KR102153013B1 - Rotating parts, method of manufacturing the same and steam turbine including the same - Google Patents

Abstract

The present invention relates to a rotor, a method for manufacturing a rotor for manufacturing the same, and a steam turbine including the same, comprising: a rotor provided to be rotatable; And n buckets fastened to the rotor to convert energy of the steam injected from the nozzle into mechanical work, wherein the n buckets are fastened to the rotor in a tangential entry method, and the n All of the three buckets may be formed to be supported by the rotor. Thereby, the bucket can be stably fastened to the rotor.

Description

A rotating body, a method of manufacturing a rotating body for manufacturing the same, and a steam turbine including the same TECHNICAL FIELD [ROTATING PARTS, METHOD OF MANUFACTURING THE SAME AND STEAM TURBINE INCLUDING THE SAME}

The present invention relates to a rotor, a method for manufacturing a rotor for manufacturing the same, and a steam turbine including the same, and more particularly, in a so-called tangential entry method in which a bucket is inserted along the circumferential direction of the rotor. A rotating body capable of stably fastening a bucket to a rotor when fastened to a rotor, a rotating body manufacturing method for manufacturing the same, and a steam turbine including the same.

In general, a turbine is a machine that converts the energy of a fluid such as water, gas, steam, etc. into mechanical work. Usually, a turbo-type machine that rotates at high speed by planting several blades or blades on the circumference of a rotating body and spraying steam or gas there. Is called a turbine.

Types of such turbines include a hydraulic turbine that uses the energy of high water, a steam turbine that uses the energy of steam, a gas turbine that uses the energy of high-temperature and high-pressure gas, and the energy of high-pressure compressed air. And air turbines.

Among them, the steam turbine is formed to convert the energy of the steam into mechanical work by rotating the rotor by ejecting the steam from the nozzle and hitting the blade.

Specifically, the steam turbine includes a casing that forms the outer shape and skeleton of the turbine, a rotating body rotatably installed in the casing, and a nozzle for injecting steam to the rotating body.

Korean Patent Publication No. 10-1376716 discloses a conventional rotating body and a steam turbine including the same.

Referring to Korean Registered Patent Publication No. 10-1376716, a conventional rotating body is fastened to the rotor to convert the energy of steam injected from a rotor and nozzle (not shown) to be rotatably provided into mechanical work. It includes n buckets (10, 11, 12).

Here, the n buckets 10, 11, 12 are fastened to the rotor 1 in a so-called tangential entry method.

Specifically, the rotor is formed in a disk shape, and a tangential entry 4 serving as an entrance and exit of the bucket is formed on one side of the outer circumference of the rotor, and the buckets 10 and 11 are supported on the other side of the outer circumference of the rotor. A circumferential dovetail protrusion 3 is formed extending from the tangential entry 4 along the circumferential direction of the rotor. Here, the circumferential dovetail protrusion 3 is disconnected by the tangential entry 4.

Each of the n buckets (10, 11, 12) has a root portion having a circumferential dovetail groove (10a, 11a, 12a) engageable with the circumferential dovetail projection (3), and a rotational radial direction of the rotor from the root portion. It includes a wing protruding into.

On the other hand, the n-th bucket 12, which is a final bucket, is not supported by the circumferential dovetail protrusion 3 because it is inserted only into the tangential entry 4, and is supported by a separate pin 13 . Specifically, a first pin hole forming a first pin hole into which the first pin 13 is inserted together with a third groove 10b to be described later on one side of the root portion of the n-th bucket 12 in the circumferential direction of the rotor A second groove 12b is formed and forms a second pin hole into which the second pin 13 is inserted together with a fourth groove 11b to be described later in the other side of the root portion of the n-th bucket 12 ( 12c) is formed. In addition, a third groove 10b forming a first pin hole together with the first groove 12c is formed in a root portion of the first bucket 10 adjacent to the n-th bucket 12. In addition, the second groove 12c is provided in the root portion of the n-1th bucket 11 adjacent to the nth bucket 12 on the opposite side of the first bucket 10 based on the nth bucket 12. ) And a fourth groove 11b forming a second pin hole is formed. According to this configuration, the n-th bucket 12 is supported by the first bucket 10 at one side of the n-th bucket 12 through the first pin 13 and the first pin hole, The other side of the nth bucket 12 is supported by the n-1th bucket 11 through the second pin 13 and the second pin hole.

A conventional rotating body according to this configuration is manufactured as follows.

That is, the first to n-1th buckets 10 and 11 are connected to the rotor through the circumferential dovetail grooves 10a and 11a, the tangential entry 4 and the circumferential dovetail protrusion 3 of each bucket. It is sequentially assembled with the rotor by being inserted in the circumferential direction of.

Then, the n-th bucket 12, which is a final bucket, is inserted into the tangential entry 4.

Then, the first pin 13 is inserted into the first pin hole, and the second pin 13 is inserted into the second pin hole.

