KR20140139914A - Lifting device and method for drawing generator rotor shaft of combined power plant using the same - Google Patents

Abstract

Disclosed is a method for drawing a generator rotor shaft of a one shaft type combined power plant by using a lifting device. The method, which is to draw a generator rotor shaft in a one shaft type combined power plant where a gas turbine including an upper casing assembly and a lower casing assembly, a generator, and a steam turbine are aligned, includes the steps of providing a space for moving in the gas turbine by separating the upper casing assembly from the lower casing assembly; respectively separating a shaft of the gas turbine and a generator rotor shaft combined to a shaft of the steam turbine through flange; installing a lifting device in the generator and lifting and descending the generator by using the lifting device; holding a drawing member, which is connected to a ceiling crane, at the end of the rotor shaft exposed toward the gas turbine in the generator; drawing the rotor shaft toward the space for moving by moving the ceiling crane with the drawing member, thus, a part of the rotor shaft is drawn; and holding the drawing member at the center unit of the rotor shaft, and drawing the entire rotor shaft to lift and move the rotor shaft.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a lifting device and a method of lifting a rotor shaft of a hybrid power generation facility using the lifting device.

The present invention relates to a lifting device and a method of lifting a shaft of a generator of a uni-axial combined-cycle power plant using the lifting device, and more particularly, to a lifting device for lifting a shaft of a generator rotor, a steam turbine and a rotating shaft of a gas turbine by using a lifting device The present invention relates to a lifting device for lifting a rotor shaft by lifting a generator and reducing the weight of the rotor shaft, and a method of lifting a rotor shaft of a uni-axial combined power generation facility using the lifting device.

Generally, a combined power plant is a power generating facility that produces electricity using a combination of a gas turbine, a generator, and a steam turbine.

Such gas turbines, generators, and steam turbines are suitably used in combination. In recent years, the gas turbine, the generator, and the steam turbine are also used as a uniaxial type in which a single shaft is connected and arranged.

Fig. 1 is a diagram showing a conventional one-shaft type combined power generation facility.

The conventional uniaxial combined-cycle power generation system includes a gas turbine 2 that burns fuel supplied through a supply pipe 2 to produce primary power, and a boiler 2 that uses exhaust gas heat discharged to an outlet of the gas turbine 2, A steam turbine 4 for producing steam from the steam turbine 2 and producing secondary power through the produced steam and a steam turbine 4 which is taken in line with the gas turbine 2 and the steam turbine 4, And a generator 6 for generating electricity using rotation of a rotor shaft 8, which is coupled to the shaft 5 of the steam turbine 4 and the steam turbine 4, respectively.

Here, the steam turbine 4 may include a high-pressure steam turbine and a low-pressure steam turbine.

The rotor shaft 8 is formed to be longer than the length of the generator 6 in a configuration including a rotator installed across the center hole of the stator of the generator 6, 9 and flanges 7, 9 respectively coupled to the flanges of the flange and steam turbine shaft 5.

The unidirectional combined-cycle power plant uses the combustion energy of the fuel to drive the gas turbine 2 to generate power, generates steam through a boiler (not shown), and then supplies the steam turbine 4 And secondarily generates power.

At this time, if the unidirectional combined cycle power plant is used for a long period of time, damage may occur. Therefore, the gas turbine 2, the generator 6 and the steam turbine 4 should be periodically disassembled and the rotor shaft of the generator 4 must be maintained.

A method of drawing the rotor shaft 8 of the generator 6 in a conventional uniaxial combined cycle power plant will be described. The gas turbine 2 and a part of the steam turbine 4 on both sides of the generator 6 are disassembled and the flange of the gas turbine shaft 3 and the steam turbine shaft 5 and the flange 7 , 9), respectively.

A horizontal beam is installed on the decomposition moving path of the generator 6 and a frame for installing a crane having a trolley and a sliding device is installed on a horizontal beam Install it. Then, the generator is lifted by the lifting strap of the large-capacity crane, and the slider is transported laterally, and then the generator is placed on the floor. Then, after the rotor shaft 8 is taken out from the generator 6 by using the large-capacity crane, maintenance work such as repair of the bearing is performed.

Background Art [0002] The background art of the present invention is disclosed in Korean Patent Registration No. 0846270 entitled " Ancillary Combustion System of Combined Cycle Power Plant, Date of Registration: July 23, 2008).

