KR100907178B1 - Spindle motor - Google Patents

Abstract

The present invention is disclosed with respect to a spindle motor. A spindle motor according to the present invention, comprising: a shaft supported by a metal bearing fitted to a bearing holder; A rotor comprising a bush mounted to the shaft and a rotor yoke having a driving magnet therein; A stator mounted at a position corresponding to the driving magnet of the rotor to generate a rotating magnetic force; A second back yoke pressed into the shaft under the bush; It is characterized in that it comprises a suction magnet is mounted along the outer peripheral surface of the upper end of the bearing holder to apply a suction force to the second back yoke to hold the rotor yoke.

The spindle motor according to the present invention prevents injuries of the rotor yoke when the spindle motor is driven in an external state or in a vertical state, and facilitates the installation of the suction magnet and the back yoke for noise reduction while minimizing the leakage magnetic flux of the suction magnet. Can be adjusted.

Suction magnet, back yoke, rotor yoke

Description

Spindle Motors {SPINDLE MOTOR}

1 is a longitudinal sectional view schematically showing the structure of a conventional spindle motor.

Figure 2 schematically shows the structure of a spindle motor according to the invention.

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

101, 201 --- shaft 102, 202 --- metal bearing

103, 203 --- Bearing Holder 104, 204 --- Stator

105,205 --- drive magnet 106,206 --- turn table

107, 207 --- T bush 108, 208 --- bush

109, 209 --- rotor yoke 110, 210 --- suction magnet

111 --- Back York 211 --- First Back York

212 --- Second hundred yoke

The present invention relates to a spindle motor, in particular, to minimize the leakage flux of the suction magnet while preventing the injured rotor yoke and easy installation of suction magnet and back yoke for noise reduction when driving the spindle motor in an external impact or vertical state It relates to a spindle motor that can adjust the attraction force.

1 is a longitudinal sectional view schematically showing the structure of a conventional spindle motor. As shown in FIG. 1, a rotor 101 having a shaft 101 supported by a metal bearing 102 fitted to a bearing holder 103, the rotor yoke 109 fixed by a bush 108 to the shaft 101. ) Is installed. In addition, a driving magnet 105 is installed inside the rotor yoke 109, and a stator 104 for generating a rotating magnetic force is mounted at a position corresponding to the driving magnet 105.

The upper end of the shaft 101 is equipped with a turn bush 106 and a tee bush 107 for seating the disk.

In addition, the bush 108 is mounted to the shaft 101, the inner groove is provided in the lower side of the bush 108, which is a non-magnetic material is attached to the suction magnet 110. Here, the suction magnet 110 is attached to the inner groove of the bush 108 with an adhesive.

The back yoke 111 is attached to the upper end of the bearing holder 103 so as to correspond to the suction magnet 110.

Referring to the operation of the spindle motor according to the prior art made of the configuration as follows.

First, when the shaft 101 including the rotor yoke 109 is rotated by the rotating magnets of the driving magnet 105 and the stator 104, the tee bush mounted on the upper end of the shaft 101 ( 107 and the turn table 106 are rotated integrally. Then, the disk seated on the turn table 106 is rotated.

In the metal bearing 102, oil flows out to allow the shaft 101 to rotate smoothly, and the oil forms a lubrication film between the shaft 101 and the metal bearing 102 to form the lubrication film. The friction and wear of the metal bearing 102 is prevented.

At this time, the suction magnet 110 pulls the back yoke 111 made of steel to prevent the injuring of the rotor yoke 109 and reduces noise.

However, the structure in which the magnet 110 of the conventional spindle motor having the above configuration is bonded to the bush 108 has a low suction force even though a magnet having a high grade is used due to leakage magnetic flux. The use of the adhesive in the assembly process of the magnet 110 and the back yoke 111 causes an increase in the work process, and the amount of the adhesive application is not easy to manage, thereby providing a cause of a defect.

The present invention, in the spindle motor, the suction force by minimizing the leakage flux of the suction magnet while preventing the injuries of the rotor yoke and easy installation of the suction magnet and back yoke for noise reduction when driving in the vertical state or external impact of the spindle motor The purpose is to provide a spindle motor that can adjust the.

In order to achieve the above object, the spindle motor according to the present invention,                     

A shaft supported by a metal bearing fitted to the bearing holder;

A rotor comprising a bush mounted to the shaft and a rotor yoke having a driving magnet therein;

A stator mounted at a position corresponding to the driving magnet of the rotor to generate a rotating magnetic force;

A second back yoke pressed into the shaft under the bush;

It is characterized in that it comprises a suction magnet is mounted along the outer peripheral surface of the upper end of the bearing holder to apply a suction force to the second back yoke to hold the rotor yoke.

Here, in particular, the first back yoke is characterized in that it is coupled with one side of the suction magnet to enhance the suction force of the suction magnet.

According to the present invention, it is possible to minimize the leakage magnetic force of the suction magnet and to reduce the suction force by preventing the suction of the rotor yoke and the installation of the suction magnet and the back yoke for noise reduction when driving in an external impact or vertical state of the spindle motor. I can regulate it.

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

2 is a view schematically showing the structure of a spindle motor according to the present invention. As shown therein, the shaft 201 is supported by a metal bearing 202 inserted into the bearing holder 203, and the rotor yoke 209 fixed by the bush 208 is mounted to the shaft 201. .

In addition, a driving magnet 205 is installed inside the rotor yoke 209, and a stator 204 for generating a rotating magnetic force is mounted at a position corresponding to the driving magnet 205. And the upper end of the shaft 201 is mounted with a tea bush 207 for mounting the turn table 206 and the disk (not shown).

