end, the pressing unit 1300, the support member 1310, the insertion protrusion 1320 and the wedge (1330; Wedge) includes.

Hereinafter, the pressurizing portion 1300a of the steam turbine 100 according to the first embodiment of the present invention will be described in detail with reference to FIG. 5.

The support member 1310a is provided at an inner end of the root member 1210. The insertion protrusion 1320a is formed to protrude from an outer surface of the support member 1310a and is inserted into the insertion groove 1211. Accordingly, the insertion protrusion 1320a prevents the root member 1210 from being separated from the pressing part 1300a in the axial direction of the disc 1100. The wedge 1330a is interposed between an inner surface of the support member 1310a and an inner wall of the slot 1110 to press the support member 1310a and the root member 1210 to the outside. The wedge 1330a is inserted into the separation preventing groove 1130 to prevent the root member 1210 from being separated in the axial direction of the disk 1100 from the disk 1100.

The support member 1310a may be bent inwardly so that the end portion of the adjacent surface 1120 side covers the wedge 1330a. Accordingly, the support member 1310a prevents the wedge 1330a from being separated in the axial direction of the disk 1100.

Hereinafter, the pressurizing portion 1300b of the steam turbine 100 according to the second embodiment of the present invention will be described in detail with reference to FIG. 6.

The support member 1310b is provided at an inner end of the root member 1210. In this case, the support member 1310b may include a sheet 1311 and a block 1312. The sheet 1311 has the insertion protrusion 1320b formed on an outer surface thereof. The sheet 1311 contacts the inner end of the root member 1210 such that the insertion protrusion 1320b is inserted into the insertion groove 1211. The block 1312 is provided to contact the inner surface of the sheet 1311. Accordingly, the block 1312 prevents abrasion, damage, and the like, which may be caused by the direct friction between the sheet 1311 and the wedge 1330b.

The wedge 1330b is interposed between an inner surface of the block 1312 and an inner wall of the slot 1110 to press the sheet 1311, the block 1312, and the root member 1210 outward. do. The wedge 1330b is inserted into the separation preventing groove 1130 to prevent the root member 1210 from being separated from the disk 1100 in the axial direction of the disk 1100.

The sheet 1311 may be bent inwardly such that an end portion of the side of the adjacent surface 1120 covers the block 1312 and the wedge 1330b. Accordingly, the support member 1310b prevents the block 1312 and the wedge 1330b from being separated in the axial direction of the disk 1100.

Meanwhile, referring to FIGS. 4 and 7, the separation preventing groove 1130 may have an inner wall portion contacting the inner surface of the wedge 1330 to be inclined with respect to the inner end of the root member 1210. Can be. In more detail, the separation prevention groove 1130 may have an inner wall portion in contact with an inner surface of the wedge 1330 from the inside of the slot 1110 toward the adjacent surface 1120. It may be formed to be inclined inward with respect to the radial direction of (R). The wedge 1330 is also formed such that the inner surface of the wedge 1330 is inclined inward with respect to the outer surface of the wedge 1330 from the inside of the slot 1110 toward the adjacent surface 1120. Can be.

In this case, the root member 1210 and the pressing unit 1300 can be prevented from being separated in the axial direction of the disk 1100. That is, based on FIG. 7, when the root member 1210 and the pressurizing portion 1300 are forced to the left side (upstream side of the steam flow direction G), the right side (vapor flow direction G) The inner wall of the separation preventing groove 1130 disposed on the downstream side of the role of the stopper for the pressing portion 1300. In addition, when the root member 1210 and the pressurizing portion 1300 are forced to the right side (downstream side of the steam flow direction G), the left side (upstream side of the steam flow direction G) is disposed The inner wall of the separation prevention groove 1130 also serves as a stop against the pressing unit 1300.

Accordingly, the steam turbine 100 of the present invention, even if there is no separate fixing member for fixing the root member 1210 to the disk 1100, the root member 1210 through the pressing unit 1300 is Deviation from the disk 1100 in the axial direction can be prevented. Therefore, according to the steam turbine 100 according to the present invention, the design is easy, it is possible to reduce the manufacturing cost of the product.

In FIG. 7, a portion of the inner wall of the slot 1110 formed between the pair of pressing portions 1300 and facing the inner end of the root member 1210 is the root member 1210. Although shown as parallel to the inner end of the), this is merely exemplary. An inner wall portion of the slot 1110 formed between the pair of pressing portions 1300 is formed to protrude toward the root member 1210 and has a separate protrusion to serve as a bump for the pressing portion 1300. It may be said that the shape (not shown) may be formed.

