KR102366844B1 - Rotating Supporter with automatic alignment for inspection of turbine rotors - Google Patents

Abstract

The present invention relates to a rotating support for inspection of a self-aligning turbine rotor. The rotating support for the inspection of the self-aligning turbine rotor according to one embodiment of the present invention comprises: a base frame extending in the rotor shaft direction of the turbine rotor; a left rotor shaft support unit for supporting a left part of a rotor shaft of the turbine rotor, including a support frame disposed on the base frame; and a right rotor shaft support unit for supporting a right part of the rotor shaft of the turbine rotor, including the support frame disposed on the base frame. An objective of the present invention is to provide the rotating support for the inspection of the self-aligning turbine rotor, which can safely inspect and repair the turbine rotor.

Description

Rotating Supporter with automatic alignment for inspection of turbine rotors

The present invention relates to a rotary support for checking a self-aligning turbine rotor, and more particularly, to a rotary support for checking and repairing a turbine rotor of a steam turbine used in a thermal power plant, etc. .

Currently, there are about 300 domestic power plants in operation, including nuclear power, coal-fired power plants, and combined cycle power plants. Among them, thermal power plants use high-temperature and high-pressure steam generated from boilers to rotate turbines to generate electricity from generators. In the case of a steam turbine, in order to proceed with the planned disassembly and maintenance work, disassembly of the steam turbine casing and inspection and maintenance of the turbine rotor are necessarily accompanied.

In order to inspect the turbine rotor, the inspection is performed while the turbine rotor is rotated while supporting both ends of the turbine rotor shaft, and there is a risk of separation of the turbine rotor by rotating the turbine rotor with a crane, and there is a problem that maintenance work is inefficient.

For this purpose, a "turbine rotor rotary support" (Registered Utility Model No. 20-0443744, 2009.3.11 announcement) has been proposed by the present applicant.

The apparatus described in the registered utility model is shown in Figs. When the turbine rotor rotary support is described with reference to FIGS. 1 and 2 , it includes a driving side device 120 and a driven side device 130 without a power generating device, and the driving side device 120 is shown in FIG. 2 . As shown, the rotor shaft support rollers 212 and 213 for supporting the rotor shaft 110 of the turbine rotor 100 and; a first power transmission unit 215 (first chain) connected to the gear reduction unit 217 to transmit power to the driving support roller 212; a second power transmission unit 216 (second chain) connected to the driving support roller 212 to transmit power to the driven support roller 213; a power generating unit 218 connected to the gear reduction unit 217 to generate and transmit power and mounted inside the main body 211; The rotor shaft support rollers 212 and 213 are supported, the control box 221 is provided on the outside, and the first power transmission unit 215, the gear reduction unit 217 and the power generation unit 218 are provided inside. The body 211 for embedding; includes.

The first and second power transmission units 215 and 216 are formed of a chain. Due to the nature of the chain, the rotating side is pulled and taut, while the opposite side is stretched, and when performing forward and reverse rotation, accurate rotational force is not transmitted, and the rotational force of the driving support roller 212 is transmitted to the driven support roller 213 by the chain. While rotating the rotor shaft 110, it is not rotated at the same time, but the driving support roller 212 is rotated first, and the second chain 216 is rotated while extending and the driven support roller 213 is rotated to rotate the turbine shaft 110. Therefore, as the rotation of the turbine shaft 110 becomes non-uniform, there is a disadvantage in that a large amount of initial rotational force is required.

In addition, there is no proper regulation for the left and right widths of the bottom surface of the turbine rotor support, and due to the narrow width, the force is applied in the lateral direction while the heavy turbine is placed on the first and second rotor shaft support rollers 212 and 213. There is a risk that the device may tip over or even overturn if applied. In addition, the conventional turbine rotor support has a problem in that it is difficult to accurately seat the support when the center shafts of the driving-side device and the driven-side device do not match, and it is difficult to separate the high-pressure turbine part and the low-middle-pressure turbine part and check them.

Accordingly, the present invention has been devised to solve the problems of the prior art, and it is an object of the present invention to provide a rotary support for automatically aligning turbine rotor inspection that can be inspected and repaired more safely while stably supporting the turbine rotor. .