In order to separate a generator from a conventional combined-cycle power plant and take out a rotor shaft, a large-capacity crane for lifting a generator must be installed on a ceiling. Therefore, workability is significantly deteriorated due to the necessity of a large- And the cost of repair increases.

Therefore, there is a need to improve this.

The present invention has been made in view of the above-described needs, and it is an object of the present invention to disassemble a flange of a shaft of a generator rotor and a steam turbine and a shaft of a gas turbine, to secure a space by lifting a generator using a lifting device The present invention provides a lifting device that can simplify the laying process by reducing the weight of the facility by pulling out the rotor shaft, and a method of lifting the rotor shaft of the uni-axial combined power generation facility using the lifting device.

Another object of the present invention is to provide a lifting device capable of easily lifting a generator even when a space for installing a lift device is not secured in a lower portion of a generator by installing a lifting portion on a bottom surface of a supporter portion mounted on a side surface of the generator, And a method of drawing a shaft of a generator of a uni-axial combined cycle power plant using the same.

According to an aspect of the present invention, there is provided a lifting device comprising: a support part provided at both sides of a housing of a generator and having a plurality of seating parts; A lift portion supported on a bottom surface of the seat portion and lifting the generator through the support portion by a lift operation; And a controller for controlling each of the elevating and lowering parts to rise and raise the same height so as to lift the generator evenly.

The support portion may include a support frame disposed on both side surfaces of the housing of the generator, the support frame having the seating portions at both side edges thereof; And a coupling member for coupling the support frame to the housing of the generator.

Further, the support portion is provided with a bending prevention frame to prevent deformation of the support frame.

Further, the seat portion is reinforced by a reinforcing frame provided above the seat portion.

The elevating portion may include a bottom plate placed on the floor; An installation block provided on the bottom plate and extending upward; And a cylinder member provided on the upper side of the installation block and contacting the bottom surface of the seating part.

Further, the installation blocks are mutually fixed by a connecting member.

In order to accomplish the above object, a method of withdrawing a rotor shaft of a generator of a uniaxial combined cycle power plant using a lifting device of the present invention comprises a gas turbine including an upper casing assembly and a lower casing assembly, a uniaxial combination comprising a generator and a steam turbine A method of withdrawing a rotor shaft of a generator from a power plant, comprising: separating the upper casing assembly from the lower casing assembly to form a moving space in the gas turbine; Separating the shaft of the gas turbine and the shaft of the steam turbine and the rotor shaft of the generator flanged together, respectively; Installing a lifting device on the generator and lifting the generator using the lifting device; Using a lifting member connected to a ceiling crane at an end of the rotor shaft exposed in the direction of the gas turbine from the generator; Moving the ceiling crane and pulling the rotor shaft toward the moving space part with the lifting member to pull out a part of the rotor shaft; And a step of hooking a central portion of the rotor shaft with a lifting member, and lifting and moving the entire rotor shaft.

In addition, the step of installing the lifting device and lifting and lowering the generator may include the steps of mounting a support frame having a seating part on both sides of the generator using a coupling member; Disposing a lifting portion on a lower portion of the seat portion; And driving the cylinder member to lift the generator through the seat portion.

The elevating portion may include a bottom plate placed on the floor; An installation block provided on the bottom plate and extending upward; And a cylinder member provided on the upper side of the installation block and contacting the bottom surface of the seating part.

Further, in the lifting device installation and the lifting and lowering of the generator, the lifting device lifts the generator at a height higher than a height at which the rotor shaft can be drawn out through the moving space portion.

Further, in the step of drawing out a part of the rotor shaft, the salient member draws 60 to 70% of the entire length of the rotor shaft.

Further, after the step of withdrawing a part of the rotor shaft, the step further comprises supporting the bottom surface of the rotor shaft using at least one supporting member.

A method of drawing a shaft of a generator rotor shaft, a shaft of a steam turbine, and a shaft of a gas turbine by disassembling a flange of a shaft of a gas turbine and lifting a generator by lifting the apparatus, Since the rotor shaft is taken out after securing it, it is possible to reduce the weight of the equipment, simplify the planing process, and reduce the inspection and repair cost.

The lifting device according to the present invention can elevate the generator at a set distance by providing a lifting portion on the bottom surface of the supporter portion mounted on the side surface of the generator so that the generator can be easily lifted even when the installation space of the lifting device is not secured in the lower portion of the generator And convenience of use can be provided.

