KR20170002458U - Rotary type rotor shaft supporting stand - Google Patents

Abstract

The present invention relates to a rotary rotor stand, and more particularly, to a rotary rotor stand which includes a frame provided corresponding to each of rotor shafts extending to both sides of a power generation turbine, a plurality of support shafts provided on each of the frames, A roller cover provided on the circumferential surface of the support roller for protecting the support roller from the rotor shaft and a caster provided on the frame located at least at one side of each frame corresponding to both sides of the rotor shaft. do.
The present invention provides a caster in a stand that supports a rotor shaft in a circumstantial manner for repairing a turbine, which facilitates the positioning of the stand, allows the caster of the positioned frame to be spaced from the floor, Therefore, it is possible to prevent the casters from being damaged by the load, and it is possible to detect whether or not the rotor shaft is correctly positioned, thereby preventing the eccentric load of the support roller from being generated.

Description

ROTARY TYPE ROTOR SHAFT SUPPORTING STAND

The present invention relates to a rotary type rotor stand, and more particularly, to a stand for supporting a rotor shaft externally for repairing a turbine, a caster is provided for facilitating positioning of the stand, The present invention relates to a rotary type rotor stand capable of preventing damage to a caster due to a load and detecting whether a rotor shaft is set in a proper position, thereby preventing an eccentric load from being generated in the support roller.

In general, when a gas turbine rotor is heavy enough to handle dozens of tons and requires repair, it is mounted on a stand, and then the operator climbs up using a ladder to perform a nondestructive inspection of the upper rotor blade (blade) A turbine bucket replacement was performed.

The support for supporting the existing gas turbine is configured to support the rotor shaft formed on both sides of the gas turbine rotor at the bottom, and once the gas turbine rotor is supported on the support, the gas turbine rotor is placed in a difficult to rotate state .

Such a support for a gas turbine rotor is disclosed in Korean Patent Registration No. 10-0661756 (filed on December 20, 2006, entitled: Pipe Piercing Device).

The technical structure described above is a background technology for assisting the understanding of the present invention and does not mean a conventional technology widely known in the art to which the present invention belongs.

Existing gas turbine support rods are unstable in posture due to the complicated operation when checking the compressor blades of the gas turbine rotor and replacing the turbine bucket, and there is a risk of safety accident such as falling of the portable equipment.

In addition, the existing support for the gas turbine has to be rotated at 90 일정 for a certain period of time when there is a possibility of bending phenomenon when the support of the gas turbine rotor is installed for a long time due to its weight of tens of tons. However, There is a problem that the work stability line and efficiency are lowered.

In addition, the conventional support for a gas turbine has a large load due to its own weight, which damages the roller as the synthetic resin, damages the rotor journal, and causes the rotor to tilt, resulting in damage due to mutual contact between the equipment and the rotor There is a problem.

In addition, since the conventional gas turbine support frame is in contact with the bottom of the frame itself, it is difficult to accurately position the support frame according to the position of the rotor.

Therefore, there is a need to improve this.

It is an object of the present invention to provide a rotary type rotor stand which can easily position a stand by providing a caster on a stand for supporting a rotor shaft in a circumstance for repairing a turbine .

It is an object of the present invention to provide a rotary type rotor stand for preventing the casters from being damaged due to a load by allowing the casters of the positioned frames to be spaced from the floor so that the stands are held in contact with the floor.

Another object of the present invention is to provide a rotary type rotor stand for detecting whether or not the rotor shaft is positively positioned at an intermediate position of a pair of support rollers through a sensor to prevent the eccentric load of the support roller from being generated.

A rotary rotor stand according to the present invention includes: a frame provided corresponding to each of rotor axes extending to both sides of a power generation turbine; A plurality of support rollers provided on the upper side of each of the frames and circumscribed with the corresponding rotor shaft to rotate in a rolling manner; And a roller cover provided on a circumferential surface of the support roller to protect the support roller from the rotor shaft, wherein a frame positioned at at least one side of each frame corresponding to both sides of the rotor shaft facilitates positional movement And a caster is further provided.

The frame has a plurality of receiving portions formed along a lower edge thereof; The casters are rotatably connected to the inside of the accommodating portion in the circumferential direction so that the direction of movement of the frame can be easily set. The casters can be rotatably rotated on the floor while being accommodated in the accommodating portion, thereby being protected from the outside.

And the casters are connected to a screw threaded to the frame while being protruded to the outside of the frame, and after the positioning of the frame, the casters are spaced from the floor by the operation of the screw.

The support roller being rotatably mounted on the bracket; The bracket can be finely corrected by the position correcting unit.

Wherein the position correcting portion includes: a shaft rotatably screwed to the bracket while being fixed in position above the frame; A handle for rotating the shaft; And a guide rail for guiding the bracket to be positionally corrected with respect to the frame.

The frame may include a rotor axis sensor for detecting the correct position of the rotor axis on the support roller.

As described above, the rotary rotor stand according to the present invention can easily locate the stand by providing a caster on a stand that supports the rotor shaft in a circumstance for repairing the turbine unlike the prior art.