The rotary support for inspection of the self-aligning turbine rotor according to an embodiment of the present invention includes a base frame 310 extending in the direction of the rotor shaft 110 of the turbine rotor 100; a left rotor shaft support portion 400 for supporting the left portion of the rotor shaft 110 of the turbine rotor 100, including a support frame 410 disposed on the base frame 310; and a right rotor shaft support portion 600 for supporting the right portion of the rotor shaft 110 of the turbine rotor 100 including the support frame 610 disposed on the base frame 310; do.

In addition, the left rotor shaft support 400 includes a mounting plate 440 disposed on the support frame 410; and a plurality of support rollers (450, 460) coupled to the mounting plate (440) to support the rotor shaft (110).

In addition, the left rotor shaft support part 400 is provided with rollers 412 on both sides to be movably disposed on the base frame 310 and a support plate 411 coupled to the lower portion of the support frame 310 . It is characterized in that it further comprises.

In addition, the left rotor shaft support portion 400 includes a plurality of rollers 422 in which the rotation shaft is disposed in the longitudinal direction of the base frame 310 ; and an upper plate 420 coupled to the upper portion of the support frame 410, including springs 424 disposed on both sides of the roller 422, respectively; and an adjustment plate 430 movably disposed on the upper plate 420 , wherein the mounting plate 440 is coupled to the adjustment plate 430 .

In addition, the support rollers 450 and 460 include a pair of first support rollers 450 and a pair of second support rollers 460 disposed above the first support roller 450 . do it with

In addition, the mounting plate 440 is formed with a moving hole 441 in which each of the second support rollers 460 can move, and the moving hole 441 includes a first moving hole 441a extending in the vertical direction and and a second moving hole 441b extending outwardly from an upper portion of the first moving hole 441a, and the second support roller 460 includes the first moving hole 441a and the second moving hole ( It is characterized in that it is movably coupled along 441b).

In addition, the right rotor shaft support portion 600 is disposed on the upper portion of the support frame 610, characterized in that it further includes a pair of rotation support rollers 650 for supporting the rotor shaft (110).

In addition, the right rotor shaft support portion 400 includes an upper plate 620 including a coupling hole 622 and a plurality of rollers 625 radially disposed around the coupling hole 622 ; A rotational shaft coupled to the coupling hole 622 is disposed on a bottom surface of the rotation plate 630 to be rotatably disposed on the upper plate 620; and a driving motor 660 coupled to the rotation plate 630 to rotate the rotation support roller 650; the rotation support roller 650 is disposed on the rotation plate 630 characterized by being

In addition, the upper plate 620 has an inner peripheral plate 623 to which the inner end of each roller 625 is coupled; and an outer circumferential disc 624 to which the outer end of each of the rollers 625 is coupled.

In addition, a first intermediate rotor shaft support part 500 that supports the rotor shaft 110 and is disposed on the base frame 310 between the left rotor shaft support part 400 and the right rotor shaft support part 600 is provided. It is characterized in that it further comprises.

In addition, a second intermediate rotor shaft support part 550 that supports the rotor shaft 110 between the left rotor shaft support part 400 and the right rotor shaft support part 600 and is disposed on the base frame 310, It is characterized in that it further comprises.

In addition, the first intermediate rotor shaft support part 500 includes a support frame disposed on the base frame 310 to support the left side of the rotor shaft 110 of the turbine rotor 100 , and the second middle The rotor shaft support 550 includes a support frame disposed on the base frame 310 to support the right side of the rotor shaft 110 of the turbine rotor 100 .

In addition, the first intermediate rotor shaft support part 500 is provided with rollers on both sides so as to be movably disposed on the base frame 310 and coupled to the lower portion of the support frame of the first intermediate rotor shaft support part 500 . It characterized in that it further comprises a support plate.

According to the present invention, while stably supporting the turbine rotor, there is provided a rotary support for self-aligning turbine rotor inspection that can be inspected and repaired more safely.

