KR101943459B1 - A sttopper for turbine rotor slip prevention - Google Patents

Abstract

The present invention relates to a stopper to prevent slip of a turbine rotor and, more specifically, to a stopper to prevent slip of a turbine rotor, which restricts slip (movement) of the turbine rotor in an axial direction when a coupling is separate and the turbine rotor is lifted in order to repair the turbine rotor connected on one shaft through the coupling, and also smoothly rotates the turbine rotor for various kinds of maintenances even if the slip of the turbine rotor is restricted. To this end, according to the present invention, the stopper to prevent slip of a turbine rotor comprises: a block body coupled to turbine equipment of both sides of the turbine rotor, wherein the turbine rotor is connected on one shaft through combination between couplings having a weight balancing groove formed along a circumferential surface; and a guide roller coupled to the block body, disposed on the weight balancing groove of the turbine rotor to restrict axial movement of the turbine rotor, and interlocked with the rotation of the turbine rotor to be rotated. The guide roller comprises a fixed guide roller fixed in the block body toward the center of the coupling, and a rotation guide roller installed on the upper side of the fixed guide roller and hinge-coupled to the block body to be able to be vertically rotated.

Description

[0001] The present invention relates to a turbine rotor slip prevention stopper,

The present invention relates to a turbine rotor slip prevention stopper, and more particularly, to a turbine rotor slip prevention stopper for preventing a turbine rotor from slipping in an axial direction during maintenance of the turbine rotor.

Turbine equipment used in power plants is a device that generates electricity by rotating the generator by converting thermal energy of steam into mechanical energy in thermal cycle using operating steam.

Turbine facilities used in power plants include steam turbines and gas turbines.

The above-mentioned turbine hits a rotating turbine blade of a high-temperature high-pressure steam blown out from a nozzle or a fixed blade and rotates the shaft by its impulsive action or recoil action.

As shown in FIG. 1, the turbine includes a rotor 10 and a plurality of low-pressure turbine rotors 20 and a high-pressure turbine rotor 10. , And the generator rotor 30 is coupled to the shaft 40 by a coupling 40 to rotate at a high speed of 3,600 rpm.

These turbines are regularly inspected to check for any abnormality. Since the failure of the turbine during operation of the power plant is directly related to the generation amount and reliability of the power generation, the preventive maintenance work is planned and performed regularly in the field.

To accomplish this, the bolts of the coupling 40, which is the coupling means between the respective rotors 10, 20 and 30, are disassembled to disassemble the turbine, and then the rotors 10, 20 and 30 are lifted from the bearings And a series of maintenance work such as alignment measurement.

At this time, as a device for lifting the rotors 10, 20 and 30, a lifting device using an oil pump is used, and the lifting device is disclosed in the applicant's "Registration Utility Model No. 20-0461263".

That is, after the bolts are loosened to disassemble the coupling 40, the rotors 10, 20, and 30 are lifted using a lifting device so that maintenance work of various kinds can be performed.

However, as described above, in a state where the rotors 10, 20, 30 are lifted using the lifting device, the rotors 10, 20, 30 slip in the axial direction according to the axial tilt, .

In order to prevent this, the exciter of the power generation unit is disassembled and a device such as a dummy is installed to prevent the rotor from moving. However, this is troublesome and inconvenient, and can lead to a delay in the entire process of planned preventive maintenance.

Therefore, there is a demand for a stopper that prevents rotor slip from occurring regardless of the axial tilt of the rotor even after rotor lifting for rotor maintenance work.

Korea Registered Utility Model No. 20-0461263

SUMMARY OF THE INVENTION It is an object of the present invention to provide a turbine rotor having a coupling in which a weight balancing groove of a groove is formed along a circumferential surface, By preventing the occurrence of accidents during the maintenance process of the turbine rotor by preventing the movement of the rotor, it is installed on the turbine facility which is not related to the power generation process, thereby preventing the maintenance process delay and shortening the maintenance time, And to provide a turbine rotor slip prevention stopper that maximizes efficiency.

