KR101136831B1 - Turning device for turning a heavy bearing of the Turbine Generator - Google Patents

Abstract

The present invention relates to a turning device (10) for rotating a bearing (1) to check a heavy bearing of a turbine generator, the present invention is a rotating unit (20) for rotating a bearing (1), rotating a bearing (1) And a frame 40 constituting the basic frame of the lifting unit 30 and the turning device 10 to move up and down to a possible height. With this configuration, the present invention lifts and rotates the heavy bearing 1 for turbine generators to facilitate the rotation of the bearing 1 necessary for the bearing 1 inspection.

Turning Equipment, Bearing Inspection, Hydraulic Cylinders, Turbine Generator Bearings

Description

Turning device for turning a heavy bearing of the Turbine Generator}

The present invention relates to a heavy bearing turning device of a turbine generator, and more particularly to a bearing turning device for lifting and rotating the bearing to inspect and maintain the heavy bearing of the turbine generator.

In general, a turbine generator consists of a nozzle that discharges steam, a turbine that rotates by steam, a generator that generates electrical energy, and a bearing rotatably supporting the turbine, and is used to generate electrical energy in a thermal power plant or a nuclear power plant. do. For example, in a thermal power plant, fuel such as crude oil or heavy oil is burned in a boiler, and the generated waste gas is discharged to the chimney. The heat energy heats the boiler water in the boiler to produce high pressure and high temperature steam. This steam is sent to the turbine, where it converts its thermal energy into rotational energy. When the generator directly connected to the turbine generates electricity, thermal energy is converted into electrical energy.

In rotating machines or devices, as well as turbine generators for generating electricity in thermal power plants, bearings support the rotating rotors smoothly, which plays an important role in enabling operation and operation.

However, if the bearing supporting the rotating body is damaged or damaged, the turbine will not rotate smoothly and the turbine generator will not function properly, and if it is severely impossible to start, the performance and reliability of the turbine generator will be degraded. Management is needed. However, the bearings of turbine generators used in power plants are heavy and bulky, so it is impossible to lift or rotate them by manpower during inspection. Thus, a separate device for rotating heavy bearings was required for heavy bearing inspection of turbine generators.

This necessity has created a turbine overhead crane for elevating a heavy bearing to a predetermined position. The turbine overhead crane lifts and rotates a bearing using a lifting equipment capable of hooking and lifting the bearing.

In particular, the lifting equipment is made of a soft nylon sling to prevent damage to the shell and bevel metal of the bearing when rotating to check the bearings for precise assembly.

However, when the nylon sling used for lifting the bearing is damaged by the sharp edges of the bearing shell, there is a problem that the bearing falls during the lifting of the bearing, thereby causing the possibility of breakage of the bearing and the possibility of personal injury.

In addition, the work of rotating the bearing by the operator directly hanging on the lifting equipment is difficult to work due to the heavy weight of the bearing and requires a lot of workers to rotate the bearing, there was a problem that the work takes a long time to rotate the bearing and waste manpower .

The present invention was devised to solve the above-mentioned problems of the prior art, and an object of the present invention is to lift and rotate heavy bearings while preventing bearing breakage and human accident that may occur due to falling of bearings during heavy bearing lifting. It is to provide a turning device that can be.

In addition, the turning device replaces the work that was dependent on the manpower during the rotation of the bearing, thereby reducing the time required to rotate the heavy bearing and reducing the number of workers required for the bearing rotation, thereby preventing the waste of manpower. For the purpose of

Heavy-weight bearing turning device for a turbine generator of the present invention frame; A pair of rotating units which are coupled to both guide rails of the frame to enable vertical linear driving and rotate heavy bearings; And a pair of elevating units for elevating the pair of rotary units to a position where the bearing is rotatable.