1 is a plan view of a conventional turbine rotor support;
Figure 2 is a front view of the turbine rotor support of Figure 1,
3 is a perspective view of a rotary support for checking a self-aligning turbine rotor according to the present invention;
4 is a front view of the rotary support for checking the automatic alignment type turbine rotor according to the present invention;
5 is a plan view of a rotary support for checking a self-aligning turbine rotor according to the present invention;
6 is a view showing a state before the turbine rotor is seated on the rotary support for self-aligning turbine rotor inspection according to the present invention,
7 is a detailed view of the left rotor shaft support in the present invention,
8 is a view showing a state before the turbine rotor is seated on the left rotor shaft support in FIG.
9 is a view showing a cross section of the left rotor shaft support in the present invention,
10 is a view showing a state in which the upper part of the left rotor shaft support part is separated in the present invention;
11 is a lower detailed view of the left rotor shaft support in the present invention,
12 is a detailed view of the right rotor shaft support in the present invention,
13 is a view showing a state in which the upper part of the right rotor shaft support part is separated in the present invention;
14 is a view showing a state in which the high-pressure turbine part and the low-middle-pressure turbine part of the rotor shaft are separated and supported in the present invention.

Hereinafter, a rotary support for self-aligning turbine rotor inspection according to a preferred embodiment of the present invention will be described in detail with reference to the drawings.

Figure 3 is a perspective view of a rotary support for checking the automatic alignment type turbine rotor according to the present invention, Figure 4 is a front view of the rotary support for checking the automatic alignment type turbine rotor according to the present invention, Figure 5 is an automatic It is a plan view of the rotary support for checking the alignment type turbine rotor, Figure 6 is a view showing the state before the turbine rotor is seated on the rotary support for the automatic alignment type turbine rotor check according to the present invention, Figure 7 is in the present invention It is a detailed view of the left rotor shaft support, FIG. 8 is a view showing a state before the turbine rotor is seated on the left rotor shaft support in FIG. 7, and FIG. 9 is a cross-sectional view of the left rotor shaft support in the present invention. , Figure 10 is a view showing a state in which the upper part of the left rotor shaft support part is separated in the present invention, Figure 11 is a detailed view of the lower part of the left rotor shaft support part in the present invention, and Figure 12 is a right rotor shaft support part in the present invention It is a detailed view, and FIG. 13 is a view showing a state in which the upper part of the right rotor shaft support part is separated in the present invention, and FIG. It is a drawing.

First, the rotary support 300 for checking the automatic alignment type turbine rotor according to a preferred embodiment of the present invention is a base frame 310; A left rotor shaft support portion 400 for supporting the left portion of the rotor shaft 110 of the turbine rotor 100; and a right rotor shaft support portion 600 supporting a right portion of the rotor shaft 110 of the turbine rotor 100 .

The rotary support 300 for self-aligning turbine rotor inspection according to the present invention is for inspecting and repairing the turbine rotor 100 disposed inside the turbine casing of the steam turbine, and the turbine rotor 100 is as shown The rotor shaft 110 is disposed in the center, the high-pressure turbine rotor unit 140 is coupled to the left side of the rotor shaft 110 in the drawing, and the low-mid pressure turbine rotor unit 150 is coupled to the right side of the rotor shaft 110 . do. The low and medium pressure turbine rotor unit 150 includes a medium pressure turbine rotor unit 151 and a low pressure turbine rotor unit 152 .

The base frame 310 is formed to extend in the direction of the rotor axis of the turbine rotor and is disposed on the floor on which the rotary support 300 of the present invention is installed, and a plurality of metal frames are combined.

A left rotor shaft support part 400 and a right rotor shaft support part 600 are disposed on the base frame 310 , and a first intermediate rotor shaft support part 500 and a second intermediate rotor shaft support part 550 to be described later are disposed.

The left rotor shaft support portion 400 is disposed on the base frame 310 to support the left portion of the rotor shaft 110 , and as shown in FIGS. 7 to 10 , the support frame 410 and the support frame It includes a support roller coupled to the 410.

The support frame 410 is disposed on the base frame 310 to have a support roller installed thereon, and a support plate 411 is coupled to the lower portion of the support frame 410 .

The coupling of the support frame 410 and the support plate 411 is formed with a protrusion 413 having a pointed conical tip 413a on the support plate 411 as shown in FIG. 11, so that the protrusion 413 is It is coupled to the coupling hole 410a at the bottom of the support frame 410 and then fixed with a bolt and a nut.

