KR101204974B1 - Fixation apparatus of vibration sensor for turbine generator - Google Patents

Abstract

The problem to be solved by the present invention is to provide a fixing device of a vibration sensor for a turbine generator for accurately detecting only the vibration generated by the rotation of the rotor. The fixing device of the vibration sensor for a turbine generator according to the present invention, the lower frame is fixed to the body of the pedestal, the upper frame having a rail formed in the longitudinal direction of the rotor; An upper frame coupled to the rail of the lower frame to be movable and having an inclined upper surface; A gap adjusting unit coupled to an upper surface of the upper frame and configured to adjust a gap between the rotor and the vibration sensor according to the shape of the rotor; An angle adjusting unit coupled to one end of the gap adjusting unit and configured to adjust an angle formed by the rotor and the vibration sensor according to the shape of the rotor; And a fixing part coupled to one end of the angle adjusting part and having a fixing groove to which the vibration sensor is fixed. According to the present invention, by fixing the fixing device of the vibration sensor for the turbine generator to the body of the pedestal and by coupling the respective components of the vibration sensor fixing device for the turbine generator through the bolt, due to the vibration generated by the incidental rotation as the rotor rotates This has the advantage of minimizing the impact. Therefore, the vibration sensor fixed to the vibration sensor fixing device for the turbine generator has an effect that can accurately detect only the vibration by the rotation of the rotor.

Description

Fixation apparatus of vibration sensor for turbine generators

The present invention relates to a device for fixing a vibration sensor for a turbine generator, more specifically, turbine power generation for accurately detecting only the vibration generated by the rotation of the rotor by minimizing the effect of the vibration caused by the incidental rotation as the rotor rotates. The present invention relates to a device for fixing a vibration sensor for a machine.

Turbine is one of the key facilities of the power plant. Steam turbines are mainly used in thermal and nuclear power plants. A steam turbine is a rotary power engine that extracts energy from the flow of steam. The steam turbine strikes a turbine blade that rotates steam, which is ejected and expanded by high temperature and high pressure steam from a nozzle or a fixed blade, and rotates the shaft by impulse or reaction. It is to let.

When the production of the steam turbine is completed, the performance of the steam turbine is measured through a balancing test. At this time, the balance of the rotor was tested by detecting vibration generated as the rotor rotates.

In order to test the balancing of the steam turbine, the steam turbine is placed on a pedestal and the steam turbine is supported by one or more pedestals since it has a considerable weight and length. The pedestal is composed of a body portion and the upper portion directly supporting the rotor of the steam turbine, conventionally fixed the vibration sensor to the fixing device coupled to the upper portion of the pedestal to detect the vibration generated as the rotor rotates.

In addition, since the upper part of the pedestal directly supports the rotor, the upper part of the pedestal vibrates due to the vibration generated as the rotor rotates. Due to the vibration of the upper pedestal, the fixing device coupled to the upper part also vibrates and the vibration is detected by the vibration sensor fixed to the fixing device. That is, the vibration sensor is for detecting only the vibration generated by the rotation of the rotor, but according to the conventional method detects not only the vibration generated by the rotation of the rotor, but also incidentally occurring at the top of the pedestal, accurate vibration There was a problem that cannot be detected.

The problem to be solved by the present invention is to provide a fixing device of a vibration sensor for a turbine generator for accurately detecting only the vibration generated by the rotation of the rotor.

In addition, the problem to be solved by the present invention is to provide a fixing device of a vibration sensor for a turbine generator for easily adjusting the distance between the rotor and the sensor.

In addition, the problem to be solved by the present invention is to provide a fixing device of a vibration sensor for a turbine generator for easily adjusting the angle between the rotor and the sensor.

The fixing device of the vibration sensor for the turbine generator, the lower frame is fixed to the body of the pedestal, the upper frame having a rail formed in the longitudinal direction of the rotor; An upper frame coupled to the rail of the lower frame to be movable and having an inclined upper surface; A gap adjusting unit coupled to an upper surface of the upper frame and configured to adjust a gap between the rotor and the vibration sensor according to the shape of the rotor; An angle adjusting unit coupled to one end of the gap adjusting unit and configured to adjust an angle formed by the rotor and the vibration sensor according to the shape of the rotor; And a fixing part coupled to one end of the angle adjusting part and having a fixing groove to which the vibration sensor is fixed.

In addition, the upper surface of the upper frame is preferably formed with a first coupling groove for coupling with the gap adjusting portion.