Here, the rotation unit, the first cylinder unit for generating a linear driving force; A rack which is linearly reciprocated in response to the linear driving force of the first cylinder unit; A pinion meshed with the rack and rotated to convert the linear driving force into a rotational driving force; A sliding shaft having a mount plate detachable / combinable with the bearing and slidably mounted in the pinion and rotating the bearing when the pinion rotates; And a rotation unit support in which the first cylinder unit, the rack, and the pinion are installed.

In addition, the sliding shaft is characterized in that the length is adjusted by sliding corresponding to the diameter of the bearing.

Here, the sliding shaft has a cogwheel-shaped cross section, it is characterized in that the slideable insertion into the mounting hole of the pinion having a cogwheel-shaped cross section.

In addition, the mount plate is characterized in that it has a bolt hole corresponding to the fastening hole formed in the bearing to be coupled to the bearing by a fastening bolt.

Here, the bolt hole of the mount plate is characterized in that the elliptical to couple the fastening bolt in response to the position change of the fastening hole of the bearing.

In addition, the rotation unit support is characterized in that it comprises a rotation unit guide coupled with the guide rail to prevent the separation of the rotation unit and to guide the linear movement up and down.

The first cylinder unit may include a first hydraulic cylinder and a first piston linearly reciprocated by the first hydraulic cylinder, wherein the first piston is fixedly coupled to the rack.

In addition, the lifting unit, the lifting support coupled to the rotation unit support; And a second cylinder unit coupled to the lifting support to linearly drive the rotary unit.

The second cylinder unit may include a second hydraulic cylinder and a second piston linearly reciprocated by the second hydraulic cylinder, and the second piston is fixedly coupled to the lifting support.

In addition, the frame, the foot master for selectively fixing the turning device to the floor; Cylinder supports coupled to both sides of the frame to support the second cylinder unit; A lift support rail coupled to the frame and coupled with the lift support to guide the vertical movement of the lift support; And a guide rail coupled to the frame and coupled to the rotation unit guide to guide the linear movement of the rotation unit.

According to the heavy-weight bearing turning device for the turbine generator of the present invention, the turning device is lifted and rotated the heavy-weight bearing for the turbine generator in place of the turbine overhead crane using a nylon sling as the lifting equipment, the bearing falls due to damage of the lifting equipment This can reduce the possibility of bearing breakage and human accident.

In addition, it is possible to reduce the time required for the turning device to rotate the heavy weight bearing for turbine generators, which was dependent on the manpower, and the manpower is wasted because only the operator who operates the turning device and inspects the bearing is needed. Can be prevented.

Hereinafter, with reference to the accompanying drawings it will be described in detail with respect to the heavy-weight bearing turning device for a turbine generator according to a preferred embodiment of the present invention.

As shown in FIG. 1, a heavy bearing turning apparatus 10 for a turbine generator according to a preferred embodiment of the present invention includes a rotating unit 20, a lifting unit 30, and a frame 40. 20) and the lifting unit 30 are each provided with a pair.

2 to 6, the rotation unit 20 is coupled to each of the guide rails 44 on both sides of the frame 40, and can be linearly driven up and down to rotate the heavy bearing 1, the first cylinder Unit 21, rack 22, pinion 23, sliding shaft 24 and rotating unit support 26.

The first cylinder unit 21 generates a linear driving force, and includes a first hydraulic cylinder 21a and a first piston 21b linearly reciprocating by the first hydraulic cylinder 21a. 21b is fixedly coupled to the rack 22 to linearly reciprocate the rack 22.

The rack 22 is used to transmit the linear driving force generated in the first cylinder unit 21 to the pinion 23. The rack 22 is fixedly coupled to the first piston 21b to receive the linear driving force of the first cylinder unit 21. Reciprocating linearly. The top surface of the rack 22 is toothed to be engaged with the pinion 23.

The pinion 23 is engaged with the rack 22 and rotated to convert the linear driving force generated in the first cylinder unit 21 into rotational driving force. The outer circumference of the pinion 23 is toothed to be engaged with the rack 22.