The support plate 411 is disposed on the base frame 310 in the form of a plate as shown in FIG. 11 , and a pair of rollers 412 are coupled to the left and right sides of the lower portion of the support plate 411 , respectively. The left and right rollers 412 of the support plate 411 are moved to the left and right of the base frame 310 along the left and right edge frames 311 of the base frame 310 .

In addition, pins 401 are provided on the left and right sides of the support plate 411 to move the left rotor shaft support 400 on the base frame 310 and then pin ( 401) is inserted to fix the left rotor shaft support 400.

The upper plate 420 is coupled to the upper portion of the support frame 410 . 9 and 10, a groove 421 is formed in the upper plate 420, and a plurality of rollers 422 and a spring 424 elastically supported on the left and right sides of the roller 422 are formed in the groove 421. ) is placed.

Each roller 422 extends in the longitudinal direction of the base frame 310 and its rotation axis is arranged parallel to the axial direction of the rotor shaft 110 or the longitudinal direction of the base frame 310 as shown. In addition, a plurality of rollers 422 are spaced apart in the width direction of the base frame 310 so that front and rear ends of each roller 422 are coupled to a pair of connecting plates 423 , respectively.

The spring 424 is for elastically supporting the plurality of rollers 422 coupled to the pair of connecting plates 423, and springs 424 on the outside of the rollers 422 disposed at the edges of the connecting plate 423. This arrangement, the spring 424 is also arranged on the outside of the roller 422 arranged on the opposite edge of the connecting plate (423).

Accordingly, the springs 424 disposed on both edges of the connecting plate 423 elastically support the plurality of rollers 422 connected by the connecting plate 423 at both sides.

A support roller is disposed on the upper portion of the upper plate 420, and the support rollers can be moved to both sides by the plurality of rollers 422, and the plurality of rollers 422 are stably supported by the springs 424 disposed on both sides. is supported

The support roller part is mounted on the upper part of the support frame 410 to support the rotor shaft 110 by a plurality of support rollers 450 and 460, and is an adjustment disposed on the lower part as shown in FIGS. 7 to 9 . It includes a plate 430 , a mounting plate 440 , and a plurality of support rollers 450 and 460 .

The adjustment plate 430 is movably disposed on both sides on the upper part of the upper plate 420 , and the adjustment plate 430 is movable to both sides in the width direction of the base frame 310 by a plurality of rollers 422 . will do

Coupling holes 431 extending in the width direction of the base frame 310 are formed on both sides of the adjustment plate 430 , and coupling bolts 432 are coupled to the upper plate 420 through the coupling holes 431 .

Therefore, by moving the adjustment handle 470 coupled to the mounting plate 440 to both sides to adjust the position of the adjustment plate 430, and then by coupling the coupling bolt 432 to the upper plate 420 at the adjusted position to adjust The position of the plate 430 is fixed.

The mounting plate 440 is vertically coupled to the adjustment plate 430 , and the supporting rollers 450 and 460 are coupled to the mounting plate 440 . In addition, an adjustment knob 470 is coupled to the mounting plate 440 as shown in FIG. 7 .

In the present invention, when the rotor shaft 110 is seated on the rotary support 300 in the turbine rotor 100 , the axis line of the rotor shaft 110 and the left and right rotor shaft support parts 400 and 600 of the rotary support 300 are aligned. If they do not match, the position is adjusted by moving the adjustment plate 430 to both sides on the upper plate 420 using the adjustment handle 470 as described above, and then the rotor shaft 110 is seated.

The support rollers 450 and 460 are composed of a pair of first support rollers 450 and a pair of second support rollers 460 , and the pair of first support rollers 450 are mounted on the mounting plate 440 . It is horizontally spaced apart to support one end of the lower portion of the rotor shaft 110 . In addition, each of the first support rollers 450 is made of two support rollers disposed on the left and right with the mounting plate 440 as the center connected to each other by a shaft portion.

In each of the first supporting rollers 450 , the rotation shaft thereof is supported by a bearing on the mounting plate 440 , and in this embodiment, it is formed of a thrust bearing. When the axis of the first support roller 450 is slightly misaligned with the axis of the rotor shaft 110 as the rotation shaft of the first support roller 450 is supported by the thrust bearing on the mounting plate 440, the turbine rotor 100 They are automatically aligned during the installation process.