In addition, the gap adjusting portion has a shape of a square pillar, the side of the square pillar is formed with an elliptical first adjustment groove for adjusting the distance between the rotor and the vibration sensor, the bottom surface of the square pillar is the angle adjustment It is preferable to form stepped inward to join the portion.

In addition, the gap adjusting portion, having one or more first adjustment groove, it is preferable to be coupled to the upper frame through the first adjustment groove.

In addition, the angle adjusting portion has a T-shape protruding from one side of the square pillar, the second projection is formed in the elliptical second adjustment groove for adjusting the angle in the protruding portion of the square pillar, the other It is preferable that a fifth coupling groove is formed on the side to engage with the fixing part.

In addition, the fixing portion has a shape of a flat plate, it is preferable that an elliptical third adjustment groove for adjusting the position of the vibration sensor in the longitudinal direction of the rotor is formed.

In addition, the fixing portion has one or more fixing grooves, it is preferable that the fixing groove is formed along the longitudinal direction of the rotor.

According to the present invention, by fixing the fixing device of the vibration sensor for the turbine generator to the body of the pedestal and by coupling the respective components of the vibration sensor fixing device for the turbine generator through the bolt, due to the vibration generated by the incidental rotation as the rotor rotates This has the advantage of minimizing the impact. Therefore, the vibration sensor fixed to the vibration sensor fixing device for the turbine generator has an effect that can accurately detect only the vibration by the rotation of the rotor.

In addition, by providing a gap adjusting portion, there is an advantage that the gap between the rotor and the vibration sensor can be easily adjusted so that the rotor and the vibration sensor maintain an appropriate distance according to the shape of the rotor.

In addition, by having an angle adjusting unit, there is an advantage that the angle between the rotor and the vibration sensor can be easily adjusted to maintain the proper angle between the rotor and the vibration sensor according to the shape of the rotor.

1 is a perspective view showing an embodiment of a fixing device of a vibration sensor for a turbine generator of the present invention.
Fig. 2 is an exploded perspective view of Fig. 1; Fig.
3 is a state diagram used in FIG.

Hereinafter, a preferred embodiment of a fixing device of a vibration sensor for a turbine generator will be described in detail with reference to the accompanying drawings. In the following description, well-known functions or constructions are not described in detail since they would obscure the invention in unnecessary detail.

1 and 2 showing an embodiment of the fixing device 10 of the vibration sensor for a turbine generator according to the present invention, the present invention is fixed to the body of the pedestal 300, the upper surface of the rotor 200 in the longitudinal direction A lower frame 20 having a rail 21 formed as a shape; An upper frame 30 coupled to the rail 21 of the lower frame 20 so as to be movable and having an inclined upper surface; It is coupled to the upper surface of the upper frame 30, the gap adjusting unit 40 for adjusting the distance between the rotor 200 and the vibration sensor according to the shape of the rotor 200; An angle adjuster 50 coupled to one end of the gap adjuster 40, for adjusting an angle formed by the rotor 200 and the vibration sensor according to the shape of the rotor 200; And a fixing part 60 coupled to one end of the angle adjusting part 50 and having a fixing groove 62 to which the vibration sensor is fixed.

The lower frame 20 is to couple the fixing device 10 of the vibration sensor for the turbine generator to the main body of the pedestal 300, one side of the lower frame 20 is fixedly coupled to the main body of the pedestal 300 , The upper surface is coupled to the upper frame (30). In this case, the lower frame 20 may be coupled to the main body of the pedestal 300 using bolts or rivets, and may be coupled to the lower frame 20 and the pedestal 300 by welding. In addition, the upper frame 30 is coupled to the lower frame 20 to be movable in the longitudinal direction of the rotor 200.

That is, the rail 21 is formed on the upper surface of the lower frame 20 in the longitudinal direction of the rotor 200, and the upper frame 30 is coupled to the rail 21 formed in the lower frame 20 to be movable. In addition, it is preferable that one or more rails 21 are formed. According to FIG. 1, three rails 21 are formed on the upper surface of the lower frame 20, and one upper frame is formed on the three rails 21. 30 are coupled to be movable.

In addition, one upper frame 30 may be coupled to the lower frame 20, or two upper frames 30 may be coupled to each other. That is, when the two upper frames 30 are coupled to the lower frame 20, the respective upper frames 30 are coupled to face each other. At this time, the rail 21 formed in the lower frame 20 is also formed corresponding to the number of the upper frame 30.

For example, when two upper frames 30 are coupled to the lower frame 20, six rails 21 are formed in the lower frame 20, and three rails 21 have one upper frame ( It is coupled to the moveable 30 and the remaining three rails 21 are coupled to the other upper frame 30 to be movable.