In order to achieve the above object, the present invention provides a turbine rotor comprising: a block body coupled to a turbine rotor on one side of a turbine rotor, And a guide roller coupled to the block body and positioned in the weight balancing groove of the turbine rotor to restrain the turbine rotor from moving in the axial direction and to be rotated by interlocking with the rotation of the turbine rotor, Is composed of a fixed guide roller fixed to the block body toward the center of the coupling and a turning guide roller hinge-coupled to the block body so as to be rotated up and down above the fixed guide roller. A slip prevention stopper is provided.

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Preferably, the guide roller comprises a protruding bar provided from the block body toward the coupling, and a rotating member coupled to the end of the protruding bar so as to be rotatable and positioned in the weight balancing groove of the coupling.

At this time, it is preferable that the rotating direction of the rotating member is perpendicular to the rotating direction of the rotor.

The block body may include a lower block that can be coupled to the turbine equipment and an upper block that can be installed in the lower block and pass through toward the coupling, The swing block is axially coupled to the swing block, and the swing block is installed on the swing block.

The turbine rotor slip prevention stopper according to the present invention has the following effects.

First, the stopper is installed on the turbine facility and is coupled to the weight balance groove formed in the coupling of the rotor, thereby preventing the rotor slip due to the axial tilt of the rotor during the rotor lifting for rotor maintenance.

That is, even if the shaft of the rotor is inclined, the coupling constituting the rotor is caught by the stopper, so that the rotor does not slip in the axial direction.

Accordingly, the risk of accident due to rotor slip can be prevented, and the rotor maintenance work can be stably performed.

Second, since the guide roller for guiding the rotation of the rotor to the stopper is provided, the rotation of the rotor can be smoothly performed even when the stopper supports the coupling.

Accordingly, there is an effect that various rotor maintenance operations can be carried out smoothly without restriction.

Third, the guide rollers are provided in a pair in the height direction of the coupling, and the upper guide rollers provided at the upper portion are provided to be pivotable in the upward and downward directions on the stopper, so that they can be automatically matched to the weight balancing grooves of the coupling.

That is, the upper guide roller is rotated downward by its own weight so that the coupling curvature can be automatically matched with the lower guide roller.

Thus, there is an effect that the efficiency of supporting the coupling of the guide roller can be improved regardless of the height of the guide roller.

Fourth, since there is no need to provide a stopper on the power generation unit side, it is possible to prevent the maintenance process from being delayed due to the power generation unit disassembly operation.

As a result, the maintenance process time can be shortened, so that the work productivity can be improved.

Furthermore, the construction cost can be reduced by shortening maintenance time.

Fifth, by reducing the weight and simplifying the stopper structure, it is possible to shorten the time for installing and disassembling the stopper.

In addition, the convenience of transportation and storage can be improved, and the satisfaction of the operator can be enhanced.

Figure 1 schematically illustrates a turbine installation
2 is an exploded perspective view showing a turbine rotor slip prevention stopper according to a preferred embodiment of the present invention.
3 is a perspective view showing a turbine rotor slip prevention stopper according to a preferred embodiment of the present invention.
FIG. 4 is a perspective view showing a state in which a turbine rotor slip prevention stopper according to a preferred embodiment of the present invention is installed in a turbine facility and restrains coupling of the turbine rotor. FIG.
FIG. 5 is a side elevational view showing a state in which a turbine rotor slip prevention stopper according to a preferred embodiment of the present invention is installed in a turbine facility and restrains coupling of the turbine rotor. FIG.

It is to be understood that the words or words used in the present specification and claims are not to be construed in a conventional or dictionary sense and that the inventor can properly define the concept of a term in order to describe its invention in the best possible way And should be construed in light of the meanings and concepts consistent with the technical idea of the present invention.

Hereinafter, a turbine rotor slip prevention stopper according to a preferred embodiment of the present invention will be described with reference to FIGS. 2 to 5 attached hereto.

Turbine rotor The slip prevention stopper ensures smooth maintenance work without lifting the turbine rotor when the turbine rotor is lifted using lifting equipment for turbine rotor maintenance.

The turbine rotor slip prevention stopper includes a block body 100 and a guide roller 200 as shown in FIG.

The block body 100 is configured to be detachable to the turbine equipment S provided on both sides of the turbine rotor, as a configuration for supporting the stopper.

