KR200325120Y1 - Self Compensation 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 balancer includes: a body having a race annularly drawn around a rotation axis of the rotating body; A plurality of rigid bodies movably positioned within the race; A cover member coupled to the main body to be coupled to the main body to cover the race; the race includes two or more installation grooves formed on an outer wall thereof; It is provided with a ring member installed in the installation groove to guide the rigid body is contacted by the centrifugal force during rotation of the main body to reduce the coefficient of friction.

Therefore, the manufacturing cost can be reduced by eliminating the surface treatment process so that the friction coefficient is reduced on the race surface.

Description

Self Compensation Balancer

The present invention relates to a self-compensating dynamic balancer, and more particularly, to a self-compensating balancer having an improved race face structure to reduce a friction coefficient between a rigid body and a race.

In general, a disc player, which is a device for recording information on a disc such as a compact disc (CD), a CD-ROM, a digital video disc (DVD), a DVD-ROM, or playing back the recorded information, is employed. Rotating bodies such as spindle motors and turntables are usually inconsistent between the center of gravity and the center of gravity due to the eccentric mass of the rotating body due to errors in the manufacturing process. As such, when the rotating body rotates while the rotation center and the center of gravity do not coincide with each other, the rotation center is idle and a whirling phenomenon occurs. Therefore, the internal vibration of the rotating body is generated, in particular, the vibration in the radial direction of the rotation causes a serious problem.

As shown in FIG. 1, a conventional self-compensating balancer for suppressing internal vibration includes a case 10 and a plurality of rigid bodies 40 located in the case 10. The case 10 includes a main body 20 having an annular lace 21 formed therein so that the rigid body 40 is placed, and a cover member 30 that can cover the opening of the main body 20. .

A fastening hole 35 is formed at the center of the cover member 30 to couple the case 10 to the rotation shaft 51 of the driving source 50. The annular race 21 is a space in which the rigid body 40 can move freely, and the center of the fastening hole 35 is the center of rotation thereof. Accordingly, when the case 10 rotates, the rigid body 40 located inside the race 21 is positioned in a direction away from the center of rotation of the rotation shaft 51 by centrifugal force. Here, when the rotating shaft 51 revolves by eccentric mass, the rigid body 40 is located on the opposite side to the revolving center with respect to the rotating shaft 51 to suppress internal vibration by the eccentric mass. The self-compensating balancer is internally formed by the unbalanced mass of the rotating body by properly determining the center and diameter of the annular race 21 and the diameter, mass, and number of the rigid bodies 40 in consideration of the normal rotational speed of the rotating body. It will alleviate vibration.

The conventional self-compensating balancer having the above-described configuration requires a cost such as surface treatment of the outer wall of the race 21 in contact with the rigid body 40 so as to reduce the coefficient of friction with the rigid body in order to achieve a good balancing operation. If there is a rise and such surface treatment is poor, there is a problem that the balancing performance may be lowered.

The present invention was devised in view of the above problems, and an object of the present invention is to provide a self-compensating balancer having an improved structure by installing a separate member having a low coefficient of friction on a race surface in contact with a rigid body.

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

Figure 2 is an exploded perspective view schematically showing a self-compensation balancer according to an embodiment of the present invention.

3 is a cross-sectional view of FIG.

4 is an enlarged cross-sectional view of a portion A of FIG.

<Description of Symbols for Main Parts of Drawings>

50 ... Drive 51 ... Rotating shaft 60 ...

61 ... Race 61a ... Outer wall 61b ... Bottom

70 ... rigid 80 ... cover member 90 ... ring member

The present invention for achieving the above object, the main body having a race coupled to the rotating body is installed in the rotating body so as to suppress the internal vibration by the eccentric mass of the rotating body, the annular inlet around the rotation axis of the rotating body; A plurality of rigid bodies movably positioned within the race; A self-compensating balancer comprising: a cover member coupled to the main body to cover the race, wherein the race has two or more installation grooves formed on an outer wall thereof; And a ring member installed in the installation groove to guide the rigid body in contact with the centrifugal force during rotation of the main body to reduce the friction coefficient thereof.

Here, the ring member is installed so that a constant distance is maintained so as not to touch the outer wall of the race when the rigid body rolls inside the race, the ring member is preferably made of a metal material.