As shown in FIGS. 2 to 4, the sliding shaft 24 has a mount plate 25 detachable / combinable with the bearing 1 and is slidably mounted inside the pinion 23. When rotating, the bearing 1 is rotated. The sliding shaft 24 is slid corresponding to the diameter of the bearing 1 is adjusted in length. In addition, the sliding shaft 24 has a gear-shaped cross section and is slidably inserted into the mounting hole 23a of the pinion 23 having a gear-shaped cross section. In addition, the cross section of the gear-shaped sliding shaft 24 is engaged with the cross-section of the gear-shaped mounting hole 23a so that the sliding shaft 24 can receive the rotational driving force of the pinion 23.

As shown in FIG. 5, the mount plate 25 provided at the distal end of the sliding shaft 24 has a bolt hole 25a corresponding to the fastening hole 2 formed in the bearing 1 so as to be engaged with the bearing 1. Equipped with. The bolt hole 25a is elliptical to couple the fastening bolt 70 in response to the positional change of the fastening hole 2 which is changed according to the size and type of the bearing 1.

The rotary unit support 26 is installed with the first cylinder unit 21, the rack 22 and the pinion 23, as shown in Figure 6 to prevent the separation of the rotary unit 20 and linear movement It includes a rotary unit guide 27 coupled with the guide rail 44 to guide.

The operation of the rotating unit 20 will be described below.

When the bearing 1 rotates clockwise, the first cylinder unit 21 receives hydraulic pressure through the flow control valve 21c at the front end and pushes the rack 22 connected to the pin to the left to the rack 22. ) Rotates the pinion 23 engaged with the clockwise clockwise to rotate the sliding shaft 24 mounted therein clockwise.

In the counterclockwise rotation of the bearing 1, the first cylinder unit 21 receives hydraulic pressure through the rear flow control valve 21d and pulls the rack 22 connected to the pin to the right. The pinion 23 engaged with 22 is rotated counterclockwise to rotate the sliding shaft 24 mounted therein counterclockwise.

As shown in FIG. 7, the elevating unit 30 elevates the rotary unit 20 to a position where the bearing 1 can rotate, and includes an elevating support 32 and a second cylinder unit 31.

The lifting support 32 is coupled to the rotation unit support 26 to transmit the linear driving force generated in the second cylinder unit 31 to the rotation unit support 26.

The second cylinder unit 31 generates a linear driving force, and includes a second piston 31b linearly reciprocating by the second hydraulic cylinder 31a and the second hydraulic cylinder 31a, and the second piston. 31b is fixedly coupled to the lifting support 32 to linearly reciprocate the lifting support 32.

The operation of the lifting unit 30 will be described below.

When the bearing 1 is raised (UP), the second cylinder unit 31 receives hydraulic pressure through the flow control valve 31c at the front end to raise the lifting support 32 coupled with the rotary unit support 26.

When the bearing 1 is lowered (D / W), the second cylinder unit 31 discharges the hydraulic pressure through the rear flow control valve 31d to lower the lifting support 32 coupled with the rotary unit support 26. Let's do it.

As shown in FIG. 8, the frame 40 forms a basic skeleton of the turning device 10, and the foot master 41, the cylinder support 42, the lifting support rail 43, and the guide rail 44 are formed. Include.

Frame 40 is made of aluminum alloy to maintain sufficient strength to support the weight of the bearing during lifting or rotation of the heavy bearing, and to reduce the weight of the equipment itself.

The foot master 41 is installed at the bottom of the frame 40 to move the turning device 10 and to firmly fix the turning device 10 to the floor by using a reaction plate during the lifting or rotation of the bearing 1. Let's do it.

The cylinder support 42 is installed on both sides of the frame 20 to support the second cylinder unit 31.

The lifting support rail 43 is coupled to the frame 40 to engage with the lifting support 32 and guides the vertical movement of the lifting support 32.

