KR20160071275A - Damper unit for shaft - Google Patents

Abstract

A damper unit for a shaft is disclosed. According to one embodiment of the present invention, the damper unit for a shaft comprises: a cover housing of which the inside is filled with fluid and which is mounted in an end part of a rotating shaft; a mass disposed inside the cover housing; and an elastic body connecting the masses.

Description

[0001] Damper unit for shaft [0002]

The present invention relates to a damping device for damping a natural frequency due to a torsion which is provided at an end of a shaft in which a torsion due to rotation is generated. More specifically, the torsion damper is installed at a shaft end of the turbine, Shaft damper unit.

In general, all rotating machines will generate some torsional vibration even while operating stably at rated load. When starting or stopping rotating machine and when transient conditions such as sudden speed change or load change occur, Vibration occurs.

Rotors, such as rotors, for example, are used in a wide variety of mechanical and electrical components, including generators, motors and other similar devices. The rotating body has a plurality of torsional natural frequency modes and it is desirable to keep these frequency modes within a certain range for various reasons including stress, fatigue, performance, and the like.

For example, other machine elements, including generators or rotors, typically have a torsional eigenfrequency mode that is close to twice the line frequency, such that when the frequency mode approaches twice the line frequency, Such as the final stage buckets of the < / RTI >

The frequency of the current toroidal torsional mode can be varied by changing the inertia or torsional stiffness which directly affects the frequency of the rotor mode of interest.

In particular, large-scale facilities such as turbine-generators of nuclear power plants are largely affected by torsional vibrations. Recently, nuclear power plants built in or outside of the country have been equipped with turbines or generators together or separately for reasons of increased acceptance of reactor output, , It is very important to maintain safety operation through precise measurement and analysis after replacement as well as design stage in order to prevent malfunction after replacement of equipment and to ensure the soundness of low-pressure turbine final stage blade .

Turbine or generator manufacturers are required to design the equipment so that the natural frequency of the equipment is sufficiently spaced from the grid frequency to prevent excessive torsional vibration due to resonance from the design stage and to prevent breakage of equipment due to torsional vibration characteristics and torsional stress It is used by attaching a damper.

In order to minimize the torsional vibration due to the rotation of the shaft installed in the turbine, for example, the damper is provided with an additional attachment for changing the natural frequency at the end of the shaft to change the natural frequency generated by the rotation of the shaft However, the weight increase due to the adhered additionally affects the frequency generated in the other components connected to the shaft, resulting in a change to an unacceptable stress state.

Korean Patent Publication No. 10-2013-0124709

The embodiments of the present invention are intended to provide a damper unit capable of preventing damage to the shaft by changing the natural frequency of the shaft generated in accordance with rotational twist in a gas turbine, a steam turbine, or various turbines.

According to an aspect of the present invention, there is provided a cover comprising: a cover housing mounted on an end of a shaft on which rotation is performed, A weight disposed within the cover housing; And an elastic body connecting the weight to each other.

The weight body is a first to an n-th unit weight body divided into a plurality of sections along an inner circumferential direction of the cover housing.

The first through nth unit weights extend in the longitudinal direction of the cover housing along the longitudinal direction and the radially extended length r1 extend toward the center of the cover housing. do.

And the longitudinal extension length L1 is elongated relative to the radially extended length r1.

The first through n-th unit weights And are arranged in a vertically symmetrical manner.

The elastic body is characterized in that either a leaf spring or a coil spring is selectively used.

The elastic body includes first to n-th unit elastic bodies disposed radially from the center of the cover housing toward the first to n-th unit masses.

And the first to nth unit elastic bodies are rounded toward the radial direction of the cover housing.

The first to n-th unit elastic bodies are characterized in that the spring coefficient values are all constant.

The first to n-th unit elastic bodies are characterized in that the spring coefficient values are different.

And the elastic body is extended to a length corresponding to the longitudinal extension length (L1) of the first to n-th unit weight bodies.

And the elastic body is formed with an opening hole which is opened for movement of the fluid inside the cover housing.

And the opening holes are opened with different diameters.

The cover housing further includes a mounting member disposed along the circumferential direction of the cover housing facing the shaft to be mounted on the shaft.

And a control unit provided outside the cover housing and adjusting a natural frequency of the shaft by applying current to the iron powder contained in the fluid.

Embodiments of the present invention may be applied to an end of a shaft of a gas turbine or steam turbine to prevent damage to the shaft by easily adjusting the natural frequency according to the rotation of the shaft to prevent damage to the component connected to the gas turbine or steam turbine So that stable operation can be achieved.

