KR100243161B1 - Self-compensating dynamic balancer - Google Patents

Abstract

Disclosed is a self-compensating balancer coupled to a rotating body so as to suppress internal vibration caused by the eccentric mass of the rotating body.

The disclosed self-compensating balancer includes: a main body having an annular lace formed around an axis of rotation of the rotating body, and an installation portion formed stepwise on the outer wall of the race; A plurality of rigid bodies movably positioned within the race; A fluid injected into the race to facilitate the flow of the rigid body; A cover member coupled to the installation portion of the main body to cover the race and protruding on a surface facing the race so as to be positioned around the installation portion and having a guide jaw for guiding the movement of the fluid. Characterized in that it can be suppressed to enter the coupling portion therebetween.

Description

Self Compensation Balancer

The present invention relates to a self-compensating balancer, and more particularly, to a self-compensating balancer having an improved structure to prevent oil from entering between a main body and a cover member.

In general, the rotational body is inconsistent with the center of rotation and the center of gravity of the rotational body due to eccentric mass due to errors in the manufacturing process. In this way, when the rotating body rotates while the rotation center and the center of gravity are inconsistent, the rotation center is idle, that is, whirling. As a result, the rotating body particularly generates internal vibration in the rotation radius direction.

As described above, a conventional self-compensating balancer for suppressing internal vibration has a main body 1 having an annular lace 2 formed with an inlet and opening one surface thereof, as shown in Figs. It includes a rigid body (3) placed in the race (2) and a cover member (7) adapted to cover the opened portion of the body (1).

A coupling hole 1a for coupling the main body 1 to the rotation shaft 9a of the driving source 9 is formed at the center of the main body 1. The race 2 is a space in which the rigid body 3 can move freely, and the race 2 has its center of rotation as its center of rotation. Therefore, when the main body 1 rotates, the rigid body 3 located inside the race 2 is intended to be located in a direction away from the center of rotation of the rotation shaft 9a by centrifugal force. Here, when the rotating shaft 9a revolves by eccentric mass, the rigid body 3 is located on the opposite side to the revolving center based on the rotating shaft 9a to suppress internal vibration by the eccentric mass.

As described above, the configured self-compensating balancer takes into account the normal rotational speed of the rotating body, the diameter of the center of the race 2 forming the annular shape, the diameter of the rigid body 3, the mass of the rigid body 3, and the rigid body 3 The internal vibration caused by the unbalanced mass of the rotor can be reduced by determining the number of

As such, the conventional self-compensating balancer provided has a disadvantage in that the rigid body 3 does not stop quickly in the balancing position due to weak damping between the rigid body 3 and the race 2 during the balancing operation. In view of this, the fluid 5 was injected into the race 2. Here, the fluid 5 instead of contributing to substantial balancing, relieves the friction between the rigid body 3 and the race 2 and the cover member 7 and applies internal damping to the rigid body 3.

As described above, when the self-compensating balancer in which the fluid 5 is injected into the race 2 is used while being employed in a disc player or the like and disposed vertically, as shown in FIG. Is likely to enter the gap 8 between the main body 1 and the cover member 7. In this case, since the fluid 5 inside the race 2 gradually decreases, the lubrication action is slowed down, so that the balancing performance is lowered.

Accordingly, an object of the present invention is to provide a self-compensating balancer having an improved structure to suppress the loss of fluid injected into a race.

1 is a partial perspective view showing a general self-compensating balancer.

2 is a schematic cross-sectional view showing an example disposed in the vertical direction of the self-compensating balancer of FIG.

Figure 3 is an exploded perspective view showing a self-compensation balancer according to an embodiment of the present invention.

Figure 4 is a schematic cross-sectional view showing an example in which the self-compensation balancer according to the embodiment of the present invention is disposed in the vertical direction.