FIG. 1 is a view showing a conventional uniaxial combined-cycle power generation facility.
2 is a perspective view of a lifting device according to an embodiment of the present invention installed in a generator of a combined power generation facility.
3 is an exploded perspective view of a lifting device according to an embodiment of the present invention.
4 is a view illustrating a lifting device of a generator with a lifting device according to an embodiment of the present invention.
FIG. 5 is a view illustrating a state in which an upper case assembly of a gas turbine is detached in a method of withdrawing a rotor shaft of a hybrid power generation facility according to an embodiment of the present invention.
6 is a view illustrating a state in which a flange is detached from a generator shaft of a hybrid power generation facility according to an embodiment of the present invention.
FIG. 7 is a state diagram in which a lifting device is installed and lifted in a generator in a method of withdrawing a rotor shaft of a hybrid power generation facility according to an embodiment of the present invention.
8 is a state diagram in which a lifting member is attached to a rotor shaft in a method of withdrawing a rotor shaft of a hybrid power generation facility according to an embodiment of the present invention.
FIG. 9 is a state diagram illustrating a portion of a rotor shaft taken out of a generator shaft of a hybrid power generation facility according to an embodiment of the present invention.
FIG. 10 is a state diagram illustrating a method of hooking and transferring a lifting member to a central portion of a rotor shaft in a method of drawing a rotor shaft of a generator of a combined-cycle power generation facility according to an embodiment of the present invention.
FIG. 11 is a flowchart illustrating a process of withdrawing a rotor shaft of a hybrid power generation facility according to an embodiment of the present invention.

Hereinafter, a lifting device according to an embodiment of the present invention and a method of withdrawing a rotor shaft of a uniaxial combined-cycle power plant using the lifting device 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 of the present invention, which 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.

FIG. 2 is a perspective view of a lifting device according to an embodiment of the present invention installed in a generator of a combined power generation facility, FIG. 3 is an exploded perspective view of a lifting device according to an embodiment of the present invention, FIG. 6 is a view showing a lifting device of a generator with a lifting device according to an embodiment. FIG.

1 to 4, a lifting apparatus 100 according to an embodiment of the present invention includes a support unit 20, a lift unit 30, and a control unit 40.

The support part 20 is provided on both sides of the housing 160 of the generator 16, which is applied to the hybrid power generation facility, and is provided with a plurality of seating parts 22, respectively.

The generator 16 is provided with a stator 162 on the inside of the housing 160 and a mounting hole 164 through which the rotor shaft 18 is inserted is formed at the central portion of the stator 162 on both sides.

The lifting device 100 of the present invention can be provided on both sides of the generator 16 since the housing 160 of the generator 16 does not have a space on the bottom.

The support portion 20 can be detachably attached to both sides of the housing 160 of the generator 16.

The seat portion 22 plays the role of supporting the load of the generator 16 when it provides the upward pressing force of the lift portion 30 to be described later.

The support portion 20 includes a support frame 24 and a coupling member 26.

The support frame 24 is disposed on both side surfaces of the housing 160 of the generator 16, and a seating portion 22 is formed at both side edges.

The support frame 24 is in the form of a lustrous plate, which serves to evenly distribute the overall weight of the generator 16 through the side of the housing 160.

It is preferable that the support frame 24 is gradually widened from the lower side to the upper side.

The coupling member 26 is a structure for coupling the support frame to the housing of the generator.

A plurality of coupling members 26 are detachably installed at predetermined intervals in the longitudinal and lateral directions to uniformly transmit the load of the housing 160 of the generator 16 to the support frame 24.

That is, as the number of the engaging members 26 is increased, the load applied to each engaging member 26 is reduced, so that breakage of the engaging member 26 can be prevented.

As described above, the installation number of the coupling member 26 and the installation position of the housing 160 of the generator 16 can be variously changed.

The support portion 20 is provided with a bending prevention frame 28 to prevent the support frame 24 from being deformed.

The bending prevention frame 28 is formed in a lattice shape on the side of the support frame 24 and functions to reinforce the load while dispersing the load when the housing 160 of the generator 16 is lifted through the support frame 24 Thereby preventing the support frame 24 from being deformed.

That is, since the bending prevention frame 28 has an effect of increasing the thickness of the support frame 24, it is possible to prevent the support frame 24 from being deformed in various forms.

The bending prevention frame 28 can be fixed to the contact surfaces between the gratings and the side surface of the support frame 24 through welding.