At this time, the turbine equipment (S) refers to plates or frames provided on both sides of the turbine rotor.

The block body 100 may include a lower block 110, an upper block 120, and a swing block 130.

The block body 100 may be integrally formed, but the fixed guide roller and the rotation guide roller, which will be described later, can be separately installed.

The lower block 110 is installed in the turbine equipment S and is preferably formed in a hexahedron for a stable installation.

The lower block 110 is formed with a facility fixing hole 111 for coupling with the turbine equipment S and a block fixing hole 112 for coupling with the upper block 120.

At this time, the facility fixing hole 111 is preferably in the shape of a long hole.

This is for the purpose of facilitating the adjustment of the position of the lower block 110, which is an installation reference for the facility.

It is preferable that the facility fixing holes 111 are provided as a pair.

The block fixing hole 112 is for coupling with the upper block 120, and is preferably formed in a circular shape.

At this time, it is preferable that the block fixing hole 112 is formed in plural so that the position of the upper block 120 can be moved on the lower block 110.

On one side of the lower block 110, a coupling groove 113 for coupling a fixed guide roller to be described later is formed.

Here, the one surface refers to the surface of the turbine rotor 10 facing the coupling 40.

It is preferable that the coupling groove 113 is formed as a thread groove.

That is, the lower guide block 110 can be screwed to a later-described fixed guide roller.

The upper block 120 is configured to be provided with a rotation guide roller, which will be described later, and is detachable to the lower block 110.

The upper block 120 includes an engaging portion 121 coupled to the lower block 110 and a turning portion 122 that rotates the later described guide roller.

A bolt fixing hole 121a is formed in the coupling portion 121 so as to be coupled to the lower block 110.

The bolt fixing holes 121a are formed on both sides of the coupling portion 121 and the bolt fixing holes 121a correspond to the block fixing holes 112 of the lower block 110. [

At this time, it is preferable that the bolt fixing hole 121a is also formed as a long hole like the equipment fixing hole 111. [

The swivel portion 122 is provided for the rotation guide roller installation described later, and is formed at the center of the upper surface of the engagement portion 121.

At this time, a through hole 122a through both sides of the coupling part 40 is formed in the swivel part 122.

On both sides of the swivel portion 122, a shaft hole 122b communicating with the through hole 122a is formed.

The swing block 130 serves as an intermediary for installing a rotation guide roller to be described later on the upper block 120 and is configured to be axially coupled to the through hole 122a of the swing portion 122. [

The swing block 130 is formed to have a size that can be pivoted in the upward and downward directions on the through hole 122a, and is formed as a hexahedron.

At this time, corresponding holes 131 corresponding to the shaft holes 122b of the swivel portion 122 are formed on both sides of the swing block 130. [

With such a configuration, the swing block 130 is axially coupled to the through hole 122a of the swivel portion 122 as shown in Fig.

At this time, both end portions of the hinge pin 132 are exposed to both sides of the rotation part 122, and are not separated from the rotation part 122 through the fixing ring 133.

A coupling groove 134 for coupling with a rotation guide roller, which will be described later, is also formed on one side of the swing block 130.

At this time, it is preferable that the coupling groove 134 is screwed to the rotation guide roller, and the coupling groove 134 is formed with a thread.

Next, the guide roller 200 rests on the weight balancing groove H of the coupling so as to prevent the lifted turbine rotor from slipping through the lifting device for turbine rotor maintenance.

That is, according to the axial tilt of the turbine rotor, the lifted turbine rotor can be tilted to one side, and since the guide roller 200 is positioned in the weight balancing groove H of the coupling 40, The coupling 40 is interfered with the guide roller 200 so that no movement occurs.

At this time, the weight balancing groove H is a groove formed along the circumferential surface of the coupling 40 so that the weight can be attached to and detached from the coupling 40 to match the center of gravity of the turbine rotor.

It is preferable that the guide rollers 200 are provided in plural in the height direction of the coupling 40 so that the support force against the turbine rotor can be stabilized.

For convenience of explanation, the guide roller 200 having a pair of the fixed guide roller 210 and the rotation guide roller 220 will be described in this specification.