However, in such a conventional rotating body, a method of manufacturing a rotating body for manufacturing the same, and a steam turbine including the same, there is a problem that the bucket is not stably fastened to the rotor. That is, the n-th bucket 12 is not supported by the circumferential dovetail protrusion 3, but is supported by the first bucket 10 and the n-1th bucket 11, so that the first bucket 10 ) And the fastening portion between the rotor and the n-1th bucket 11 and the rotor, a significant load is applied to the fastening portion, and damage is generated, so that the bucket is separated from the rotor. In addition, there is a problem that a considerable load is applied to the first pin 13, the first pin hole, the second pin 13, and the second pin hole, and damage is caused, so that the bucket is separated from the rotor. . In addition, there is a problem that the n-th bucket 12 is moved in the axial direction of the rotor and is separated from the rotor. And, during operation, the n buckets (10, 11, 12) are rotated relative to the rotor along the circumferential direction of the rotor, so that the energy of the steam cannot be completely converted into mechanical work, and the efficiency is reduced. there was.

Korean Patent Publication No. 10-1376716

Accordingly, an object of the present invention is to provide a rotating body in which a bucket can be stably fastened to a rotor, a rotating body manufacturing method for manufacturing the same, and a steam turbine including the same.

The present invention, in order to achieve the object as described above, the rotor (rotor) provided to be rotatable; And n buckets fastened to the rotor to convert the energy of the steam injected from the nozzle into mechanical work, wherein the n buckets are fastened to the rotor in a tangential entry method, It provides a rotating body, characterized in that all of the n buckets are supported by the rotor.

In the tangential entry of the rotor, the n buckets as a whole are moved along the circumferential direction of the rotor, so that a part of the tangential entry is part of one of the n buckets and the axial and radial directions of the rotor. And the rest of the tangential entry may overlap a portion of the bucket adjacent to the one bucket in the axial and radial directions of the rotor.

The rotor may include a rotor wheel having the tangential entry; And a converter filling the tangential entry.

The converter may be formed to be coupled to the rotor wheel by moving along the axial direction of the rotor.

The rotor wheel includes an axial dovetail groove engraved radially inward of the rotor from the tangential entry and extending along the axial direction of the rotor, and the converter is an axial dovetail engaged with the axial dovetail groove. May include projections.

The rotor wheel includes a first circumferential dovetail protrusion extended in a circumferential direction of the rotor from the tangential entry and cut off by the tangential entry, and the converter fills the cut-off portion of the first circumferential dovetail protrusion. It may include a second circumferential dovetail protrusion.

The first circumferential dovetail protrusion and the second circumferential dovetail protrusion may form one annular dovetail protrusion.

The second circumferential dovetail protrusion may be formed to support at least one of the n buckets.

Each bucket may include a root portion having a circumferential dovetail groove engaged with some of the one annular dovetail protrusion; And a wing portion protruding from the root portion in a radial direction of rotation of the rotor.

On the circumferential direction of the rotor, the length of the tangential entry, the length of the second circumferential dovetail protrusion, the length of the root portion, and the length of the circumferential dovetail groove may all be the same.

The first to n-1th buckets are inserted in the circumferential direction of the rotor through a circumferential dovetail groove of each bucket, a tangential entry of the rotor wheel, and a first circumferential dovetail protrusion of the rotor wheel. Sequentially assembled, the n-th bucket is assembled with the converter through the circumferential dovetail groove of the n-th bucket and the second circumferential dovetail protrusion of the converter, and the converter assembled with the n-th bucket is in the tangential entry. By being inserted in the axial direction of the rotor, the first bucket to the n-1 th bucket and the assembled rotor wheel are assembled, and the first to the n-1 th bucket assembled to the rotor wheel and the converter assembled The n-th bucket as a whole is moved to a predetermined position along the circumferential direction of the rotor, so that a contact portion between the first circumferential dovetail protrusion and the second circumferential dovetail protrusion is an axis of the n-1 th bucket and the rotor. The other contact portions between the first circumferential dovetail protrusion and the second circumferential dovetail protrusion overlap in a direction and a radial direction, and may overlap in the axial and radial directions of the n-th bucket and the rotor.

When the length of the root portion in the circumferential direction of the rotor is one pitch, the predetermined position is the first to n-1th bucket assembled to the rotor wheel and the first to the n-1th bucket assembled to the converter. The n bucket may be a position moved along the circumferential direction of the rotor by a half pitch as a whole.

It may include a fixing means for fixing the first to the nth bucket to the predetermined position.

The fixing means includes: a first pin hole formed in the first circumferential dovetail protrusion or the second circumferential dovetail protrusion; A second pin hole formed in the bucket and facing the first pin hole when the first to n-th buckets are positioned at the predetermined position; And a pin inserted into the first pin hole and the second pin hole.

The first pin hole is formed through the second circumferential dovetail protrusion along the axial direction of the rotor from the circumferential center side of the second circumferential dovetail protrusion, and the second pin hole is the n-1 th It may be formed between the root portion of the bucket and the root portion of the n-th bucket along the axial direction of the rotor, passing through the root portion of the n-1th bucket and the root portion of the nth bucket.

And, the present invention, the first step of having the rotor and the n buckets; The rotor includes a rotor wheel having the tangential entry and a converter filling the tangential entry, and sequentially passes a first bucket to an n-1 th bucket in a circumferential direction of the rotor through a tangential entry of the rotor wheel. A second step of assembling with the rotor wheel by inserting; A third step of assembling the nth bucket with the converter; A fourth step of inserting the converter assembled with the nth bucket into the tangential entry in the axial direction of the rotor and assembling the first to n-1th buckets and the assembled rotor wheel; A fifth step of moving the first to n-1th buckets assembled to the rotor wheel and the nth buckets assembled to the converter by a half pitch along the circumferential direction of the rotor as a whole; And a sixth step of fixing the n buckets by inserting a pin into a first pin hole formed in the rotor and a second pin hole formed in the bucket.