The embodiments of the present invention can adjust the natural frequency of the shaft inevitably vibrating through the weight, the elastic body, and the fluid to damp the vibration due to the twist of the shaft.

1 is a perspective view showing a state in which a shaft damper unit according to an embodiment of the present invention is installed on a shaft;
2 is an exploded perspective view of a shaft damper unit according to an embodiment of the present invention;
3 is a perspective view showing a state in which a cover housing is separated from a damper unit for a shaft according to an embodiment of the present invention;
Figure 4 is a front view of Figure 3;
5 is a view showing a damper unit for a shaft according to another embodiment of the present invention.
6 is an operational state diagram of a damper unit for a shaft according to an embodiment of the present invention.

A structure of a damper unit for a shaft according to an embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a perspective view showing a state in which a damper unit for a shaft according to an embodiment of the present invention is installed on a shaft, FIG. 2 is an assembled perspective view of a damper unit for a shaft according to an embodiment of the present invention, 3 is a perspective view showing a state in which a cover housing is separated from a shaft damper unit according to an embodiment of the present invention, and Fig. 4 is a front view of Fig.

1 to 4, a shaft damper unit 1 according to an embodiment of the present invention is mounted on an end portion of a shaft 10, which is rotated inside a turbine provided in various power plants, Is used to adjust the natural frequency generated according to the rotation of the shaft (10) and is detachably installed at the end of the shaft (10) for facilitating inspection and repair by the operator.

The damper unit 1 includes a cover housing 100, a weight body 200 disposed inside the cover housing 100, and an elastic body 300 connecting the weight body 200 with each other, do.

The cover housing 100 is formed in a cylindrical shape and its diameter is changed according to the detailed dimensions of the weight 200 and the elastic body 300 to be described later, and the diameter and the width shown in the drawings are not necessarily limited.

The cover housing 100 includes a first housing 102 extending in a length corresponding to the longitudinal direction of the weight 200 and a second housing 106 located on the front side of the first housing 102, And a third housing 104 positioned on the rear side of the first housing 102. The second housing 106 and the third housing 104 extend in the lengthwise direction relatively shorter than the first housing 102 .

The second and third housings 106 and 104 are provided to keep the opened front and rear surfaces of the first housing 102 in a hermetically sealed state and are provided with a packing material (not shown) to prevent the leakage of the fluid filled in the cover housing 100 And is further inserted between the first housing 102 and the third housing 106 to prevent leakage of the fluid. The first housing 102 and the third housing 106 are disposed in the first housing 102 and the second housing 106, respectively.

The cover housing 100 has a mounting member 500 disposed circumferentially with respect to a surface of the cover 10 opposite to the shaft 10 to be mounted on an end of the shaft 10. The mounting member 500 has a diameter A plurality of bolts are used.

The mounting member 500 is inserted in the direction of the shaft 10 from the inside of the third housing 106 and a separate packing material is inserted into the mounting member 500 so that the damper unit 1 is coupled with the shaft 10 The leakage of the fluid can be stably prevented even when the rotor is rotated at a high speed, so that the natural frequency of the shaft 10 can be stably maintained.

The weight unit 200 includes first to nth unit weights 200a to 200n spaced at regular intervals along the inner circumferential direction of the first housing 102, 200a to 200n are extended in the longitudinal direction L1 extending along the longitudinal direction of the cover housing 100 and a radially extended length r1 extending toward the inside center of the cover housing 100. [

The weight 200 has the above-described structure in order to maintain the inertia energy due to rotation when the shaft 10 is rotated and to adjust the natural frequency by increasing the mass.

The first through nth unit weights 200a through 200n extend in the longitudinal extension length L1 corresponding to the width of the first housing 102 and the thickness extends in the radially extended length r1, The first to nth unit weights 200a to 200n are manufactured to a specific weight according to the length, weight, and natural frequency of the shaft 10, and are not particularly limited to specific weights.

The first to nth unit weights 200a to 200n are formed such that the longitudinal extension length L1 is relatively longer than the radially extended length r1, The reason for this is that the total flow rate of the fluid filled in the cover housing 100 is increased to adjust the natural frequency according to the rotation of the shaft 10 together with the weight 200.

In particular, when the longitudinal extension length L1 is extended to the length shown in the drawing, the total flow rate of the fluid can be increased and the natural frequency can be conveniently adjusted without any additional cost increase.