The fixed guide roller 210 is installed on the lower block 110 and protrudes from the lower block 110 toward the coupling 40.

The fixed guide roller 210 is preferably composed of a protruding bar 211 and a rotating member 212.

The protruding bar 211 is configured to be screwed into the coupling groove 113 of the lower block 110.

That is, a part of the outer peripheral surface of the protruding bar 211 forms a thread.

At this time, the protruding bar 211 is installed so as to protrude straight from the lower block 110, and the position where the protruding bar 211 faces is the center (center) of the coupling 40.

The rotating member 212 is disposed in the weight balancing groove H and is coupled to the protruding bar 211.

The rotating member 212 is located in the weight balancing groove H and directly contacts the coupling 40 to restrain movement of the turbine rotor.

The rotary member 212 is installed to be rotatable on the protruding bar 211.

This is for the purpose of enabling smooth rotation even in a state where the turbine rotor is restrained to the stopper.

That is, even when the turbine rotor is lifted, a rotary operation must be performed for maintenance, and the rotary member 212 restricting the coupling 40 in the weight balancing groove H is installed so as to be rotatable, The rotation of the rotor can be smoothly performed.

At this time, the rotational direction of the rotating member 212 is preferably perpendicular to the rotating direction of the turbine rotor.

That is, the axis of the rotary member 212 and the axis of the turbine rotor are set perpendicular to each other.

The rotating member 212 has an inner rolling portion 212a having a height corresponding to the depth of the weight balancing groove H and an outer rolling portion 212b having a diameter corresponding to the width of the weight balancing groove H .

The inner rolling portion 212a of the rotary member 212 is rolled along the inner surface constituting the weight balancing groove H and the outer rolling portion 212b is rolled on the outer peripheral surface of the coupling 40, do.

The rotation guide roller 220 serves to restrict the movement of the turbine rotor together with the fixed guide roller 210.

That is, since the guide roller 200 of the means for preventing the movement of the turbine rotor is additionally provided in the height direction of the coupling 40, it is possible to more stably prevent the movement of the turbine rotor.

The rotation guide roller 220 is coupled to the swing block 130 installed on the upper block 120 as described above.

The configuration of the rotation guide roller 220 is the same as that of the fixed guide roller 210, and a detailed description thereof will be omitted.

As the rotation guide roller 220 is coupled to the swing block 130, it can be rotated up and down unlike the fixed guide roller 210, and the rotation operation is performed by the weight of the rotation guide roller 220 As shown in FIG.

As the rotation of the rotation guide roller 220 is performed in this way, the rotation guide roller 220 is naturally directed toward the center of the coupling 40 even if it is located off the center of the coupling 40.

That is, since the position of the rotation member 222 of the rotation guide roller 220 is always positioned at the rotation radius of the coupling 40, the role of the guide roller 200 can be effectively performed.

With this structure, regardless of the height of the rotation guide roller 220, the pair of guide rollers 200 corresponds to the curvature of the outer peripheral surface of the coupling 40 as shown in Fig.

On the other hand, the stopper having such a structure is provided so as to be installed on both sides of the turbine rotor in order to stably support the turbine rotor.

That is, two stoppers are provided in one set to prevent turbine rotor slip.

Hereinafter, the operation of the turbine rotor slip prevention stopper constructed as described above will be described.

The fixing guide roller 210 is fixed to the coupling groove 113 of the lower block 110 by screwing.

In addition, the rotation guide roller 220 is engaged with the upper block 120.

To this end, a rotation guide roller 220 is screwed into the coupling groove 134 of the swing block 130, and the swing block 130 is positioned in the through hole 122a of the upper block 120.

Thereafter, the hinge pin 132 is passed through the shaft hole 122b and the corresponding hole 131, and both ends of the hinge pin 132 are fixed to both sides of the hinge pin 122 by using the fixing ring 133. [

Next, the lower block 110 provided with the fixed guide roller 210 is fixed to the turbine equipments on both sides of the turbine rotor.

And the bolts B are passed through the facility fixing holes 111 to fix the lower block 110 to the turbine equipment.

At this time, the position of the lower block 110 is adjusted in consideration of the position of the weight balancing groove H of the coupling 40.