And, the present invention, the casing; The rotating body rotatably provided in the casing; And it provides a steam turbine including a nozzle for injecting steam to the rotating body.

A rotor according to the present invention, a rotor manufacturing method for manufacturing the same, and a steam turbine including the same, includes a rotor provided to be rotatable; And n buckets fastened to the rotor to convert the energy of the steam injected from the nozzle into mechanical work, wherein the n buckets are fastened to the rotor in a tangential entry method, , All of the n buckets may be formed to be supported by the rotor. Thereby, the bucket can be stably fastened to the rotor.

1 is a front view showing a rotating body and a steam turbine including the same according to an embodiment of the present invention,
Figure 2 is a flow chart showing a method for manufacturing a rotating body for manufacturing the rotating body of Figure 1,
3 is a perspective view showing a second step in the method of manufacturing the rotating body of FIG. 2;
4 is a perspective view showing a third step in the method of manufacturing the rotating body of FIG. 2;
5 is a perspective view showing a fourth step in the method of manufacturing the rotating body of FIG. 2;
6 is a front view showing a fifth step in the method of manufacturing the rotating body of FIG. 2;
7 is a perspective view showing a sixth step in the method of manufacturing the rotating body of FIG. 2;
8 is a perspective view showing a rotating body manufactured by the method of manufacturing the rotating body of FIG. 2.

Hereinafter, a rotor according to the present invention, a method for manufacturing a rotor for manufacturing the same, and a steam turbine including the same will be described in detail with reference to the accompanying drawings.

1 is a front view showing a rotor and a steam turbine including the same according to an embodiment of the present invention, FIG. 2 is a flow chart showing a method of manufacturing a rotor for manufacturing the rotor of FIG. 1, and FIG. 3 is FIG. 2 is a perspective view showing a second step in the method of manufacturing a rotating body of FIG. 2, FIG. 4 is a perspective view showing a third step in the method of manufacturing a rotating body of FIG. 2, and FIG. A perspective view showing the steps, FIG. 6 is a front view showing the fifth step in the method of manufacturing the rotating body of FIG. 2, FIG. 7 is a perspective view showing the sixth step in the manufacturing method of the rotating body of FIG. 2, and FIG. It is a perspective view showing a rotating body manufactured by the rotating body manufacturing method of FIG. 2.

Referring to the accompanying Figures 1 to 8, the steam turbine according to an embodiment of the present invention, a casing 100 forming the outer shape and skeleton of the turbine, a rotor rotatably installed inside the casing 100 It may include a nozzle (not shown) for injecting steam to the entire 300 and 400 and the rotating bodies 300 and 400.

Among these, the rotors 300 and 400 are fastened to the rotor 300 to convert energy of the steam injected from a rotor 300 and a nozzle (not shown) provided to be rotatable into mechanical work. It may include n buckets 400.

Further, the n buckets 400 may be fastened to the rotor 300 in a so-called tangential entry method, and all of the n buckets 400 may be formed to be supported by the rotor 300.

Specifically, the rotor 300 includes a rotor wheel 310 having a tangential entry 312 serving as an entrance of the bucket 400 and a converter 320 filling the tangential entry 312, The rotor wheel 310 and the converter 320 coupled to each other may be formed as a whole in a disk shape.

The rotor wheel 310 extends in the circumferential direction of the rotor 300 from the tangential entry 312 and the tangential entry 312 formed in a slot on one side of the outer circumference of the rotor wheel 310 The first circumferential dovetail protrusion 314 disconnected by the tangential entry 312 and the tangential entry 312 are engraved radially inward of the rotor 300 and the axial direction of the rotor 300 is It may include an axial dovetail groove 316 extending along.

The tangential entry 312 is a portion that becomes an entrance and exit of the bucket 400 so that the bucket 400 is inserted and fastened along the circumferential direction of the rotor 300, as described above, and a route to be described later of the bucket 400 The tangential entry 312 may have a circumferential length equal to the circumferential length of the root portion 410 so that the portion 410 can enter and exit the tangential entry 312. At this time, the circumferential direction means the circumferential direction of the rotor 300.

Here, the tangential entry 312 may be formed to have a size in which a plurality of buckets 400 can enter and enter the tangential entry 312 at the same time, but the first circumferential dovetail by the tangential entry 312 In order to minimize the increase in the cut-off portion of the protrusion 314, it may be desirable to form one bucket 400 at a time in a size that allows access to the tangential entry 312 as in the present embodiment.

The first circumferential dovetail protrusion 314 may form one annular dovetail protrusion R formed on the outer periphery of the rotor 300 together with a second circumferential dovetail protrusion 324 to be described later. Here, the one annular dovetail protrusion R is the n buckets 400 when the n buckets 400 are moved along the circumferential direction of the rotor 300 together with a circumferential dovetail groove 412 to be described later. ) Not only to guide the movement, but also to prevent the n buckets 400 from being separated from the rotor 300 in the axial and radial directions of the rotor 300 and to support the n buckets 400 Can play a role.