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

The self-compensating balancer according to one embodiment of the present invention is employed in a rotating body such as a turntable of a disc player to suppress internal vibration due to eccentric mass.

Referring to FIG. 2, the self-compensating balancer includes a main body 60 having an annular race 61 formed therein, a rigid body 70 movably disposed inside the race 61, and an opening of the race 61. Cover member 80 is coupled to cover the race 61 and the ring member 90 is installed in the installation groove (H) formed in the outer wall (61a) of the race (61).

A coupling hole 63 is formed at the center of the main body 60. The coupling hole 63 is coupled to the rotation shaft 51 of the drive source 50 to provide a rotational force. Therefore, the main body 60 can rotate according to the rotational force provided from the drive source 50. The main body 60 is generally manufactured by injection molding.

The opening of the race 61 may be formed over the upper front surface of the main body 60 so that the rigid body 70 can be placed therein, and formed to a size that the rigid body 70 can fit into a portion of the upper portion of the lace 61. It may be.

The plurality of rigid bodies 70 are directed in the radial direction opposite to the center of the main body 60 by the centrifugal force during the rotation of the rotating body. Here, when the rigid body 70 moves in the race 61 to find its compensating position during the high speed rotation of the rotor, the rigid body 70 contacts the race 61 in the axial direction and in a direction perpendicular to the axis. do. That is, since the rigid body 70 receives the centrifugal force by the rotational force of the rotating body, the sliding contact mainly occurs in the axial direction in contact with the race 61, and the rolling contact occurs in the direction perpendicular to the axis.

In order to prevent the rigid body 70 from contacting the bottom of the race 61 by using the physical principle, the performance of the balancer may be improved by operating the entire frictional force on the surface in contact with the rigid body 70.

In consideration of this, the present invention, as shown in Figure 3, by installing a ring member 90 with less friction force in the installation groove (H) formed in the outer wall (61a) of the race 61, when the main body 60 rotates A plurality of rigid bodies 70 are contacted by the centrifugal force and have a shape in which the movement thereof can be guided. Here, the material of the ring member 90 corresponds to any metal material having a small coefficient of friction. In addition, the ring member 90, when the rigid body 70 placed on the bottom surface 61b of the race 61 is pushed to the outer wall (61a) of the race 61 by the rotation and centrifugal force of the rotating body, the rigid body 70 is It is desirable to have a shape that does not catch. On the other hand, the ring member 90 is installed in the mounting groove (H) is preferably maintained at a constant interval so as not to contact the outer wall (61a) of the race 61 in the state in which the rigid body 70 is in contact. .

Therefore, as long as the surface of the ring member 90 has a low coefficient of friction, it is not necessary to precisely process the race 61 surface, so that the main body can be produced by a simple molding injection operation. The ring member 90 may be installed in the installation groove H formed on the race 61 surface of the main body 60 to increase the balancing effect.

In addition, when the ring member 90 is installed in parallel in a proper arrangement state, in the so-called vertical type in which the rotating body is disposed in the vertical direction, even when the main body is stopped, the rigid body 70 is always between the ring members 90. ) Can be placed.

The self-compensating balancer according to the present invention having the above-described configuration reduces the frictional contact between the rigid body and the ring member by installing two or more ring members on the outer wall of the race and makes the rigid body contact only with the ring member, thereby reducing the inner surface of the race. It is possible to eliminate the machining process to make the friction coefficient smaller and thus reduce the work cost, thereby reducing the manufacturing cost and increasing the balancing efficiency of the balancer.

Claims (3)

A main body coupled to the rotating body so as to suppress internal vibration due to the eccentric mass of the rotating body, the main body having an annular inlet-shaped race around the rotating shaft of the rotating body; A plurality of rigid bodies movably positioned within the race; In the self-compensating balancer comprising: a cover member coupled to the body to cover the race: The race has two or more installation grooves formed on the outer wall thereof; And a ring member installed in the installation groove so that the rigid body is contacted by the centrifugal force during rotation of the main body to reduce the coefficient of friction thereof. The self-compensating balancer as claimed in claim 1, wherein the ring member is installed to maintain a predetermined distance so that the rigid body does not touch the outer wall of the race when the rigid body rolls inside the race. The self-compensating balancer according to claim 1 or 2, wherein the ring member is made of a metal material.