The seating portion 22 is reinforced while being supported by a reinforcing frame 29 provided on the upper side of the seating portion 22. [

The reinforcing frame 29 includes a vertical reinforcing frame 29a vertically joined to the upper side of the seating portion 22 and fixed and supported on the side surface of the support frame 24 and a vertical reinforcing frame 29b vertically abutting on the upper side of the vertical reinforcing frame 29a And a horizontal reinforcing frame 29b fixedly supported on the side surface of the support frame 24.

The reinforcing frame 29 can be fixed to the seating portion 22 and the support frame 24 through welding.

The elevating portion 10 is supported on the bottom surface of the seat portion 22 and lifts up the generator 16 through the support portion 20 by the lifting and lowering operation.

The elevating portion 30 includes a bottom plate 32, a mounting block 34, and a cylinder member 36.

The bottom plate 32 is formed in the shape of a square plate to distribute and support the load.

The mounting block 34 is provided above the bottom plate 32 and extends upward.

The mounting block 34 is formed in a rectangular column shape and extends upward.

The upper surface of the bottom plate 32 and the side surface of the support block 34 may be provided with reinforcing brackets 33 for reinforcing the sides of the installation block 34.

The reinforcing bracket 33 prevents the mounting block 34 from tipping over from the bottom plate 32.

The mounting block 34 can be fixed to each other by a connecting member 38.

4, the connecting member 38 may be fixed to the side surfaces of the plurality of mounting blocks 34 to prevent the mounting block 34 from being sideways apart from the reinforcing bracket 33 .

The cylinder member 36 is provided on the upper side of the mounting block 34 and is in contact with the bottom surface of the seating part 22. [ The cylinder axis of the cylinder member 36 comes into contact with the bottom surface of the seat portion 22 and pushes it upward.

At this time, a groove is formed in the bottom surface of the seating part 22 to prevent the cylinder shaft of the cylinder member 36 from being detached.

The control unit 40 controls the elevating and lowering units 30 to elevate and raise the generator 16 evenly to the same height. Since each of the lift portions 30 is provided with two cylinder members 36, all four cylinder members 36 are controlled.

FIG. 5 is a state view of separating an upper case assembly of a gas turbine in a method of withdrawing a rotor shaft of a hybrid power generation facility according to an embodiment of the present invention, FIG. 6 is a cross- 7 is a state diagram in which the lifting device 100 is installed and lifted in the generator in the method of withdrawing the rotor shaft of the hybrid power generation facility according to the embodiment of the present invention, FIG. 9 is a view illustrating a state in which a lifting member is attached to a rotor shaft in a method of withdrawing a rotor shaft of a hybrid power generation facility according to an embodiment of the present invention. FIG. 10 is a view showing a state in which the rotor shaft is taken out from the center of the rotor shaft in the method of drawing the rotor shaft of the hybrid power generation facility according to the embodiment of the present invention. The state diagram for transferring the material to give walking. FIG. 11 is a flowchart illustrating a process of withdrawing a rotor shaft of a hybrid power generation facility according to an embodiment of the present invention.

Referring to FIGS. 2 to 11, a method of withdrawing a rotor shaft of a uni-axial combined cycle power plant using a lifting device 100 according to an embodiment of the present invention will be described.

The unidirectional combined cycle power plant according to the present invention includes a gas turbine 12 including an upper casing assembly 122 and a lower casing assembly 124 and a power generator 16 and a steam turbine 14 arranged in a line, The steam generated in the boiler is supplied to the steam turbine 14 through the duct to turn the rotor shaft 18 of the generator 16 to generate electricity do.

At this time, the rotor shaft 18 of the generator 16 is connected to the shaft 13 of the gas turbine 12 and the shaft 15 of the steam turbine 14 via the flange 17 and 19, .

As described above, in the unidirectional combined cycle power plant, the generator 16 is a critical facility to be centrally managed, and the rotor shaft 8 of the long-term after-use generator 16 must be taken out to maintain the main portion of the rotor shaft 18 .

Therefore, the following drawing method is applied to draw the rotor shaft 18 from the generator 16.

Referring to Figures 5 and 11, "S10" is the distance from the lower casing assembly 124 to the upper casing assembly 122 in the gas turbine 12 to form a moving space 126 in the gas turbine 12 .

The upper casing assembly 122 and the lower casing assembly 124 may be mutually anchored in a threaded manner through the flange coupling.