In addition, the first circumferential dovetail protrusion 314 is formed of the rotor 300 so that the bucket 400 inserted through the tangential entry 312 is movable along the circumferential direction of the rotor 300. A cross section perpendicular to the circumferential direction may be formed uniformly.

In addition, the first circumferential dovetail protrusion 314 has a bucket 400 fastened to the first circumferential dovetail protrusion 314 from the first circumferential dovetail protrusion 314 to the radius of the rotor 300 In order to prevent deviation in the direction, it may include at least one raised portion raised in the axial direction of the rotor 300 and at least one settled portion settled in the axial direction of the rotor 300.

The axial dovetail groove 316 not only allows the converter 320 to move along the axial direction of the rotor 300 together with an axial dovetail protrusion 326 to be described later to be fastened to the rotor wheel 310 , The converter 320 may be formed to prevent separation from the rotor wheel 310 in the circumferential direction and radial direction of the rotor 300 and to support the converter 320.

That is, in the axial dovetail groove 316, the axial dovetail protrusion 326 to be described later of the converter 320 inserted into the axial dovetail groove 316 moves along the axial direction of the rotor 300 To be possible, a cross section perpendicular to the axial direction of the rotor 300 may be formed uniformly.

And, the axial dovetail groove 316, the converter 320 fastened to the axial dovetail groove 316 is separated from the axial dovetail groove 316 in the radial direction of the rotor 300 To prevent, at least one raised portion raised in the circumferential direction of the rotor 300 and at least one settled portion settled in the circumferential direction of the rotor 300 may be included.

The converter 320 includes a second circumferential dovetail protrusion 324 and the axial dovetail groove 316 not only filling the tangential entry 312, but also filling the disconnected portion of the first circumferential dovetail protrusion 314. ) May include an axial dovetail protrusion 326 that meshes.

The second circumferential dovetail protrusion 324 may be formed to form the annular dovetail protrusion R together with the first circumferential dovetail protrusion 314 as described above.

That is, the second circumferential dovetail protrusion 324 has a uniform cross section perpendicular to the circumferential direction of the rotor 300 so that the bucket 400 can move along the circumferential direction of the rotor 300 Can be.

In addition, the second circumferential dovetail protrusion 324 is a bucket 400 fastened to the second circumferential dovetail protrusion 324 from the second circumferential dovetail protrusion 324 to the radius of the rotor 300 In order to prevent deviation in the direction, it may include at least one raised portion raised in the axial direction of the rotor 300 and at least one settled portion settled in the axial direction of the rotor 300.

Here, the second circumferential dovetail protrusion 324 has at least one raised portion and at least one settling portion similar to the first dovetail protrusion to support at least one bucket 400 of the n buckets 400. Can be formed. That is, the second circumferential dovetail protrusion 324 may be formed by a portion of the n-1th bucket 400n-1 and the nth bucket ( 400n) may be supported, or, unlike the present embodiment, when the n buckets 400 are not entirely moved by half pitch, one of the n buckets 400 may be supported. .

Meanwhile, the second circumferential dovetail protrusion 324 may be formed to have a size capable of filling the tangential entry 312. That is, the circumferential length of the second circumferential dovetail protrusion 324 may be formed at a level equal to the circumferential length of the tangential entry 312.

The axial dovetail protrusion 326 has a constant cross section perpendicular to the axial direction of the rotor 300 so as to be able to engage with the axial dovetail groove 316, and is raised in the circumferential direction of the rotor 300. It may include at least one raised portion and at least one settled portion settled in the circumferential direction of the rotor 300.

Each of the n buckets 400 includes a root portion 410 fastened to the rotor 300 and a wing portion 420 protruding from the root portion 410 in a radial direction of rotation of the rotor 300. I can.

The root part 410 includes a circumferential dovetail groove 412 engaged with a part of the one annular dovetail protrusion R, and a platform 414 forming the exterior of the circumferential dovetail groove 412. I can.

The circumferential dovetail groove 412 has a uniform cross section perpendicular to the circumferential direction of the rotor 300 so as to be able to engage with the one annular dovetail protrusion R, and the axial elevation of the rotor 300 It may include at least one raised portion and at least one settled portion settled in the axial direction of the rotor 300.

In addition, the circumferential dovetail groove 412 may have a circumferential length of the circumferential dovetail groove 412 equal to the circumferential length of the root portion 410.

Here, in the rotating bodies 300 and 400 according to the present embodiment, the converter 320 and the bucket 400 supported by the converter 320 are moved along the axial direction of the rotor 300 and the rotor wheel ( 310) and to prevent separation from the buckets 400 supported by the rotor wheel 310, may be manufactured according to the following manufacturing method of the rotating bodies 300 and 400.

That is, the rotating bodies 300 and 400 include a first step (S1) including the rotor 300 and the n buckets 400, a first bucket 4001 to an n-1th bucket 400n- A second step (S2) of assembling 1) with the rotor wheel 310 (S2), a third step of assembling the n-th bucket (400n) with the converter 320 (S3), and the converter 320 with the rotor wheel It may be manufactured according to a fourth step (S4) of assembling with 310 and a fifth step (S5) of moving the n buckets 400 as a whole along the circumferential direction of the rotor 300.