The second support roller 460 is disposed on the upper side of the first support roller on the mounting plate 440 , and the distance between the two second support rollers 460 is greater than the distance between the two first support rollers 450 . placed largely horizontally.

Each of the second support rollers 460 is made of two support rollers disposed on the left and right with the mounting plate 440 as a center and connected to each other by a shaft portion, and the shaft portion connecting the two support rollers is a moving hole 441 . is movably coupled to the The moving hole 441 includes a first moving hole 441a extending up and down and a second moving hole 441b extending outward (horizontal direction) from the upper portion of the first moving hole 441a.

By this configuration, the second support roller 460 is movably coupled along the first moving hole 441a and the second moving hole 441b. As shown in FIG. 8, the rotor shaft 110 is supported by the support roller Before being seated in the (450, 460), the second support roller 460 moves to the upper part of the first moving hole 441a, and then moves it outward along the second moving hole 441b, the rotor shaft 110 is seated on the first support roller 450 . After the rotor shaft 110 is seated on the first support roller 450, the second support roller 460 is moved to the upper portion of the first moving hole 441a along the second moving hole 441b as shown in FIG. After the first moving hole (441a) is moved to the lower portion so that the outer peripheral surface of the second support roller (460) is in contact with and supported by the rotor shaft (110). As such, in a state in which the shaft portion of the second support roller 460 moves to the lower portion of the first moving hole 441a, the center of the second support roller 460 coincides with a horizontal line passing through the center of the rotor shaft 110 or a horizontal line The center of the second support roller 460 may be located on the upper side.

In this way, by allowing the outer peripheral surfaces of the two second support rollers 460 to support the rotor shaft 110 , the rotor shaft 110 is stably supported without being separated from the first and second support rollers 450 and 460 . It is possible to perform maintenance and inspection of the turbine rotor 100 .

The right rotor shaft support portion 600 is disposed on the base frame 310 to support the right portion of the rotor shaft 110 , and as shown in FIGS. 12 and 13 , the support frame 610 and the support frame It includes a support roller coupled to the 610.

An upper plate 620 is coupled to the upper portion of the support frame 610 . 13, a circular groove 621 is formed in the upper plate 620, and a rotation shaft (not shown) protruding from the bottom surface of the rotation plate 630 is coupled at the center of the groove 621. A ball 622 is formed and a plurality of rollers 625 are disposed in the groove 621 on the outside of the coupling hole 622 .

Each roller 625 has a rotational axis of which is radially arranged with respect to the coupling hole 622, and a plurality of rollers 625 are spaced apart from each other at a predetermined angle with respect to the coupling hole 622 and are radially arranged so that each roller 625 ), the inner end is coupled to the inner circumferential plate 623, and the outer end of the roller 625 is coupled to the outer circumferential plate 624, respectively.

A rotating plate 630 is disposed on the upper portion of the upper plate 620 , and the rotating plate 630 can be stably rotated by a plurality of radially arranged rollers 625 .

The support roller part is mounted on the upper part of the support frame 610 to support and rotate the rotor shaft 110 by the rotation support roller 650, and as shown in FIGS. 12 and 13, a rotation plate disposed on the lower part 630 , and a driving motor 660 , and a pair of rotation support rollers 650 .

The rotation plate 630 is rotatably coupled to the upper portion of the upper plate 620 , and a rotation shaft (not shown) formed on the bottom surface of the rotation plate 630 is coupled to the coupling hole 622 of the upper plate 620 . and the rotation plate 630 is rotatably disposed around the coupling hole 622 by a plurality of rollers 625 .

Coupling holes 631 are formed on both sides of the rotation plate 630 , and coupling bolts (not shown) are coupled to the upper plate 620 through the coupling holes 631 .

Therefore, the rotation plate 630 is rotated around the coupling hole 622 to adjust the angle of the rotation plate 630, and then the coupling bolt (not shown) through the coupling hole 631 at the adjusted position is applied to the upper plate ( By coupling to 620), the position of the rotating plate 630 is fixed. When the alignment line of the axis line of the rotor shaft 110 and the left and right rotor shaft support portions 400 and 600 of the rotary support 300 together with the adjustment plate 430 of the left rotor shaft support 400 described above does not match, the above-described As shown, the rotor shaft 110 is seated after adjusting the position by rotating the rotation plate 630 of the right rotor shaft support portion 600 .