The first through n-th unit weights 200a through 200n may be disposed inside the cover housing 100 in a vertically symmetrical shape and may be changed to other shapes through simulation. Also, the size of each unit weight is not necessarily limited to the shape shown in the drawings, and may be changed.

The first through n-th unit weights 200a through 200n correspond to the inner circumferential surface of the first housing 102 so that the outer circumferential surface of the first and second unit weights 200a through 200n coincides with the inner side of the first housing 102 when the shaft 10 rotates together. The first to nth unit weights 200a to 200n corresponding to the rigid body are rotated at the inner edge position of the cover housing 100, 200a to 200n of the rotating body 2 can freely move in the remaining region except for the area occupied by the rotating body 2, thereby changing the natural frequency of the rotating body 2. Here, the rotating body 2 means an assembly composed of a shaft 10, such as a gas turbine, and not a shaft-like structure in which the rotating body is directly rotated, and in one example, a gas turbine or other assembly with a steam turbine or shaft This is true.

3 to 4, one of the leaf spring and the coil spring is selectively used in the elastic body 300. In this embodiment, the leaf spring is used, but it is also possible to use the coil spring Leave.

The elastic body 300 includes first to nth unit elastic bodies 300a to 300n arranged radially from the center of the cover housing 100 toward the first to nth unit masses 200a to 200n The first through n-th unit elastic bodies 300a through 300n are formed in a rounded shape toward the radial direction of the cover housing 100.

The reason for this is that the stress applied to the first to nth unit elastic bodies 300a to 300n is dispersed when the damper unit rotated together with the shaft 10 is rotated at a predetermined speed, It is possible to prevent the occurrence of breakage due to the concentration of stress at the position, so that it can be safely used even in long-term use.

In particular, in the case of a rotating body which is not stopped for failure or inspection after being started up once, such as a gas turbine or a steam turbine, it is used with a check period of about ten years, so that the first to nth unit elastic bodies 300a- 300n is not deformed or broken due to rotation in any one of the unit elastic bodies.

The first to nth unit elastic bodies 300a to 300n have a predetermined thickness t and extend radially from the center of the cover housing 100 as described above, And the other end is fixed to the first to n-th unit elastic bodies 300a to 300n.

The first to nth unit elastic bodies 300a to 300n may be configured such that the spring coefficient values are all constant or the spring coefficient values are different from each other and set to a specific spring coefficient value according to the natural frequency according to the rotation of the shaft 10 .

Therefore, it is possible to attenuate the natural frequency generated by the rotation of the shaft 10 together with the weight 200 and the fluid, and to easily adjust the natural frequency to an intended natural frequency, 2 can be prevented from being damaged, thereby enabling stable use.

The first to nth unit elastic bodies 300a to 300n extend in a length corresponding to the length L1 of the first to nth unit weights 200a to 200n, Is used to adjust the natural frequency of the shaft 10 by damping the inertia energy generated by the weight 200 when the shaft 10 is rotated.

The first to nth unit elastic bodies 300a to 300n are formed with an opening hole 310 for movement of the fluid inside the cover housing 100. The opening holes 310 are all opened with the same diameter, Diameter, and is not particularly limited to the diameters shown in the drawings.

In order to easily move the first to n-th unit elastic bodies 300a to 300n with the fluid separated from each other, for example, the opening hole 310 is formed at a predetermined interval in the longitudinal direction and the circumferential direction of the first unit elastic body 300a And the arrangement is arranged such that the number of the opening holes is increased toward the side where the first to nth weights 200a to 200n RK are located with respect to the radial direction.

Although not shown in the drawing, the diameter of the opening hole formed at a specific position is relatively large, and the diameter of the opening hole positioned at another position is formed to be small, so that the first through the nth weights 200a through 200n, So that the amount of movement of the fluid moving to the other side can be controlled to be different.

Therefore, by rotating the shaft 10, the flow velocity of the fluid moving through the opening hole 310 can be adjusted differently, so that the natural frequency of the shaft 10 can be adjusted to reduce the resonance, It is possible to prevent breakage and breakdown of components connected to the rotating body 2.

As shown in the drawing, the opening hole 310 may be formed as a hole that passes all through, or a flap (not shown) may be installed in the opening hole 310 to selectively open or close according to the movement of the fluid. The flap is configured to be kept in close contact with the outside of the opening hole 310 when the fluid is moved through the opening hole, and is selectively spaced apart from the opening hole 310 so that a large amount of fluid moves through the opening hole.