Specifically, the bucket 400 that is finally assembled among the n buckets 400 is referred to as an n-th bucket 400n, and the bucket 400 adjacent to the n-th bucket 400n is referred to as a first bucket 4001. And, referring to the second bucket 4002 to the n-1th bucket 400n-1 sequentially along the circumferential direction of the rotor 300 from the first bucket 4001 to the n-th bucket 400n , Through the first step (S1) and the second step (S2), the first bucket 4001 to the n-1th bucket 400n-1 are the tangential entry 312, the first By being inserted in the circumferential direction of the rotor 300 through the circumferential dovetail protrusion 314 and the circumferential dovetail groove 412, it may be sequentially assembled with the rotor wheel 310.

Then, through the third step (S3), the n-th bucket 400n includes a circumferential dovetail groove 412 of the n-th bucket 400n and a second circumferential dovetail protrusion of the converter 320 ( It may be assembled with the converter 320 through 324.

Then, through the fourth step (S4), the converter 320 assembled with the n-th bucket 400n is inserted into the tangential entry 312 in the axial direction of the rotor 300, so that the first It may be assembled with the rotor wheel 310 assembled with the bucket 4001 to the n-1th bucket 400n-1. That is, the axial dovetail protrusion 326 is inserted into the axial dovetail groove 316, and the second circumferential dovetail protrusion 324 is inserted into the tangential entry 312 so that the first circumferential dovetail The one annular dovetail protrusion R is formed together with the protrusion 314, and the n-th bucket 400n is engaged with the second circumferential dovetail protrusion 324, and the first bucket 4001 and It may be interposed between the n-1th bucket 400n-1.

Then, through the fifth step (S5), the first bucket 4001 to the n-1th bucket 400n-1 and the converter 320 assembled to the rotor wheel 310 The n-th bucket 400n as a whole may be moved to a predetermined position along the circumferential direction of the rotor 300.

Here, the predetermined position is any one of the n buckets 400 at a contact portion between the first circumferential dovetail protrusion 314 and the second circumferential dovetail protrusion 324 The root portion 410 of the rotor 300 overlaps in the axial and radial directions, and the other contact portion between the first circumferential dovetail protrusion 314 and the second circumferential dovetail protrusion 324 The root portion 410 of the bucket 400 adjacent to one bucket 400 and the rotor 300 may be overlapped in the axial and radial directions.

That is, if the circumferential length of the root part 410 is one pitch, as in the present embodiment, the predetermined position is the first bucket 4001 assembled to the rotor wheel 310 To the n-1th bucket 400n-1 and the nth bucket 400n assembled in the converter 320 are generally moved along the circumferential direction of the rotor 300 by a half pitch, and the One contact portion between the first circumferential dovetail protrusion 314 and the second circumferential dovetail protrusion 324 is the central side of the n-1th bucket 400n-1 and the axial direction and radius of the rotor 300 Direction, the other contact portion between the first circumferential dovetail protrusion 314 and the second circumferential dovetail protrusion 324 is the central side of the n-th bucket 400n and the axial direction of the rotor 300 And it may be a position overlapping in the radial direction.

On the other hand, even if the rotating bodies 300 and 400 are formed through the first step (S1) to the fifth step (S5), the n buckets 400 are positioned at the predetermined positions, for example Through driving or the like, the n buckets 400 may be moved in the circumferential direction of the rotor 300 to escape from the predetermined position. That is, the contact portions between the first circumferential dovetail protrusion 314 and the second circumferential dovetail protrusion 324 are side surfaces of the root portion 410 of any one of the n buckets 400 May be overlapped with each other in the axial direction and the radial direction of the rotor 300. Accordingly, the converter 320 and the bucket 400 supported by the converter 320 are moved in the axial direction of the rotor 300 to be supported by the rotor wheel 310 and the rotor wheel 310 It can be deviated from the 400s.

In consideration of this, the rotating bodies 300 and 400 according to the present embodiment may further include fixing means for fixing the n buckets 400 to the predetermined position.

Specifically, the fixing means includes a first pin hole H1 formed in the second circumferential dovetail protrusion 324, a root portion 410 of the n-1th bucket 400n-1, and the n-th A second pin hole H2 formed between the root portion 410 of the bucket 400n and a pin P inserted into the first pin hole H1 and the second pin hole H2 may be included. have.

The first pin hole H1 is formed by passing through the second circumferential dovetail protrusion 324 along the axial direction of the rotor 300 from the circumferential center side of the second circumferential dovetail protrusion 324 I can.

The second pin hole H2 is an axial direction of the rotor 300 between the root portion 410 of the n-1th bucket 400n-1 and the root portion 410 of the nth bucket 400n According to this, the root portion 410 of the n-1th bucket 400n-1 and the root portion 410 of the n-th bucket 400n may be formed to pass through. That is, the second pin hole H2 may be formed with a groove formed in the n-1th bucket 400n-1 to be concave in the n-th bucket 400n.

The pin P is separated from the first pin hole H1 and the second pin hole H2 along the axial direction of the rotor 300 so that the first pin hole H1 and the first pin It may be press-fitted into at least one of the 2 pin holes H2.