The moving space portion 126 is a clearance space necessary for preventing the rotation when the rotor shaft 18 is moved to the right.

6 and 11, "S20" is the distance between the axis 13 of the gas turbine 12 and the axis 15 of the steam turbine 14 and the rotor axis of the generator 16 coupled to the flanges 17, (18), respectively.

 As a result, the rotor shaft 18 is in a state of being able to be drawn out without a portion that is caught on the right and left sides. However, since the generator 16 and the lower casing assembly 124 of the gas turbine 12 and the steam turbine 14 have the same height, they are difficult to pull out to the sides of the rotor shaft 16.

It is necessary to lift the generator 16 to solve this problem.

Referring to Figs. 7 and 11, "S30" is a step of installing a lifting device 100 on the generator 16 and lifting the generator 16 using the lifting device 100. Fig.

The lifting device installation and the generator elevating step S30 include a step S32 of mounting the support frame 24 having the mounting part 22 on both sides of the generator 16 using the coupling member 26, (S34) of placing the elevator 30 at the lower part of the seat 22 and driving the cylinder member 36 to lift the generator 16 through the seat 22 .

Here, four cylinder members 36 are provided on two sides of one side of the generator. Accordingly, the four cylinders 36 are controlled by the controller 40 so that the four shafts are operated to have the same length so that the generator 16 can be lifted and raised to a uniform height.

At this time, the elevating part 30 includes a bottom plate 32 placed on the floor, an installation block 34 provided on the upper side of the bottom plate 32 and extending upward, And a cylinder member (36) which is in contact with the bottom surface of the seat part (22).

It is preferable that the lifting device 100 lifts the generator 16 at a height higher than the height at which the rotor shaft 18 can be drawn out through the moving space portion 126 in the lifting device installation and the generator lifting step S30.

8 and 11, "S40" shows a state in which a lifting member 52 connected to the ceiling crane 50 at the end of the rotor shaft 18 exposed in the direction of the gas turbine 12 in the generator 16 is used It is a walking step.

The lifting member 52 may use at least one of a steel chain, a steel wire, or a thick rope.

9 and 11, "S50" indicates that the ceiling crane 50 is slid through the guide rail 54 and the rotor shaft 18 is moved toward the moving space portion 126 by the lifting member 52 And pulling out a part of the rotor shaft 18.

At this time, in step S50 of pulling out a part of the rotor shaft, the lifting member 52 can take out 60 to 70% of the entire length of the rotor shaft 18.

 The reason for this is that when the rotor shaft 18 is pulled out completely using the lifting member 52, the lifting member 52 is only caught at one end of the rotor shaft 18, It is possible to descend to the lower side. Further, when the rotor shaft 18 is pulled out to 50% or less by the lifting member 52, there is a disadvantage in that the central portion of the rotor shaft 18 can not be supported by the lifting member 52.

9 and 11, "S60" is a step after step S50 of withdrawing a portion of the rotor shaft, in which the bottom surface of the rotor shaft 18 is supported by one or more stiffening members 60 .

The strut member 60 includes an elongated strut member 62 provided on the rotor shaft 18 in close proximity to the lifting member 52 and an elongated strut member 62 extending from the rotor shaft 18 to the stator 162 insertion hole And a support member 64 for supporting a short length of the support member.

On the upper side of the supporting members 62 and 64, there is formed a seating groove portion 66 which coincides with the curvature of the rotor shaft 18.

The seating groove portion 66 prevents the rotor shaft 18 from being released to the strut members 62 and 64. [ The strut members 62 and 64 are formed so as to expand toward the lower side to enable stable support.

10 and 11, "S70" is a step of hooking the center portion of the rotor shaft 18 to the lifting member 52 and lifting the entire rotor shaft 18 to lift it.

At this time, the lifting member 52 can be configured to support two portions of the rotor shaft 18 in a stable manner while spreading in two rows, and to be connected to one another while being pinched upwards.

 A protective pad 56 for protecting the surface of the rotor shaft 18 may be provided between the lifting member 52 and the rotor shaft 18). The protective pad 56 may be formed of various protective plates such as wooden boards, synthetic resin boards, rubber boards, and the like.