Guide rail 44 is coupled to the frame 40 is coupled to the rotary unit guide 27 and guides the vertical movement of the rotary unit 20.

In addition, the heavy-weight bearing turning device for the turbine generator of the present invention is electrically operated, the hydraulic unit 50 for supplying hydraulic pressure so that the first cylinder unit 21 and the second cylinder unit 31 can generate a linear driving force , The operation switch 60 having the UP, D / W, Turn and Return buttons for selecting the bearing lifting or rotation direction, and the fastening hole 2 of the bearing 1 and the bolt hole 25a of the mounting plate 25. It may further include a fastening bolt 70 that can be coupled to.

Referring to the overall operation of the heavy-weight bearing turning device for a turbine generator of the present invention described above are as follows.

Move the turning device 10 to the disassembled bearing 1, match the bolt hole 25a of the mounting plate 25 with the fastening hole 2 on the side of the bearing 1, and make the bolt separately (70) couples the bearing (1) and the mounting plate (25).

Connect the power to the turning device 10 and fix the turning device 10 to the floor by using a reaction plate installed in the foot master 41 so that the equipment does not shake when the bearing 1 is raised or rotated.

When the UP button of the operation switch 60 is pressed, the lifting unit 30 receives the hydraulic pressure generated from the hydraulic unit 50 to the front flow control valve 31c of the second cylinder unit 31 to bearing the rotary unit 20. (1) is raised to the rotatable position.

In this case, the lifting support rail 43 and the guide rail 44 prevent the lifting support 32 and the rotation unit 20 from being separated from the frame and guide the linear motion.

When the turn or return button of the operation switch 60 is pressed, the rotary unit 20 transfers the hydraulic pressure generated from the hydraulic unit 50 to the flow control valves 21c and 21d at the front end or the rear end of the first cylinder unit 21. By rotating the pinion 23, which is supplied with the rack 22, and thus rotating the sliding shaft 24, the bearing 1 raised to the rotatable position is rotated clockwise or counterclockwise.

The operator inspects the rotated bearing 1, in which the operator can rotate the bearing in the desired direction for inspection. The operator can also put it down on the floor for bearing 1 inspection.

When the D / W button of the operation switch 60 is pressed, the lifting unit 30 discharges the hydraulic pressure through the rear flow control valve 31d of the second cylinder unit 31 so that the bearing 1 can be lowered to the floor. Lower the rotating unit 20 to the position.

In this case, the lifting support rail 43 and the guide rail 44 prevent the lifting support 32 and the rotation unit 20 from being separated from the frame and guide the linear motion.

Remove the fastening bolt 70 which couples the bearing 1 and the mounting plate 25 which were put down, removes the reaction plate of the foot master 41 which fixed the turning apparatus 10, and turning apparatus 10 Remove from bearing.

As mentioned above, although the heavy-weight bearing turning apparatus for turbine generators of this invention was demonstrated with reference to the preferred embodiment of this invention, it is clear for those skilled in the art that correction, change, and various deformation | transformation embodiments are possible without deviating from the idea of this invention. .

1 is a perspective view of a turning device according to a preferred embodiment of the present invention;

FIG. 2 is a sectional view schematically showing the rotating unit of FIG. 1; FIG.

3 is a schematic perspective view showing the non-protruding state of the sliding shaft according to the bearing size;

4 is a schematic perspective view showing the protruding state of the sliding shaft according to the bearing size;

5 is a schematic exploded perspective view showing a coupling structure of a mount plate and a bearing;

6 is a schematic view showing a coupling structure of a guide rail and a rotating unit guide;

FIG. 7 is a perspective view of the lifting unit of FIG. 1; FIG. And

8 is a sectional view of a turning device;