Here, in the method of manufacturing the rotating bodies 300 and 400 according to the present embodiment, after the fifth step S5, the pin P is formed in the first pin hole H1 and the second pin hole H2. ) And fixing the n buckets 400 may further include a sixth step (S6).

That is, the rotating bodies 300 and 400 according to the present embodiment, when the n buckets 400 are positioned at the predetermined position through the fifth step S5, the first pin hole H1 And the second pin hole H2 are opposed to each other, and the pin P is inserted into the first pin hole H1 and the second pin hole H2 through the sixth step S6. The n buckets 400 may be fixed at the predetermined position.

Hereinafter, a rotating body according to the present embodiment, a method of manufacturing a rotating body for manufacturing the same, and an effect of a steam turbine including the same will be described.

That is, the steam injected from the nozzle (not shown) is introduced into the n buckets 400 along the axial direction of the rotor 300, and the steam introduced into the bucket 400 is by the bucket 400. The flow direction is diverted and can pass through the bucket 400.

At this time, the impulse force by the steam may be applied to the bucket 400, whereby the bucket 400 is rotated in the circumferential direction of the rotor 300 together with the rotor 300, Energy can be converted into mechanical energy.

Here, in the rotor according to the present embodiment, the rotor manufacturing method for manufacturing the same, and the steam turbine including the same, the n buckets 400 are fastened to the rotor 300 in a tangential entry method, the n All of the buckets 400 are formed to be supported by the rotor 300 so that they can be stably fastened to the rotor 300. That is, the second circumferential dovetail protrusion 324 of the converter 320 fills the cut-off portion of the first circumferential dovetail protrusion 314 of the rotor wheel 310 which is disconnected by the tangential entry 312. , The one annular dovetail protrusion R, which is a complete circumferential dovetail protrusion, is formed, and the n-th bucket which is the final bucket 400 as well as the first bucket 4001 to the n-1th bucket 400n-1 (400n) may also be supported on the one annular dovetail protrusion R. Thereby, a significant load is prevented from being concentrated on a specific dovetail part, damage to the dovetail due to the concentration of the load is prevented, and the problem of detachment of the rotor 300 of the bucket 400 due to the damage of the dovetail will be prevented in advance. I can.

And, as the n buckets 400 are moved in the circumferential direction of the rotor 300 as a whole through the third step (S3) to the fifth step (S5) and are positioned at the predetermined position, the converter Since 320 and the bucket 400 are prevented from being separated in the axial and radial directions of the rotor 300, the n buckets 400 can be more stably fastened to the rotor 300.

And, as the n buckets 400 are fixed to the predetermined position through the sixth step (S6), the n buckets 400 can be prevented from being separated from the predetermined position. . Accordingly, not only the n buckets 400 can be more stably fastened to the rotor 300, but also the n buckets 400 are rotated along the circumferential direction of the rotor 300 during operation. 300) relative to the rotational motion of the energy of the steam is not completely converted to mechanical work, the problem of lowering the efficiency can be prevented in advance.

On the other hand, the present embodiment includes the axial dovetail groove 316 and the axial dovetail protrusion 326, the converter 320 is moved along the axial direction of the rotor 300, the rotor wheel 310 ), and is formed to prevent the converter 320 from being separated in the circumferential direction and the radial direction of the rotor 300. However, it is not limited thereto, and although not separately illustrated, the axial dovetail groove 316 and the axial dovetail protrusion 326 may not be formed. In this case, the effect of the n buckets 400 being supported by the rotor wheel 310 and the converter 320 may be substantially the same as in this embodiment. However, in this case, since the converter 320 is moved not only in the axial direction of the rotor 300 but also in the radial direction of the rotor 300 to be detachable from the rotor wheel 310, the converter 320 and the Assembly and detachment between the rotor wheels 310 may be facilitated. Meanwhile, in this case, the converter 320 uses the n-1th bucket 400n-1 and the nth bucket 400n among the n buckets 400 disposed at the predetermined position. It may be prevented from being separated in the axial and radial directions of 300, and the converter 320 is fastened in a manner that is press-fit into the rotor wheel 310 to be separated in the axial and radial directions of the rotor 300 Although it may be prevented, the axial dovetail groove 316 and the axial dovetail protrusion as in the present embodiment in order to stably fasten between the converter 320 and the rotor wheel 310 and prevent excessive residual stress from occurring. It may be desirable to include (326).

On the other hand, this embodiment includes the converter 320, but may not include the converter 320. That is, although not shown separately, in a state in which the first to n-1th buckets 4001 to 400n-1 are assembled to the rotor wheel 310, the nth bucket 400n is the tangential entry It is inserted into the 312, the n buckets 400 as a whole may be moved along the circumferential direction of the rotor 300 to be disposed at the predetermined position. In this case, all of the n buckets 400 may have an effect similar to that of the present embodiment. That is, a part of the tangential entry 312 is a part of one of the n buckets 400 (eg, the n-1th bucket 400n-1) and the rotor 300 A portion of the bucket 400 (for example, the n-th bucket 400n) adjacent to the one bucket 400 and the rest of the tangential entry 312 overlapping in the axial and radial directions of The first circumferential dovetail protrusion is partially overlapped in the axial and radial directions of 300, and thus, the one bucket 400 (for example, the n-1th bucket 400n-1) It is supported by 314, and the adjacent bucket 400 (for example, the n-th bucket 400n) may be supported by the first circumferential dovetail protrusion 314, although part of it. However, in this case, since mass imbalance of the rotor 300 and excessive stress concentration may occur in a part of the first circumferential dovetail protrusion 314, including the converter 320 as in the present embodiment It may be desirable.