As described above, according to the embodiment of the present invention, since the fixing device 10 of the vibration sensor for the turbine generator is fixedly coupled to the main body of the pedestal 300, the conventional fixing device coupled to the upper portion of the pedestal 300 Alternatively, since the influence of the vibration generated by the incident as the rotor 200 rotates can be minimized, the vibration sensor 100 can accurately detect only the vibration caused by the rotation of the rotor.

The lower surface of the upper frame 30 is coupled to the lower frame 20 so as to be movable, and the upper surface is formed to be inclined and coupled to the gap adjusting unit 40. The lower surface of the upper frame 30 is formed to extend a predetermined length in the horizontal direction, the second coupling groove 32 for engaging with the lower frame 30 is formed in the extended portion. The second coupling groove 32 is formed to correspond to the position of the rail 21 formed on the upper surface of the lower frame 30, the upper frame 30 by using the second coupling groove 32 and the rail 21 Coupling to the lower frame 20 to be movable. In addition, the second coupling groove 32 is preferably provided with one or more in order to improve the coupling force of the upper frame 30 and the lower frame 20.

The upper surface of the upper frame 30 is inclined at a predetermined angle, the inclined portion of the upper surface is formed with a first coupling groove 31 for coupling with the gap adjusting portion 40. The first coupling groove 31 is formed in a direction perpendicular to the longitudinal direction of the rotor 200, it is preferable that at least one is provided to improve the coupling force of the upper frame 30 and the gap adjusting portion 40. In addition, the upper frame 30 and the gap adjusting portion 40 is preferably fixed using a bolt.

The gap adjusting unit 40 is coupled to the inclined upper surface of the upper frame 30, and to adjust the gap between the rotor 200 and the vibration sensor 100 according to the shape of the rotor 200. The interval adjusting part 40 has a shape of a square pillar having a longer side than a bottom surface, and a first adjusting groove 41 is formed on the side of the square pillar to adjust the distance between the rotor 200 and the vibration sensor 100. . The first adjusting groove 41 is formed through the side of the gap adjusting portion 40, and has an oval shape.

In addition, the first adjusting groove 41 is preferably formed at least one in order to easily adjust the interval between the rotor 200 and the vibration sensor 100. In addition, since one or more first adjusting grooves 41 are formed, the coupling force is further improved because the upper frame 30 and the gap adjusting unit 40 may be coupled using a plurality of bolts.

By forming the first adjustment groove 41 in an elliptical shape, since the gap adjusting portion 40 can adjust the position coupled to the upper frame 30, the gap between the rotor 200 and the vibration sensor 100 can be easily adjusted. Can be.

In addition, one end of the gap adjusting portion 40 is formed to be stepped inward, and a third coupling groove 42 for coupling the gap adjusting portion 40 and the angle adjusting portion 50 to the stepped portion is formed. That is, the angle adjusting unit 50 is inserted into the stepped end of the gap adjusting unit 40, and the gap adjusting unit 40 and the angle adjusting unit 50 are coupled to each other through the third defect groove 42. At this time, the gap adjusting unit 40 and the angle adjusting unit 50 are coupled using a bolt. In addition, one or more third coupling grooves 42 are preferably formed, and two third coupling grooves 42 are formed in the gap adjusting part 40 illustrated in FIG. 2.

By providing the gap adjusting unit 40 as described above, the rotor 200 and the vibration sensor 100 of the rotor 200 and the vibration sensor 100 to maintain an appropriate interval according to the shape of the rotor 200, There is an advantage that the interval can be easily adjusted.

The angle adjuster 50 is inserted into and coupled to the stepped end of the gap adjusting unit 40, and adjusts an angle formed by the rotor 200 and the vibration sensor 100 according to the shape of the rotor 200. The angle adjusting unit 50 has a T-shaped shape in which one side of the square pillar protrudes, and the fifth coupling groove 53 for coupling the gap adjusting unit 40 and the angle adjusting unit 50 to the protruding portion. ) And a second adjusting groove 51 for adjusting an angle formed by the rotor 200 and the vibration sensor 100 is formed. In addition, the second adjustment groove 51 also serves to fix the gap adjusting portion 40 and the angle adjusting portion 50.

The fifth coupling groove 53 is formed on the inner side than the second control groove 51 and is formed to correspond to the third coupling groove 42 located on the outer side of the gap adjusting portion 40. That is, the interval adjusting part 40 and the angle adjusting part 50 are fixedly coupled through the fifth coupling groove 54 and the third coupling groove 42, and are fixedly coupled using bolts.