A method of drawing a generator rotor shaft of a uniaxial combined cycle power generation facility using a lifting apparatus 100 according to the present invention is characterized in that a flange connection portion of a shaft of a rotor shaft 18 and a steam turbine 14 and a gas turbine 12 And lifting the generator 16 using the lifting device 100 to pull out the rotor shaft, so that the equipment can be lightened and the laying process can be simplified.

In other words, unlike the prior art, even if a ceiling crane of less than half of the existing capacity is used without using a large-capacity crane, it is possible to draw out the rotor shaft, thereby improving convenience, simplifying the disassembling process, can do.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. I will understand.

Accordingly, the true scope of protection of the present invention should be defined by the following claims.

12: gas turbine 14: steam turbine
16: generator 18: rotor shaft
20: Support part 22:
24: support frame 26: engaging member
28: bending prevention frame 30:
32: bottom plate 34: mounting block
36: cylinder member 38: connecting member
40: Ceiling crane 42: Lifting member
44: guide rails 50, 52:
122: upper casing assembly 124: lower casing assembly
S10 to S70: Steps of the rotor shaft withdrawal process according to the present invention.

Claims (12)

A support part provided on both sides of the housing of the generator and having a plurality of seating parts, respectively;
A lift portion supported on a bottom surface of the seat portion and lifting the generator through the support portion by a lift operation; And
And a control unit for controlling each of the lifting and lowering units to raise the lifting unit to the same height so as to lift the generator evenly.
The method according to claim 1,
The support unit includes:
A support frame disposed on both side surfaces of the housing of the generator, the support frame having the seating portions at both side edges thereof; And
And a coupling member coupling the support frame to the housing of the generator.
3. The method of claim 2,
Wherein the support portion includes a bending prevention frame to prevent deformation of the support frame.
3. The method according to claim 1 or 2,
Wherein the seat portion is reinforced by a reinforcing frame provided on the upper side of the seat portion.
The method according to claim 1,
The elevating unit includes:
A floor plate resting on the floor;
An installation block provided on the bottom plate and extending upward; And
And a cylinder member provided on the upper side of the installation block and contacting the bottom surface of the seating portion.
6. The method of claim 5,
Wherein the mounting blocks are mutually fixed by a connecting member.
CLAIMS 1. A method of withdrawing a rotor shaft of a generator in a uni-axial combined cycle power plant in which a gas turbine, a generator and a steam turbine are arranged comprising an upper casing assembly and a lower casing assembly,
Separating the upper casing assembly from the lower casing assembly to form a moving space in the gas turbine;
Separating the shaft of the gas turbine and the shaft of the steam turbine and the rotor shaft of the generator flanged together, respectively;
Installing a lifting device on the generator and lifting the generator using the lifting device;
Using a lifting member connected to a ceiling crane at an end of the rotor shaft exposed in the direction of the gas turbine from the generator;
Moving the ceiling crane and pulling the rotor shaft toward the moving space part with the lifting member to pull out a part of the rotor shaft; And
A central portion of the rotor shaft is hooked by a lifting member, and the entire rotor shaft is taken out and lifted and moved;
Wherein the lifting device comprises: a lifting device for lifting the shaft of the generator in the uniaxial combined-cycle power plant using the lifting device.
8. The method of claim 7,
The step of installing the lifting device and lifting /
Mounting a support frame having a seating part on both sides of the generator using a coupling member;
Disposing a lifting portion on a lower portion of the seat portion; And
Driving the cylinder member to lift the generator through the seat portion;
Wherein the lifting device comprises: a lifting device for lifting the shaft of the generator in the uniaxial combined-cycle power plant using the lifting device.
9. The method of claim 8,
The elevating unit includes:
A floor plate resting on the floor;
An installation block provided on the bottom plate and extending upward; And
And a cylinder member provided on the upper side of the installation block and contacting the bottom surface of the seat portion
Wherein the lifting device comprises: a lifting device for lifting the shaft of the generator in the uniaxial combined-cycle power plant using the lifting device.
8. The method of claim 7,
In the lifting device installation and generator lifting step,
Wherein the lifting device lifts the generator at a height above a height at which the rotor shaft can be drawn out through the moving space portion.
8. The method of claim 7,
In the step of withdrawing a part of the rotor shaft,
Wherein the lifting member pulls out 60 to 70% of the entire length of the rotor shaft.
8. The method of claim 7,
After the step of withdrawing a part of the rotor shaft,
Further comprising the step of supporting the bottom surface of the rotor shaft using at least one stiffening member even if the bottom surface of the rotor shaft is small.

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