Meanwhile, in the present embodiment, the n buckets 400 are moved by a half pitch in the fifth step (S5), but the present invention is not limited thereto.

That is, the predetermined position may be the first bucket 4001 to the n-1th bucket 400n-1 assembled to the rotor wheel 310 and the nth bucket assembled to the converter 320 ( 400n) may be a position moved along the circumferential direction of the rotor 300 to a total of more than zero picth and less than half pitch or less than one pitch more than half pitch. Accordingly, a contact portion between the first circumferential dovetail protrusion 314 and the second circumferential dovetail protrusion 324 is an axial direction of the n-1th bucket 400n-1 and the rotor 300 and It overlaps in the radial direction, but overlaps at a portion deviating from the center of the n-1th bucket 400n-1, and another contact between the first circumferential dovetail protrusion 314 and the second circumferential dovetail protrusion 324 The portions may overlap in the axial and radial directions of the n-th bucket 400n and the rotor 300, but may overlap at a portion deviating from the center side of the n-th bucket 400n. In this case, the effect of preventing the converter 320 and the bucket 400 from being separated in the axial direction of the rotor 300 may be substantially the same as in this embodiment. However, in this case, it may be disadvantageous in terms of stress design.

Alternatively, the predetermined position may be the first bucket 4001 to the n-1th bucket 400n-1 assembled to the rotor wheel 310 and the nth bucket assembled to the converter 320 ( 400n) is moved in excess of one pitch as a whole, so that, for example, a contact portion between the first circumferential dovetail protrusion 314 and the second circumferential dovetail protrusion 324 is the n-2th bucket 400 And the rotor 300 overlapping in the axial and radial directions, and another contact portion between the first circumferential dovetail protrusion 314 and the second circumferential dovetail protrusion 324 is the n-1th bucket 400n It may be a position to overlap -1) and the rotor 300 in the axial direction and the radial direction. In this case, the effect of preventing the converter 320 and the bucket 400 from being separated in the axial direction of the rotor 300 may be substantially the same as in this embodiment. However, in this case, since the n buckets 400 need to be moved by a significant amount, the time and cost required for this may be significantly increased.

Meanwhile, in the present embodiment, the first pin hole H1 is formed on the circumferential center side of the second circumferential dovetail protrusion 324, and the second pin hole H2 is the n-1th bucket It is formed between the root portion 410 of (400n-1) and the root portion 410 of the n-th bucket 400n. However, it is not necessarily limited thereto.

That is, under the premise that the n buckets 400 are moved by half pitch, the first pin hole H1 is formed in the second circumferential dovetail protrusion 324, and the second circumferential dovetail protrusion 324 is The second pin hole H2 is formed at a portion off the center of the circumferential direction, and the root portion 410 of the n-1th bucket 400n-1 or the root portion 410 of the nth bucket 400n Can only be formed.

Alternatively, even if the first pin hole H1 is formed on the circumferential center side of the second circumferential dovetail protrusion 324 as in this embodiment, the predetermined position is the n buckets 400 When the position is moved slightly or more than the pitch, the second pin hole H2 may be formed to face the first pin hole H1 at that position. In this case, the second pin hole H2 may be formed only on the root portion 410 of any one bucket 400, and two other buckets 400 adjacent to each other (for example, the first bucket 4001 and It may be formed between the second bucket (4002).

Alternatively, the first pin hole H1 is formed in the first circumferential dovetail protrusion 314, and the second pin hole H2 is one of the n buckets 400 or two buckets adjacent to each other ( 400) may be formed between.

However, in consideration of the advantage of half-pitch movement of the n buckets 400 (reduction in manufacturing time and cost) and mass balance and stress design of the rotating bodies 300 and 400, the first pin hole H1 and It may be preferable that the second pin hole H2 is formed as in the present embodiment.

Meanwhile, the dovetail protrusion and the groove may be formed opposite to each other.

That is, in the rotor 300, instead of the first circumferential dovetail protrusion 314 and the second circumferential dovetail protrusion 324, a first circumferential dovetail groove and a second circumferential dovetail groove are formed, and each bucket ( A circumferential dovetail protrusion may be formed in the root portion 410 of 400) instead of the circumferential dovetail groove 412.

In addition, an axial dovetail protrusion may be formed in the rotor wheel 310 instead of the axial dovetail groove 316, and an axial dovetail groove may be formed in the converter 320 instead of the axial dovetail protrusion 326. .