The present invention can prevent the casters from being damaged by the load by allowing the casters of the positioned frames to be spaced apart from the floor so that the stands are held in contact with the floor.

In addition, the present invention can detect whether or not the rotor shaft is positively positioned at an intermediate position of the pair of support rollers through the sensor, thereby preventing the eccentric load of the support roller from being generated.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a perspective view of a rotary rotor stand according to an embodiment of the present invention supporting a rotor shaft of a turbine.
2 is a front view of a rotary type rotor stand according to an embodiment of the present invention.
3 is a rear view of a rotary rotor stand according to one embodiment of the present invention.
4 is a side view of a rotary rotor stand according to one embodiment of the present invention.
5 is a use state diagram of a rotary type rotor stand according to an embodiment of the present invention.

Hereinafter, an embodiment of a rotary type rotor stand according to the present invention will be described with reference to the accompanying drawings. In this process, the thicknesses of the lines and the sizes of the components shown in the drawings may be exaggerated for clarity and convenience of explanation. In addition, the terms described below are defined in consideration of the functions in the present invention, and this may vary depending on the intention or custom of the user, the operator. Therefore, definitions of these terms should be made based on the contents throughout this specification.

2 is a front view of a rotary type rotor stand according to an embodiment of the present invention, and FIG. 3 is a front view of the rotary type rotor stand according to one embodiment of the present invention. Fig. 3 is a rear view of the rotary rotor stand according to the example; Fig.

FIG. 4 is a side view of a rotary rotor stand according to one embodiment of the present invention, and FIG. 5 is a state of use of a rotary rotor stand according to an embodiment of the present invention.

1 to 5, a rotary type rotor stand 100 according to an embodiment of the present invention includes a frame 110, a support roller 120, and a roller cover 130.

In particular, the rotary rotor stand 100 is rotatably supported on the rotor shaft 20 extended to both sides of the turbine 10, and is provided to perform a repair operation of the turbine 10 at a ground level or at a low height .

The frame 110 forms the outer shape of the rotary rotor stand 100 and is made of metal or cast iron so as to sufficiently support the load bearing turbine 10 and the rotor shaft 20.

The frame 110 is positioned corresponding to each of the rotor shafts 20 extending to both sides of the rotor. Thus, the frame 110 is positioned on both sides in the axial direction of the rotor. Of course, each of the frames 110 can be deformed into various shapes.

Further, the support roller 120 is rotatably provided on the upper side of each of the frames 110. The support roller 120 is provided so as to be circumscribed with the rotor shaft 20. In particular, at least one pair of the support rollers 120 is provided so as to stably support and support the rotor shaft 20. For convenience, the support rollers 120 are shown as a pair positioned on the same plane. Therefore, the rotor shaft 20 is simultaneously circumscribed and supported by the pair of support rollers 120. [

The frame 110 is provided with a bracket 112 on the upper side so that the support roller 120 can be rotatably installed.

At this time, the support roller 120 is made of a metal material to firmly support the high-speed rotor shaft 20. As a result, the support roller 120 may damage the circumferential surface of the rotor shaft 20.

Thus, the support roller 120 forms the roller cover 130 on the circumferential surface in order to protect the circumscribed rotor shaft 20 and the support roller 120. The roller cover 130 is made of MC Nylon to protect the circumferential surface of the rotor shaft 20.

On the other hand, any one of the support rollers 120 of at least one pair of support rollers 120 must be forcibly rotated. The rotor shaft 20 and the other support roller 120 are rotated by friction.

Therefore, any one of the support rollers 120 has the rotary member 140 on one side in the axial direction. The rotating member 140 is connected to the driving motor 160 and the power transmitting member 150. Thus, when the driving motor 160 is driven, the rotating member 140 receives rotational force from the power transmitting member 150. [ The supporting roller 120 rotates in conjunction with the rotating member 140. Here, the rotary member 140 may be variously applied to gears, sprocket wheels, etc., and the power transmitting member 150 may be variously applied to belts, chains, and the like.

Particularly, the turbine 10 is lifted by a crane (not shown) or the like, and then each of the rotor shafts 20 descends to be in contact with the corresponding support roller 120.

At this time, the rotor shaft 20 must be placed in contact with the support roller 120 so as to distribute the load equally to the pair of support rollers 120. Thus, the frame 110 must be fine and easily positionable so that the central axis of the rotor shaft 20 is located at an intermediate position between the parallel center axes of the pair of support rollers 120. [

Therefore, the frame 110 located at at least one side of each of the frames 110 corresponding to both sides of the rotor shaft 20 is further provided with a caster 200 for facilitating positional movement.

For the sake of convenience, a plurality of casters 200 are provided below all the frames 110.

On the other hand, the frame 110 is rotatably supported by a rotor shaft sensor (not shown) to detect whether the rotor shaft 20 is positioned on the pair of support rollers 120 in a predetermined position, that is, the load is balanced on the pair of support rollers 120 400). The rotor shaft detection sensor 400 may be disposed on the frame 110 so as to correspond to the central position between the center axes of the pair of support rollers 120 to sense the lowermost side of the circumference of the rotor shaft 20. Of course, the rotor shaft sensing sensor 400 may sense both sides of the circumference of the rotor shaft 20.