At this time, it is understood that the position adjustment of the lower block 110 can be performed by the facility fixing hole 111 in the form of a long hole.

Next, the upper block 120 is stacked on the lower block 110, and then the upper block 120 is fixed to the lower block 110.

To this end, the bolt fixing holes 121a of the upper block 120 are aligned with the block fixing holes 112 of the lower block 110, and then the bolts B are used to fasten the bolts.

This completes the installation of the stopper in the turbine installation.

Next, after dismantling the neighboring turbine rotor-to-rotor coupling 40, the lifting device is used to lift the turbine rotor.

At this time, a pair of guide rollers 200 are positioned in the weight balancing groove H of the coupling 40.

At this time, the fixed guide roller 210 faces the center of the coupling 40, and the rotation guide roller 220 is also rotated downward by the rotation of the swing block 130 due to its own weight, The position is set while being in contact with the outer circumferential surface of the ring 40. [

This is because the rotation guide roller 220 also faces the center of the coupling 40 so that the rotation guide roller 220 and the fixed guide roller 210 correspond to the curvature of the outer peripheral surface of the coupling 40. [

Even if the axial inclination of the turbine rotor is inclined during the lifting of the turbine rotor by the lifting device, the rotational member 212 of the guide roller 200 is caught on the inner surface of the weight balancing groove H Therefore, the movement of the turbine rotor, that is, the slip does not occur.

Meanwhile, as described above, the turbine rotor maintenance preparation operation is completed, and the turbine rotor idles to measure the alignment and the like of the turbine rotor.

At this time, since the rotating member 212 of the guide roller 200 is rotated on the outer peripheral surface of the weight balancing groove H and the coupling 40, the rotation of the turbine rotor can be smoothly performed.

That is, even if the turbine rotor is spaced apart from the bearing below the turbine rotor for maintenance of the turbine rotor, since the rotary member 212 of the guide roller 200 may serve as a bearing, It is possible to smoothly perform idling.

Accordingly, the slip of the turbine rotor can be prevented through the guide roller 200, and the rotation of the turbine rotor can be smoothly performed.

As described above, the turbine rotor slip prevention stopper according to the present invention prevents the turbine rotor from slipping due to the axial tilt of the turbine rotor during the turbine rotor lifting for turbine rotor maintenance, It is possible to improve the efficiency of the maintenance work by shortening the maintenance process time.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is evident that many alternatives, modifications and variations will be apparent to those skilled in the art.

100: a block body 110: a lower block
111: Equipment fixing hole 112: Block fixing hole
113, 134: coupling groove 120: upper block
121: engaging portion 121a: bolt fixing hole
122: turning part 122a: through hole
122b: shaft hole 130: swing block
131: Corresponding ball 132: Hinge pin
133: Fixing ring 200: Guide roller
210: fixed guide roller 211: protruding bar
212, 222: rotating member 212a: inner rolling part
212b: outer roller portion 220: rotation guide roller

Claims (5)

There is provided a turbine rotor connected with one shaft through a coupling between couplings in which a weight balancing groove is formed along a circumferential surface,
A block body coupled to turbine equipment on both sides of the turbine rotor;
And a guide roller coupled to the block body and positioned in the weight balancing groove of the turbine rotor to restrain the turbine rotor from moving in the axial direction, the guide roller being rotatable with the rotation of the turbine rotor,
The guide roller
A fixed guide roller fixed to the block body toward the center of the coupling, and a rotation guide roller provided above the fixed guide roller and hinged to the block body to rotate up and down. stopper. delete The method according to claim 1,
The guide roller
A protruding bar provided to the coupling from the block body, and a rotating member coupled to the end of the protruding bar so as to be rotatable and positioned in the weight balancing groove of the coupling. The method of claim 3,
Wherein the rotating direction of the rotating member is perpendicular to the rotating direction of the rotor. The method according to any one of claims 1, 3, and 4,
The block body includes:
A lower block that can be coupled to the turbine facility, and an upper block that is installed in the lower block and penetrates front and rear toward the coupling,
A swing block is axially coupled to the upper block,
Wherein the rotation guide roller is installed in the swing block.

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