100: casing 300: rotor
310: rotor wheel 312: tangential entry
314: first circumferential dovetail protrusion 316: axial dovetail groove
320: converter 324: second circumferential dovetail protrusion
326: axial dovetail protrusion 400: bucket
4001: first bucket 4002: second bucket
400n-1: n-1th bucket 400n: nth bucket
410: root part 412: circumferential dovetail groove
420: wing portion H1: first pin hole
H2: second pin hole P: pin

Claims (15)

A rotor provided to be rotatable; And
Including; n buckets fastened to the rotor to convert the energy of the steam injected from the nozzle into mechanical work,
The rotor,
A rotor wheel having a tangential entry serving as an entrance of the bucket; And
Includes; a converter filling the tangential entry,
The rotor wheel is engraved radially inward of the rotor from the tangential entry and is formed to extend along the axial direction of the rotor, and at least one raised portion raised in the circumferential direction of the rotor and settled in the circumferential direction of the rotor. Comprising an axial dovetail groove having at least one settling portion,
The converter includes an axial dovetail protrusion having at least one raised portion raised in the circumferential direction of the rotor and at least one settling portion settled in the circumferential direction of the rotor to engage with the axial dovetail groove,
The n buckets are fastened to the rotor in a tangential entry method,
All of the n buckets are supported by the rotor,
The rotor wheel includes a first circumferential dovetail protrusion extended in a circumferential direction of the rotor from the tangential entry and cut off by the tangential entry,
The converter includes a second circumferential dovetail protrusion filling a disconnected portion of the first circumferential dovetail protrusion,
The first circumferential dovetail protrusion and the second circumferential dovetail protrusion form one annular dovetail protrusion,
Each bucket includes a root portion having a circumferential dovetail groove engaged with some of the one annular dovetail protrusion,
The first to n-1th buckets are inserted in the circumferential direction of the rotor through a circumferential dovetail groove of each bucket, a tangential entry of the rotor wheel, and a first circumferential dovetail protrusion of the rotor wheel. Are assembled sequentially,
An n-th bucket is assembled with the converter through a circumferential dovetail groove of the n-th bucket and a second circumferential dovetail protrusion of the converter,
The converter assembled with the nth bucket is inserted into the tangential entry in the axial direction of the rotor, thereby being assembled with the rotor wheel assembled with the first to n-1th buckets,
The first to n-1th buckets assembled to the rotor wheel and the nth bucket assembled to the converter are moved to a predetermined position along the circumferential direction of the rotor as a whole,
One contact portion between the first circumferential dovetail protrusion and the second circumferential dovetail protrusion overlaps in the axial and radial directions of the n-1th bucket and the rotor,
Another contact portion between the first circumferential dovetail protrusion and the second circumferential dovetail protrusion overlaps in the axial and radial directions of the n-th bucket and the rotor,
When the length of the root portion in the circumferential direction of the rotor is one pitch, the predetermined position is the first to the n-1th bucket assembled on the rotor wheel and the first bucket assembled on the converter. n is a position where the bucket is moved along the circumferential direction of the rotor by a half pitch as a whole
And a fixing means for fixing the first to n-th buckets to the predetermined position,
The fixing means,
A first pin hole formed through the second circumferential dovetail protrusion along the axial direction of the rotor from the center of the circumferential direction of the second circumferential dovetail protrusion;
It is formed between the root portion of the n-1th bucket and the root portion of the nth bucket along the axial direction of the rotor, passing through the root portion of the n-1th bucket and the root portion of the nth bucket, and the A second pin hole facing the first pin hole when the first to n-th buckets are positioned at the predetermined position; And
And a pin inserted into the first pin hole and the second pin hole. The method of claim 1,
In the tangential entry of the rotor, the n buckets as a whole are moved along the circumferential direction of the rotor, so that a part of the tangential entry is part of one of the n buckets and the axial and radial directions of the rotor. And the remainder of the tangential entry overlaps a portion of the bucket adjacent to the one bucket in the axial direction and the radial direction of the rotor. The method of claim 1,
The converter is a rotating body that is formed to be coupled to the rotor wheel by moving along the axial direction of the rotor. delete delete The method of claim 1,
The second circumferential dovetail protrusion is a rotating body formed to support at least one of the n buckets. The method of claim 1,
Each bucket further includes a blade portion protruding from the root portion in a radial direction of rotation of the rotor. The method of claim 7,
A rotating body in which the length of the tangential entry, the length of the second circumferential dovetail protrusion, the length of the root portion and the length of the circumferential dovetail groove are all the same on the circumferential direction of the rotor. delete delete delete delete delete A first step comprising the rotor of the rotating body according to any one of claims 1 to 3 and 6 to 8 and n buckets;
The rotor of the rotating body includes a rotor wheel having the tangential entry and a converter filling the tangential entry, and the first to n-1th buckets among n buckets of the rotating body are sequentially selected from A second step of assembling with the rotor wheel by inserting in the circumferential direction of the rotor through a tangential entry;
A third step of assembling an n-th bucket among n buckets of the rotating body with the converter;
A fourth step of inserting the converter assembled with the nth bucket into the tangential entry in the axial direction of the rotor and assembling the first to n-1th buckets and the assembled rotor wheel;
A fifth step of moving the first to n-1th buckets assembled to the rotor wheel and the nth buckets assembled to the converter by a half pitch along the circumferential direction of the rotor as a whole; And
A sixth step of fixing the n buckets by inserting the pins of the rotor into the first pin holes formed in the rotor and the second pin holes formed in the buckets. Casing;
Claims 1 to 3, 6 to 8 rotatably provided inside the casing The rotating body according to any one of the preceding; And
A steam turbine including a nozzle for injecting steam into the rotating body.

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