A pair of rotation support rollers 650 are rotatably coupled side by side between a pair of brackets 640 coupled on the rotation plate 630, and the rotor shaft 110 is a pair of rotation support rollers 650. It is rotated by the driving motor 660 while being supported by the .

The driving motor 660 disposed on the rotating plate 630 is for rotating the pair of rotating support rollers 650, and the sprocket 661 rotated by the driving motor 660 is attached to the chain (or belt). It is connected to one rotation support roller 650 by a pair of rotation support rollers 650, and the pair of rotation support rollers 650 are connected by a chain (or belt) so that as the drive motor 660 operates, the pair of rotation support rollers 650 are connected to each other. rotates clockwise or counterclockwise.

Accordingly, the turbine rotor 100 is inspected and repaired while rotating the turbine rotor 100 by operating the driving motor 660 .

Meanwhile, in the present invention, a first intermediate rotor shaft support part 500 and a second intermediate rotor shaft support part 550 are disposed between the left rotor shaft support part 400 and the right rotor shaft support part 600 .

The first intermediate rotor shaft support part 500 is disposed on the base frame 310 to support one end of the rotor shaft 110 on which the left high-pressure turbine rotor part 140 is disposed on the rotor shaft 110 , and the configuration thereof is the same as the aforementioned left rotor shaft support 400 .

Accordingly, the first intermediate rotor shaft support portion 500 includes a support frame 410 identical to that of the left rotor shaft support portion 400 , and a support roller portion coupled to the support frame 410 , and the lower portion of the support frame 410 . Similarly, the support plate 411 is coupled.

And, in the first intermediate rotor shaft support portion 500, the support plate 411 is the same as the left rotor shaft support portion 400, the pair of rollers 412 are coupled to the left and right edge frames 311 of the base frame 310. is moved to the left and right of the base frame 310 along the

The first intermediate rotor shaft support part 500 is the same as the configuration of the left rotor shaft support part 400 , so a detailed description of the configuration will be omitted.

The second intermediate rotor shaft support part 550 is disposed on the base frame 310 to support one end of the rotor shaft 110 on which the right middle and low pressure turbine rotor part 150 is disposed on the rotor shaft 110, the base It comprises a support frame 551 disposed on the frame, and a V-shaped support plate 552 coupled to the upper support frame 551 to support the rotor shaft 110 .

In the present invention, as described above, between the left rotor shaft support part 400 and the right rotor shaft support part 600 , the first intermediate rotor shaft support part 500 and the second intermediate rotor shaft support part 550 are disposed to form the rotor shaft 110 . ) to prevent bending deformation in the middle and to support the rotor shaft 110 more stably.

In addition, as shown in FIG. 14 , the rotor shaft 110 part to which the high-pressure turbine rotor part 140 is coupled and the rotor shaft 110 part to which the mid-low pressure turbine rotor part 150 is coupled are detachably coupled. In the case of separating the middle of the rotor shaft 110, the left rotor shaft support 400 and the first intermediate rotor shaft support 500 supporting both ends of the left portion of the rotor shaft 110 to which the high-pressure turbine rotor part 140 is coupled. The left and right parts of each rotor shaft 110 can be individually inspected and repaired in a state in which the support plate 411 is completely separated from the second intermediate rotor shaft support 550 on the base frame 310 .

As mentioned above, although the present invention has been described with reference to preferred embodiments, the present invention is not limited thereto, and those skilled in the art may make various modifications within the scope without departing from the gist of the present invention described in the claims below. There will be.

100: turbine rotor 110: rotor shaft
140: high-pressure turbine rotor unit 150: mid-low pressure turbine rotor unit
300: rotary support 310: base frame
400: left rotor shaft support 410: support frame
500: first intermediate rotor shaft support 550: second intermediate rotor shaft support
600: right rotor shaft support 610: support frame