The second adjusting groove 51 is formed to have a long oval shape in the longitudinal direction, and is formed to correspond to the third coupling groove 42 located inside the gap adjusting portion 40. The angle adjusting unit 50 may be rotated about the fifth coupling groove 53, and the angle adjusting unit 50 is rotated to adjust the angle formed by the rotor 200 and the vibration sensor 100, After the adjustment is completed, the second adjustment groove 51 and the third coupling groove 42 is fixedly coupled using a bolt. In addition, the second adjustment groove 51 is preferably formed to be curved in order to easily adjust the angle between the rotor 200 and the vibration sensor 100.

In addition, a fourth coupling groove 52 is formed on the other side of the angle adjusting unit 50 that does not protrude. The fourth coupling groove 52 is for fixing the angle adjusting unit 50 and the fixing unit 60 to be fixed, and is formed to correspond to the third adjusting groove 61 of the fixing unit 60. In addition, the fourth coupling groove 52 is preferably formed at least one in order to improve the coupling force of the angle adjusting unit 50 and the fixing unit 60, the angle adjusting unit 50 and the fixing unit 60 is fourth Fasten the bolts to the coupling groove 52 and the third control groove 61 by fastening.

By providing the angle adjuster 50 as described above, the rotor 200 and the vibration sensor 100 to maintain the proper angle according to the shape of the rotor 200 and the vibration sensor 100, There is an advantage that the angle can be easily adjusted.

The fixing part 60 has a shape of a flat plate, and the third adjusting groove 61 and the fixing groove 62 are formed. The third adjustment groove 61 is formed in an elliptical shape to adjust the position of the vibration sensor 100 in the longitudinal direction of the rotor 200. That is, the third adjustment groove 61 is formed to correspond to the fourth coupling groove 52 of the angle adjustment unit 50, the fixing portion 60 using the third adjustment groove 61, the angle adjustment unit 50. Adjust the position where it is combined with). After that, the fixing part 60 and the angle adjusting part 50 are fixed to the third adjusting groove 61 by fastening the bolts to the fourth coupling groove 52.

The fixing groove 62 is for fixing the vibration sensor 100, one or more formed in the fixing portion (60). That is, since the plurality of fixing grooves 62 are formed in the fixing unit 60, the positions in which the vibration sensor 100 is fixed may vary depending on the shape of the rotor 200.

The structure and function of the fixing device of the vibration sensor for a turbine generator according to the present invention have been described in detail. Hereinafter will be described in detail the operating state of the fixing device of the vibration sensor for a turbine generator of the present invention.

3 is a view illustrating a state of use of the present invention, wherein the fixing device 10 of the vibration sensor for a turbine generator is fixedly coupled to the main body of the pedestal 300 and fixed to the fixing device 10 of the vibration sensor for a turbine generator. The vibration sensor 100 detects vibration generated by the rotation of the rotor 200. At this time, one upper frame 30 is coupled to the lower frame 20 or two upper frames 30 are coupled, and when the two upper frames 30 are coupled, each upper frame 30 is lowered to face each other. Is coupled to the frame 20.

Since the upper frame 30 is coupled to the rail 21 of the lower frame 20 so as to be movable in the longitudinal direction of the rotor 200, the rotor 200 is moved by moving the upper frame 30 according to the shape of the rotor 200. Place it in the proper place to detect vibration. When the position adjustment of the upper frame 30 is completed, the lower frame 20 and the upper frame 30 are fixedly coupled using the second coupling groove 32.

After the position adjustment of the upper frame 30 is completed and the upper frame 30 is fixedly coupled to the lower frame 20, the gap between the rotor 200 and the vibration sensor 100 is adjusted using the gap adjusting unit 40. Adjust That is, the vibration sensor 100 adjusts the distance between the rotor 200 and the vibration sensor 100 in order to easily detect the vibration of the rotor 200, and at this time, the distance between the rotor 200 and the vibration sensor 100 Accordingly, the gap adjusting unit 40 is positioned on the upper frame 30. Since the gap adjusting part 40 is formed with an elliptical first adjusting groove 41, the gap adjusting part 40 is positioned at an appropriate position by using the first adjusting groove 41, and the upper frame 30 is disposed. The gap adjusting unit 40 is fixedly coupled to the first control groove 41 and the first coupling groove 31 by fastening a bolt.