<Description of the symbols for the main parts of the drawings>

1: bearing 2: fastener

10: turning equipment 20: rotating unit

21: first cylinder unit 21a: first hydraulic cylinder

21b: first piston 21c: shear flow control valve

21d: rear flow control valve 22: rack

23: Pinion 23a: Mounting Hole

24: sliding shaft 25: mount plate

25a: bolt hole 26: rotation unit support

27: rotating unit guide 30: lifting unit

31: second cylinder unit 31a: second hydraulic cylinder

31b: second piston 31c: shear flow control valve

31d: Rear flow control valve 32: Lift support

40: frame 41: foot master

42: cylinder support 43: lifting support rail

44: guide rail 50: hydraulic unit

60: switch 70: fastening bolt

Claims (11)

A frame 40 forming a basic skeleton; A pair of rotary units (20) coupled to both side guide rails (44) of the frame (40) to enable vertical linear driving and to rotate heavy bearings; And And a pair of elevating units (30) for elevating the pair of rotary units (20) to a position where the bearing is rotatable. The method according to claim 1, The rotating unit 20, the first cylinder unit 21 for generating a linear driving force; A rack 22 linearly reciprocating by receiving the linear driving force of the first cylinder unit 21; A pinion (23) engaged with the rack (22) to rotate to convert the linear driving force into a rotational driving force; A sliding shaft (24) having a mount plate (25) detachable from or coupled to the bearing and slidably mounted in the pinion (23) and rotating the bearing when the pinion (23) rotates; And And a rotating unit support (26) in which the first cylinder unit (21), the rack (22), and the pinion (23) are installed. The method according to claim 2, The sliding shaft 24 is a heavy-weight bearing turning device for a turbine generator, characterized in that the length is adjusted by sliding corresponding to the diameter of the bearing. The method according to claim 2 The sliding shaft (24) has a gear-shaped cross section, the heavy-weight bearing turning device for a turbine generator, characterized in that the slide pin is slidably inserted into the mounting hole of the pinion (23). The method according to claim 2, The mounting plate (25) is a heavy-weight bearing turning device for a turbine generator, characterized in that it comprises a bolt hole (25a) corresponding to the fastening hole formed in the bearing to be coupled to the bearing by a fastening bolt. The method according to claim 5, The bolt hole (25a) of the mount plate 25 is a heavy-weight bearing turning device for a turbine generator, characterized in that the elliptical to couple the fastening bolt in response to the position change of the fastening hole of the bearing. The method according to claim 2, The rotary unit support 26 includes a rotary unit guide 27 coupled with the guide rail 44 to prevent separation of the rotary unit 20 and to guide the linear movement up and down. Heavy bearing turning device. The method according to claim 2, The first cylinder unit 21 includes a first piston 21b linearly reciprocated by a first hydraulic cylinder 21a and the first hydraulic cylinder 21a, and the first piston 21b is Heavy-weight bearing turning device for a turbine generator, characterized in that fixed to the rack (22). The method according to claim 2, The lifting unit 30, the lifting support 32 is coupled to the rotary unit support 26; And And a second cylinder unit (31) coupled to the elevating support (32) to linearly drive the rotary unit (30) up and down. The method of claim 9, The second cylinder unit 31 includes a second hydraulic cylinder 31a and a second piston 31b linearly reciprocating by the second hydraulic cylinder 31a, wherein the second piston 31b is Heavy-weight bearing turning device for a turbine generator, characterized in that fixedly coupled with the lifting support (32). The method of claim 9, The frame 40 includes: a foot master 41 for selectively fixing the turning device to a floor; A cylinder support 42 coupled to both sides of the frame 40 to support the second cylinder unit 31; A lift support rail (43) coupled to the frame (40) to couple with the lift support (32) and to guide the vertical movement of the lift support (32); And A heavy-duty bearing turning for a turbine generator, comprising: a guide rail (44) coupled to the frame (40) and coupled to the rotary unit guide (27) to guide the vertical movement of the rotary unit (20). Device.

Images