The fluid is supplied to the inner volume of the cover housing 100 to be freely moved inside the cover housing 100 through the opening hole 310 opened in the first to nth unit elastic bodies 300a to 300n as described above The fluid can be easily moved through the opening hole 310 and the natural frequency of the shaft 10 can be adjusted to a desired natural frequency.

5, the damper unit 1 according to an embodiment of the present invention is installed outside the cover housing 100 and applies a current to iron powder contained in the fluid, The control unit 400 may control the amount of current applied to the shaft 10 in accordance with the number of rotations of the shaft 10.

For this purpose, an insert 20 inserted into the cover 100 so as to allow current to flow therethrough is installed in the cover housing 100, and the current applied to the insert 20 is transmitted through the controller 400, So that the natural frequency according to the rotation of the shaft 10 can be adjusted.

In this case, when the current is applied to the iron flow, the natural frequency is relatively lower than the current frequency, so that the natural frequency of the rotor 2 can be adjusted.

Unlike the above-described embodiment, the fluid can be changed to a natural frequency by using a conductive fluid that can flow electricity, rather than a general fluid, without using an insert.

An operation state of the damper unit for a shaft according to an embodiment of the present invention will be described with reference to the drawings.

Referring to FIGS. 1 and 6, when the shaft 10 installed in the rotating body 2 is rotated at a specific speed, twisting occurs in the shaft 10 due to rotation, Is generated.

The damper unit 1 is repeatedly transmitted to the shaft 10 in a form having a specific period according to the time due to the natural frequency of the shaft 10. However, by the weight 200 and the elastic body 300 provided in the damper unit 1 And the rotation of the damper unit 1 further causes the fluid to move through the opening holes 310 of the first to nth unit elastic bodies 300a to 300n as shown by the arrows.

For example, the fluid introduced through the opening hole opened in the first unit elastic body 300a is moved by the movement of the fluid through the opening hole opened in the neighboring second unit elastic body 300b, The vibration due to the rotation of the shaft 10 can be stably maintained by controlling the natural frequency of the shaft 10 by the damping door.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit of the invention as set forth in the appended claims. The present invention can be variously modified and changed by those skilled in the art, and it is also within the scope of the present invention.

2: rotating body
10: Shaft
20: insert
100: Cover housing
102: first cover housing
104: second cover housing
106: third cup housing
200: Weight
200a to 200n: first to nth unit weights
300: elastic body
300a to 300n: first to nth unit elastic bodies
310: opening hole
400:
500: mounting member

Claims (15)

A cover housing mounted on an end of the shaft where rotation is performed and filled with fluid;
A weight disposed within the cover housing; And
And an elastic body connecting the weight to each other. The method according to claim 1,
The weight may be,
And a plurality of first through n-th unit masses along the inner circumferential direction of the cover housing. 3. The method of claim 2,
The first through the n-th unit weights may include a first,
And a radially extending length (r1) extending toward an inner center of the cover housing. 2. The damper unit according to claim 1, wherein the cover housing has a longitudinal extension length (L1) extending along the longitudinal direction of the cover housing. The method of claim 3,
The longitudinal extension length (L1)
Is elongated relative to the radial extension length (r1). 3. The method of claim 2,
The first through the n-th unit weights may include a first,
Wherein the shaft damper unit is arranged in a vertically symmetrical manner. 6. The method according to claim 1 or 5,
The elastic body may be,
Wherein one of the leaf spring and the coil spring is selectively used. 3. The method according to claim 1 or 2,
The elastic body may be,
And first to n-th unit elastic bodies arranged radially from the center of the cover housing toward the first to n-th unit masses. 8. The method of claim 7,
The first to the n-th unit elastic bodies may be formed of
And is rounded toward the radial direction of the cover housing. 8. The method of claim 7,
The first to the n-th unit elastic bodies may be formed of
And the spring coefficient values are all constant. 8. The method of claim 7,
The first to the n-th unit elastic bodies may be formed of
And the spring coefficient values are different from each other. The method according to claim 1 or 3,
The elastic body may be,
And a length corresponding to a longitudinal extension length (L1) of the first through n-th unit weights. The method according to claim 1,
In the elastic body,
And an opening hole is formed in the cover housing for opening the fluid for movement of the shaft. 13. The method of claim 12,
The opening hole
Wherein the first and second shafts are opened at different diameters. The method according to claim 1,
The cover housing,
And a mounting member disposed along a circumferential direction of the cover housing facing the shaft to be mounted on the shaft. The method according to claim 1,
And a control unit provided outside the cover housing and adjusting a natural frequency of the shaft by applying a current to the iron powder contained in the fluid.

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