After the position adjustment of the vibration sensor 100 is completed using the gap adjusting unit 40, the gap adjusting unit 40 is fixedly coupled to the upper frame 30, and the rotor (using the angle adjusting unit 50) is used. 200) and the angle formed by the vibration sensor 100 is adjusted. That is, the vibration sensor 100 adjusts the angle formed by the rotor 200 and the vibration sensor 200 so that the vibration of the rotor 200 can be easily detected. 53) by rotating the center to adjust the angle formed between the rotor 200 and the vibration sensor 100. After the adjustment of the angle is completed, the angle adjusting unit 50 and the gap adjusting unit 40 is fixed by fastening the bolt to the second adjusting groove 52 and the third coupling groove 42.

After the adjustment of the angle formed by the rotor 200 and the vibration sensor 100 by using the angle adjuster 50, fixedly coupled to the angle adjuster 50 to the gap adjusting unit 40, 60) to adjust the position of the vibration sensor (100). At this time, the position of the vibration sensor 100 may be adjusted using the third adjustment groove 61 of the fixing part 60, and the position of the vibration sensor 100 may be adjusted using the fixing groove 62. That is, since the third adjustment groove 61 is formed in an oval shape, the position of the vibration sensor 100 is adjusted by adjusting the position where the fixing part 60 is coupled to the angle adjusting part 50 by using the third adjustment groove 61. Can be adjusted. In addition, when one or more fixing grooves 62 are formed in the fixing part 60, the vibration sensor 100 may be fixed to the fixing grooves 62 formed at appropriate positions to adjust the position of the vibration sensor 100. .

As described above, but described in one embodiment of the present invention, the technical idea of the present invention is not limited to the one embodiment, it is possible to implement a variety of fixing device for the vibration sensor for a turbine generator in a range not departing from the technical idea of the present invention. .

10... Fixing device for vibration sensor for turbine generator
20... Underframe
21 ... rail
30 ... Upper frame
31 ... First coupling groove
32 ... Second coupling groove
40 ... Spacing part
41... 1st adjusting groove
42 ... 3rd engaging groove
50... Angle adjusting portion
51 ... 2nd adjusting groove
52 ... 4th coupling groove
53 ... 5th coupling groove
60 ... [0035]
61... 3rd adjusting groove
62 ... Fixing groove

Claims (7)

A lower frame 20 fixed to the body of the pedestal 300 and having a rail 21 formed in a longitudinal direction of the rotor 200 on an upper surface thereof;
An upper frame 30 coupled to the rail 21 of the lower frame 20 so as to be movable and having an inclined upper surface;
It is coupled to the upper surface of the upper frame 30, the gap adjusting unit 40 for adjusting the distance between the rotor 200 and the vibration sensor 100 according to the shape of the rotor 200;
An angle adjusting unit 50 coupled to one end of the gap adjusting unit 40 for adjusting an angle formed by the rotor 200 and the vibration sensor 100 according to the shape of the rotor 200; And
It is coupled to one end of the angle adjusting unit 50, the fixing device of the vibration sensor for a turbine generator, characterized in that it comprises a fixing part (60) having a fixing groove (62) to which the vibration sensor (100) is fixed. The method of claim 1,
The upper surface of the upper frame 30 is fixed to the vibration sensor for a turbine generator, characterized in that the first coupling groove 31 is formed for coupling with the gap adjusting portion (40). According to claim 1, wherein the gap adjusting portion 40,
It has a shape of a square pillar, an elliptical first adjustment groove 41 for adjusting the distance between the rotor 200 and the vibration sensor 100 is formed on the side of the square pillar, the bottom surface of the square pillar Fixing device of a vibration sensor for a turbine generator, characterized in that the step is formed to be stepped inward to couple the angle adjuster (50). The method of claim 3, wherein the gap adjusting portion 40,
Fixing device of a vibration sensor for a turbine generator having at least one first adjusting groove (41), and coupled to the upper frame (30) through the first adjusting groove (41). According to claim 1, The angle adjustment unit 50,
One side of the square pillar has a tee (T) shape protruding, an elliptical second adjustment groove 51 for adjusting the angle is formed in the portion protruding the square pillar, the other side of the square pillar A fixing device of a vibration sensor for a turbine generator, characterized in that the fifth coupling groove (53) for coupling with the fixed portion (60) is formed. The method of claim 1, wherein the fixing part 60,
Fixed in the turbine generator vibration sensor having a flat plate shape, characterized in that the third adjustment groove 61 of the elliptical for adjusting the position of the vibration sensor 100 according to the longitudinal direction of the rotor 200 is formed. Device. The method of claim 1, wherein the fixing part 60,
At least one fixing groove 62, wherein the fixing groove 62 is fixed to the vibration sensor for a turbine generator, characterized in that formed along the longitudinal direction of the rotor (200).

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