<Explanation of symbols for main parts of drawing>

10 ... body 11 ... race 13 ... joint

21 Rigid body 23 Fluid 30 Cover member

31 Guide chin 40 ... Driver 41 ... Rotary shaft

In order to achieve the above object, the present invention provides a self-compensating balancer coupled to the rotating body so as to suppress internal vibration caused by the eccentric mass of the rotating body, the annular formed in the center of the rotation axis of the rotating body A main body having a race and an installation portion formed on the upper end of the outer wall of the race; A plurality of rigid bodies movably positioned within the race; A fluid injected into the race to facilitate the flow of the rigid body; And a cover member coupled to an installation part of the main body to cover the race and protruding to a surface facing the race so as to be positioned around the installation part and having a guide jaw for guiding the movement of the fluid. It is characterized in that it is possible to suppress the entry into the coupling portion between the installation portion and the cover member.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

As shown in FIGS. 3 and 4, the self-compensating balancer according to the embodiment of the present invention has an annular race 11 and an installation portion 13 formed on the top of the outer wall 11a of the race 11 stepwise. ) A body 10 having a), a plurality of rigid bodies 21 movably placed inside the race 11, a fluid 23 and a body 23 movably placed inside the race 11. It is coupled to cover the race 11 and comprises a cover member 30 having a guide jaw 31 for guiding the movement of the fluid (23).

The main body 10 is rotatably installed on the rotation shaft 41 of the drive source 40. The race 11 has an outer wall 11a, a bottom 11b and an inner wall 11c as a space formed in the main body 10 so that the rigid body 21 and the fluid 23 can move. The rigid body 21 is located in the race 11 and is in contact with the outer wall 11a of the race 11 by centrifugal force during rotation by the drive source 40.

The rigid body 21 is located inside the race 11 and compensates for internal vibration caused by the eccentric mass of the rotating body when the main body 10 rotates together with a rotating body (not shown) such as an optical disk. The fluid 23 is injected into the race 11 and is substantially applied to the rigid body 21 and the outer wall 11a, the bottom 11b and the inner wall 11c of the race 11 so that the race is carried out. The friction force between 11 and the rigid body 21 is reduced.

The installation part 13 is a space in which the cover member 30 is coupled and installed as a step formed to be stepped into the upper end of the outer wall 11a of the race 11.

The cover member 30 is coupled to the installation part 13 to cover the race 11. The guide jaw 31 is formed to protrude so as to be positioned around the installation part 13 on the surface facing the race 11 of the cover member 30. The guide jaw 31 guides the movement of the fluid 23 to prevent the fluid 23 from entering the coupling portion between the mounting portion 13 and the cover member 30. This is useful when using a compensating balancer in the vertical direction.

As described above, the operation when the self-compensating balancer according to the embodiment of the present invention is arranged in the vertical direction will be described.

When the main body 10 rotates at the normal speed, the rigid body 21 and the fluid 23 are driven to the outer wall 11a by centrifugal force. At this time, the fluid 23 is moved toward the outer wall 11a by riding on the inner side of the cover member 30, the bottom surface 11b and the rigid body 21. The guide jaw 31 guides the flow of the fluid 23 so that the fluid 23 moving on the cover member 30 flows into the coupling portion between the installation part 13 and the cover member 30. Prevent it.

The guide jaw 31 may be further provided at a portion at which the inner wall 11a and the cover member 30 are coupled, in addition to a portion at which the outer wall 11a and the cover member 30 are coupled to each other.

As described above, the self-compensating balancer according to the present invention includes the guide jaw 31 in the cover member 30, whereby the fluid 23 placed in the race is the main body 10 and the cover member 30. By suppressing the loss of the coupling portion therebetween, it is possible to prevent the reduction of the fluid 23 and the deterioration of the balancing performance.

Although the present invention has been described with reference to the embodiments illustrated in the accompanying drawings, this is merely exemplary, and it will be understood by those skilled in the art that various modifications and equivalent embodiments are possible. .

Claims (1)

In the self-compensation balancer coupled to the rotating body to suppress the internal vibration caused by the eccentric mass of the rotating body, A main body having an annular lace formed around a rotation axis of the rotating body and an installation portion formed stepwise on an upper end of the outer wall of the lace; A plurality of rigid bodies movably positioned within the race; A fluid injected into the race to facilitate the flow of the rigid body; And a cover member coupled to an installation part of the main body to cover the race and protruding to a surface facing the race so as to be positioned around the installation part and having a guide jaw for guiding the movement of the fluid. Self-compensating balancer characterized in that it is possible to suppress the entry into the engaging portion between the installation portion and the cover member.

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