In addition, the first back yoke 211 and the suction magnet 210 are coupled and mounted on one side of the bearing holder 203. Here, the suction magnet 210 is mounted along the inner circumferential surface of the upper end of the bearing holder 203, to hold the vertical rise of the rotor yoke 209, the first back yoke 211 is the suction magnet ( It is coupled to one side of the 210 to prevent the magnetic force leakage of the suction magnet 210 to increase the suction force.

In addition, one side of the second back yoke 212 is press-fitted along the outer circumferential surface of the shaft 201, and the other side is formed in a structure that is mounted with the bush 208. Here, the second back yoke 212 is configured to adjust the height that is pressed into the shaft 201.

Here, the second back yoke 212 is mounted at a position corresponding to the other side surface of the suction magnet 210 while maintaining a predetermined space. Accordingly, the second back yoke 212 is also mounted on the other side of the suction magnet 210, and as a result, the back yokes may be mounted on both sides of the suction magnet 210.

In addition, the second back yoke 212 is configured to adjust the position pressed into the shaft 201 to adjust the suction force with the suction magnet 210.

Referring to the operation of the spindle motor according to the present invention made of the above configuration.

First, the rotor yoke 209, the shaft 201, the T bush 207, and the rotor may be caused by a rotating magnetic force generated between the stator 204 mounted at a position corresponding to the driving magnet 205. The turn table 206 rotates integrally.

Meanwhile, the bush 208 is mounted to the shaft 201 to rotate while fixing the rotor yoke 209.

Oil flows out of the metal bearing 202 so that the shaft 201 rotates smoothly, and the oil forms a lubrication film between the shaft 201 and the metal bearing 202 to form the lubrication film. Prevents friction and wear due to rotation of the metal bearing 202.

The first back yoke 211 made of steel is coupled to the suction magnet 210 and mounted on one side of the bearing holder 203.

That is, induction magnets are generated in the first back yoke 211 by the suction magnet 210 to prevent the magnetic force from leaking from one side of the suction magnet 210 while relatively attracting force of the suction magnet 210. This is reinforced.

Meanwhile, one side of the second back yoke 212 is mounted to the bush 208, and the other side of the second back yoke 212 is press-fitted to the shaft 201, and the press-fitted height is adjustable.                     

Here, the second back yoke 212 press-fitted to the shaft 201 allows to change the mounting position thereof, so that the rotor yoke 209 according to the position where the second back yoke 212 is press-fitted A suction force between the suction magnets 210 with and is adjusted.

In addition, the second back yoke 212 is made of a steel material, and is mounted at a position corresponding to the other side of the suction magnet 210 to generate an induction magnet in the second back yoke 212, By preventing the magnetic force leaking from the other side of the suction magnet 210 is to increase the relatively strong suction force.

Accordingly, the first and second back yokes 211 and 212 have an effect of relatively increasing the suction force with the rotor yoke 209 while preventing magnetic force leaking to both sides of the suction magnet 210.

In addition, the second back yoke 212 may be attached to the shaft 201 without using an adhesive, thereby reducing the assembly process.

As a result, by increasing the suction force of the suction magnet 210, it is possible to prevent the occurrence of noise and defects due to the external shock and the change of its position, such as the rotor injury during vertical driving, and to restore the reliability of the spindle motor Can be.

Although the present invention has been described with reference to the embodiments illustrated in the drawings, this is merely exemplary, and it will be understood by those skilled in the art that various modifications and equivalent other embodiments are possible. Therefore, the true technical protection scope of the present invention will be defined by the technical spirit of the appended claims.

As described above, the spindle motor according to the present invention prevents injuries of the rotor yoke when the spindle motor is driven in an external state or in a vertical state, and leaks of the suction magnet while facilitating installation of suction magnets and back yokes for noise reduction. The suction force can be adjusted by minimizing the magnetic flux.

In addition, by pressing and installing the back yoke to the shaft, it is possible to solve the difficulty of the attachment, it is possible to adjust the suction force by adjusting the indentation height of the back yoke.

Claims (10)

A shaft supported by a metal bearing fitted to the bearing holder; A rotor which rotates integrally with the shaft and includes a rotor yoke having a driving magnet therein; A stator mounted at a position corresponding to the driving magnet of the rotor to generate a rotating magnetic force; A second back yoke disposed below the rotor yoke and fixed to the shaft; And a suction magnet mounted on an inner circumferential side of the upper end of the bearing holder and configured to apply a suction force to the second back yoke to prevent injury of the rotor yoke. The method of claim 1, And a first back yoke coupled to one side of the suction magnet to strengthen the suction force of the suction magnet. The method of claim 1, And the second back yoke is coupled to the shaft and extends axially radially outward of the shaft. The method of claim 3, wherein Said suction magnet opposing said second back yoke. The method of claim 1, The rotor yoke is coupled to the shaft through the bushing spindle motor. The method of claim 3, wherein The rotor yoke is coupled to the shaft through a bush, An upper surface of the second back yoke is opposed to a lower surface of the bush. The method of claim 4, wherein And said second back yoke extends further beyond the position in which said suction magnet is disposed axially radially outward of said shaft. The method of claim 4, wherein And said second back yoke extends further to the axial radially outward direction of said shaft than the position in which said bearing holder is disposed. The method of claim 8, And a groove formed at a lower side of the second back yoke to face a top end of the bearing holder. delete

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