Claims (13)

a base frame 310 extending in the rotor shaft 110 direction of the turbine rotor 100;
a left rotor shaft support portion 400 for supporting the left portion of the rotor shaft 110 of the turbine rotor 100, including a support frame 410 disposed on the base frame 310; and
A right rotor shaft support portion 600 for supporting the right portion of the rotor shaft 110 of the turbine rotor 100, including the support frame 610 disposed on the base frame 310;
The left rotor shaft support 400 is
a mounting plate 440 disposed on the support frame 410;
a plurality of support rollers (450, 460) coupled to the mounting plate (440) to support the rotor shaft (110);
a plurality of rollers 422 having a rotating shaft disposed in the longitudinal direction of the base frame 310; A pair of connecting plates 423 to which the front and rear ends of the plurality of rollers 422 are coupled, respectively, and a plurality of connecting plates 423 disposed on both sides of the plurality of rollers 422 and coupled to the pair of connecting plates 423, respectively. an upper plate 420 coupled to the upper portion of the support frame 410 including springs 424 for elastically supporting the rollers 422 from both sides; and
Further comprising; an adjustment plate 430 movably disposed on the upper plate 420,
The mounting plate 440 is a rotary support for the inspection of the self-aligning turbine rotor, characterized in that coupled to the adjustment plate (430). delete According to claim 1,
The left rotor shaft support part 400 further includes a support plate 411 having rollers 412 disposed on both sides, movably disposed on the base frame 310 and coupled to a lower portion of the support frame 410 . A rotary support for the inspection of the self-aligning turbine rotor, characterized in that. delete According to claim 1,
The support rollers 450 and 460 include a pair of first support rollers 450 and
A rotary support for the inspection of the self-aligning turbine rotor, characterized in that it comprises a pair of second support rollers (460) disposed on the first support roller (450). 6. The method of claim 5,
The mounting plate 440 is provided with a movable hole 441 through which each of the second support rollers 460 is movable,
The moving hole 441 includes a first moving hole 441a extending in the vertical direction and a second moving hole 441b extending outward from the upper portion of the first moving hole 441a,
The second support roller (460) is a rotary support for the inspection of the self-aligning turbine rotor, characterized in that movably coupled along the first moving hole (441a) and the second moving hole (441b). According to claim 1,
The right rotor shaft support 600 is
A rotary support for the inspection of the self-aligning turbine rotor, which is disposed on the support frame (610) and further comprises a pair of rotary support rollers (650) for supporting the rotor shaft (110). 8. The method of claim 7,
The right rotor shaft support 400 is
an upper plate 620 including a coupling hole 622 and a plurality of rollers 625 radially disposed around the coupling hole 622;
A rotational shaft coupled to the coupling hole 622 is disposed on a bottom surface of the rotation plate 630 to be rotatably disposed on the upper plate 620; and
It is coupled on the rotation plate 630 and a driving motor 660 for rotating the rotation support roller 650; further comprising,
The rotary support roller (650) is a rotary support for the inspection of the self-aligning turbine rotor, characterized in that disposed on the rotary plate (630). 9. The method of claim 8,
The upper plate 620 includes an inner circumferential plate 623 to which the inner end of each roller 625 is coupled; and
A rotary support for the inspection of the self-aligning turbine rotor, characterized in that it further comprises an outer circumferential disk (624) to which the outer end of each of the rollers (625) is coupled. According to claim 1,
A first intermediate rotor shaft support part 500 supported on the base frame 310 and supporting the rotor shaft 110 between the left rotor shaft support part 400 and the right rotor shaft support part 600 is further included. A rotary support for the inspection of the self-aligning turbine rotor, characterized in that. According to claim 1,
Supporting the rotor shaft 110 between the left rotor shaft support part 400 and the right rotor shaft support part 600 and further comprising a second intermediate rotor shaft support part 550 disposed on the base frame 310 A rotary support for the inspection of the self-aligning turbine rotor, characterized in that. 12. The method of claim 11,
The first intermediate rotor shaft support part 500 includes a support frame disposed on the base frame 310 to support the left side of the rotor shaft 110 of the turbine rotor 100,
The second intermediate rotor shaft support part 550 includes a support frame 551 disposed on the base frame 310 to support the right side of the rotor shaft 110 of the turbine rotor 100 . Rotating support for inspection of self-aligning turbine rotors. 13. The method of claim 12,
The first intermediate rotor shaft support 500 is
Self-aligning type, characterized in that the rollers are disposed on both sides to be movably disposed on the base frame (310) and further include a support plate coupled to the lower portion of the support frame of the first intermediate rotor shaft support part (500). Rotary support for inspection of turbine rotor.

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