100: steam turbine 110: stator
111: casing 112: vane
1000: rotor 1100: disc
1200 blade 1300 pressing part

Claims (14)

In a turbine rotor rotating by supplied steam,
A disk having a plurality of slots formed along the flow direction of the steam and spaced apart from each other in the circumferential direction, the disc having a separation preventing groove formed on an inner wall of the slot;
A blade including a root member inserted into the slot and an air foil installed at an outer end of the root member when the radial direction of the disk is used, and through which steam passes; And
A support member installed at an inner end of the root member, an insertion protrusion installed on the support member to prevent the root member from being separated from the support member, and installed between the support member and an inner wall of the slot and preventing the detachment. It includes a pressing portion including a wedge (Wedge) is inserted into the groove to prevent the root member from being separated from the disk,
When the surface on the side adjacent to the wedge is the adjacent surface among the surfaces on the downstream side and the upstream side of the disk when the flow direction of the steam is referenced,
The support member,
A sheet bent such that the proximal side end thereof covers the wedge;
And a block installed to be in contact with an inner surface of the seat and preventing a friction between the seat and the wedge. The method according to claim 1,
The root member, the insertion groove is formed at the inner end when the radial direction of the disk as a reference,
The insertion protrusion, the turbine rotor is formed on the outer surface of the support member is inserted into the insertion groove. The method according to claim 1,
When the surface on the side adjacent to the wedge is the adjacent surface among the surfaces on the downstream side and the upstream side of the disk when the flow direction of the steam is referenced,
The wedge is provided on the inside of the support member when the radial direction of the disk as a reference to press the support member and the root member to the outside,
The departure preventing groove is formed to face the inside of the slot from the adjacent surface, the turbine rotor formed in the inner wall portion of the slot corresponding to the inside of the wedge. The method according to claim 3,
The separation prevention groove, the turbine rotor in which the inner wall portion in contact with the inner surface of the wedge is inclined relative to the inner end of the root member. The method according to claim 4,
The separation prevention groove, the turbine rotor is formed such that the inner wall portion in contact with the inner surface of the wedge is inclined toward the radial reference inner side of the disk toward the adjacent surface side from the inside of the slot. delete The method according to any one of claims 1 to 5,
The departure preventing grooves are formed one each in the downstream side portion and the upstream side portion of the inner wall of the slot, based on the flow direction of the steam,
The pressurizing part is provided with a pair of turbine rotors to correspond to the position where the pair of departure prevention grooves are formed. In the steam turbine which passes the supplied steam to the inside to generate power for power generation,
A stator installed on the inner circumferential surface of the casing and including a vane for guiding the flow of steam; And
Is installed inside the stator, including a rotor that rotates by the flowing steam,
The rotor is,
A disk having a plurality of slots formed along the flow direction of the steam and spaced apart from each other in a circumferential direction, the disk having a departure preventing groove formed on an inner wall of the slot;
A blade including a root member inserted into the slot, an airfoil installed at an outer end of the root member when the radial direction of the disk is used, and steam passes therethrough;
A support member installed at an inner end of the root member, an insertion protrusion installed on the support member to prevent the root member from being separated from the support member, and installed between the support member and an inner wall of the slot and preventing the detachment. It includes a pressing portion including a wedge (Wedge) is inserted into the groove to prevent the root member from being separated from the disk,
When the surface on the side adjacent to the wedge is the adjacent surface among the surfaces on the downstream side and the upstream side of the disk when the flow direction of the steam is referenced,
The support member,
A sheet bent such that the proximal side end thereof covers the wedge;
The steam turbine is installed to be in contact with the inner surface of the seat, comprising a block for preventing friction between the seat and the wedge. The method according to claim 8,
The root member, the insertion groove is formed at the inner end when the radial direction of the disk as a reference,
The insertion protrusion is formed on the outer surface of the support member and the steam turbine is inserted into the insertion groove. The method according to claim 8,
When the surface on the side adjacent to the wedge is the adjacent surface among the surfaces on the downstream side and the upstream side of the disk when the flow direction of the steam is referenced,
The wedge is provided on the inside of the support member when the radial direction of the disk as a reference to press the support member and the root member to the outside,
The departure prevention groove is formed to face the inside of the slot from the adjacent surface, the steam turbine formed in the inner wall portion of the slot corresponding to the inside of the wedge. The method according to claim 10,
The separation prevention groove is a steam turbine in which the inner wall portion in contact with the inner surface of the wedge is inclined with respect to the inner end of the root member. The method according to claim 11,
The departure prevention groove is a steam turbine formed so that the inner wall portion in contact with the inner surface of the wedge toward the adjacent surface side from the inside of the slot, inclined inward to the radial reference of the disk. delete The method according to any one of claims 8 to 12,
The departure preventing grooves are formed one each in the downstream side portion and the upstream side portion of the inner wall of the slot, based on the flow direction of the steam,
The pressurization unit is provided with a pair of steam turbines corresponding to the position where the pair of departure prevention grooves are formed.

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