When the rotor shaft sensing sensor 400 detects a state in which the rotor shaft 20 is properly positioned and transmits the signal to the driving motor 160, the driving motor 160 is operated to rotate the supporting roller 120 .

In addition, the rotor shaft sensor 400 is fixed to the mount 410. The holder 410 may be fixed to the frame 110 and may be configured to move the position of the rotor shaft sensor 400. [ Of course, the cradle 410 may be formed in various ways.

As a result, the frame 110 is moved by the caster 200 so that the rotor shaft 20 extending from the turbine 10 is lifted up and the rotor shaft 20 is stably circumscribed to the support roller 120 .

Thereafter, when the turbine 10 is lowered, the rotor shaft 20 is seated externally so as to distribute the load to the corresponding pair of support rollers 120. The fixed position of the support roller 120 is detected by the rotor shaft sensor 400. [

On the other hand, the caster 200 is provided with a plurality of caster 200 so that the heavy load of the frame 110 is dispersed and stably supported.

The frame 110 is formed with a plurality of receiving portions 210 along the lower edge thereof and the caster 200 is accommodated in each of the receiving portions 210.

At this time, the caster 200 is connected to be rotatable in the circumferential direction from the inside of the accommodating portion 210. Thus, the frame 110 becomes free to move in the forward direction. In particular, the caster 200 is connected to the frame 110 so as to be rotatable in a circumferential direction by ball bearings or the like.

The caster 200 is rotatably rotated on the floor while being accommodated in the receiving portion 210, so that the caster 200 can be protected from the outside by the frame 110.

Of course, the caster 200 can be variously modified.

When the rotor shaft 20 is seated on the support roller 120 while the caster 200 protrudes to the lower side of the frame 110 and is in contact with the bottom of the frame 110, It can be damaged by the load of the turbine 10 including the shaft 20.

To prevent this, the caster 200 is connected to the screw 220, and the screw 220 is screwed to the frame 110 while protruding outside the frame 110. Thus, the operator selects the position of the frame 110 and then rotates the screw 220 so that the caster 200 is spaced from the floor. Thus, the frame 110 is in contact with the bottom to support the rotor shaft 20.

Further, the position of the support roller 120 may need to be finely adjusted after the frame 110 is positioned.

Thus, the position correcting unit 300 is provided.

The position correcting unit 300 includes a shaft 310, a handle 320, and a guide rail 330.

The shaft 310 is rotatably screwed to the bracket 112 while being fixed at the upper edge of the frame 110. [ In particular, the frame 110 has a supporter 312 on its upper side, and the shaft 310 is rotatably installed on the supporter 312. Of course, the supporter 312 is variously deformable, and the shaft 310 is rotatable while being fixed to the supporter 312 by the bearings.

The handle 320 is provided on an end of the shaft 310 so that an operator can easily rotate the shaft 310 easily. Of course, the handle 320 can be variously modified.

The guide rail 330 is provided between the frame 110 and the bracket 112 and serves to guide the bracket 112 that is positionally corrected with respect to the frame 110. At this time, the guide rail 330 can be applied as an 'LM guide'.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. I will understand. Therefore, the true technical protection scope of this invention should be determined by the following utility model registration claim range.

10: turbine 20: rotor shaft
100: Rotating rotor stand 112: Bracket
120: Support roller 130: Roller cover
140: rotating member 150: power transmitting member
160: Driving motor 200: Caster
210: accommodating portion 220: screw
300: position correcting unit 310: shaft
312: supporter 320: handle
330: Guide rail 400: Rotor axis sensor

Claims (6)

A frame corresponding to each of the rotor shafts extending to both sides of the power generation turbine;
A plurality of support rollers provided on the upper side of each of the frames and circumscribed with the corresponding rotor shaft to rotate in a rolling manner; And
And a roller cover provided on a circumferential surface of the support roller to protect the support roller from the rotor shaft,
Wherein the frame further includes a caster for facilitating the movement of the frame positioned at at least one side of each of the frames corresponding to both sides of the rotor shaft.
The method according to claim 1,
The frame has a plurality of receiving portions formed along a lower edge thereof;
Wherein the caster is connected to the inside of the accommodating portion so as to be rotatable in a circumferential direction so that the direction of movement of the frame is easy to be set, and the casters are accommodated inside the accommodating portion and are rotated from the outside to the outside.
3. The method of claim 2,
Wherein the caster is connected to a screw threaded to the frame while being protruded to the outside of the frame, and is spaced from the floor by operation of the screw after positioning the frame.
The method according to claim 1,
The support roller being rotatably mounted on the bracket;
Wherein the bracket is finely position-corrected by the position correcting unit.
5. The apparatus according to claim 4,
A shaft rotatably threaded to the bracket while being fixed on the upper side of the frame;
A handle for rotating the shaft; And
And a guide rail for guiding the bracket to be positionally corrected with respect to the frame.
The method according to claim 1,
Wherein the frame comprises a rotor axis sensor for detecting the correct position of the rotor axis on the support roller.

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