KR20020045669A - Spindle motor - Google Patents

Abstract

PURPOSE: A spindle motor is provided to secure a load support capability in a direction of stable axis by preparing a plurality of magnet which have repulsive magnetic poles with one another for forming an air gap on a sleeve correspondent to a fixing shaft and a rotor. CONSTITUTION: A circuit board has a sleeve(200) which includes a stator composed of a core(211) and a coil(212). A rotor(300) includes a polygon mirror(310), a magnet(330) which generates a rotational electromagnetic force with the stator, and a groove(351,352) which penetrates a central face of the sleeve(200). A shaft direction load support unit(400) generates a repulsive force between the sleeve(200) and the rotor(300), and supports a load in a shaft direction of the rotor(300).

Description

Spindle motor

The present invention relates to a spindle motor, and more particularly to a spindle motor employing a sliding support method.

In general, a motor is not only classified into a rotating shaft type and a fixed shaft type according to the shaft support method, but also classified into a rolling bearing support method and a sliding bearing support method according to the support method of the driving unit.

Rolling bearings are generally designed to support shafts through one or more ball bearings, and inexpensive ball bearings provide cost savings and the ball between the inner and outer rings has great rigidity. It has the advantage that it can be used for a long time.

On the other hand, there is a problem in that high precision rotation accuracy cannot be obtained, and it is applicable to a certain low speed rotation, but there is a problem in that it is difficult to apply to products requiring high speed rotation.

That is, when applied to a motor of a recording medium that requires high-speed rotation, not only severe vibration is caused by the gap between the ball and the inner and outer rings, but also a noise is caused.

On the other hand, the sliding bearing support method is to support a shaft by forming a metal bearing containing a fluid or an oil film through oil, or to support the shaft through air. Compared to other recording media that require high-speed rotation, such as hard disk drives (HDDs) and CD-ROMs in recent years, they can maintain a high degree of accuracy while maintaining a high degree of rotation. It is widely used in motors.

1 shows a motor employing a general sliding bearing support method.

It is provided with a sleeve 10 is fixed to the circuit board 11 is installed on the center lower surface, the herringbone shaped grooves 12, 13 on the upper and lower outer peripheral surfaces.

In addition, a stator 20 including a core 21 and a coil 22 wound around the core 21 is positioned outside the sleeve 10.

On the other hand, a rotor (rotor) 30 is located on the upper portion of the sleeve 10, the lower inner surface of the rotor 30 to generate a rotating electromagnetic force together with the tactical stator 20, the magnet 31 is It is fixedly installed through the core 32.

In addition, a polygon mirror 40 is mounted on the upper surface of the rotor 30 by a cover 50 and a spring 51.

In addition, a boss 60 is integrally formed on the center lower surface of the rotor 30 so as to surround the sleeve 10. The boss 60 has a herringbone shape formed on upper and lower outer peripheral surfaces of the sleeve 10. It is given a load-bearing capacity in the radial direction while rotating about the grooves 12, 13 of the.

On the other hand, as the rotor 30 is to be given the load bearing capacity in the axial direction, the annular first magnet 70 is fixed to the upper center surface of the sleeve 10, the rotor 30 of the The center magnet is inserted into the inner surface of the first magnet 70 so as to maintain a predetermined interval, and the second magnet 80 is fixed so that magnetic poles opposite to the first magnet 70 are magnetized, that is, suction force is generated. Is installed.

In the conventional spindle motor having such a configuration, the rotor 30 rotates at a high speed about the sleeve 10 through a rotating electromagnetic force generated between the magnet 31 and the stator 20 of the rotor 30. The load carrying capacity in the radial direction is obtained through the air film generated between the herringbone-shaped grooves 12 and 13 formed on the outer circumferential surface of the sleeve 10, and the load carrying capacity in the axial direction is determined by the first and second magnets ( 70, 80) is obtained through the suction force generated between.

However, in such a conventional spindle motor, the first and second magnets 70 and 80, which generate the load bearing ability in the axial direction, are arranged in a symmetrical direction so that mutual suction force is generated even when a slight impact is applied from the outside. Since the portion is positioned to exert a repulsive force, a problem arises in that the rotor 30 is easily detached about the sleeve 10.

The present invention was created to solve the problems of the conventional spindle motor, and to provide a spindle motor that can not only ensure a stable load carrying capacity but also prevent the rotor from being separated even when an external shock is applied thereto. There is a purpose.

1 is a cross-sectional view of a typical spindle motor,

2 is a sectional view of a spindle motor according to the present invention;

3 to 6 are enlarged cross-sectional views showing an arrangement of magnets in the spindle motor according to the present invention;

<Explanation of symbols for main parts of drawing>

100: circuit board 200: sleeve

210: stator 211: core

212 coil 300 rotor

310: polygon mirror 320: leaf spring

330: magnet 340: yoke

350: axis 351,352: (herringbone shape)

400: axial load supporting means

410-470: First to seventh magnets

In order to achieve the above object, the spindle motor according to the present invention includes a circuit board; A sleeve fixedly installed at a center surface of the circuit board and having a stator including a core and a coil at an outer surface thereof; A polygon mirror is mounted on the upper surface, and a magnet that generates rotating electromagnetic force together with the stator is fixedly installed through the yoke on the lower inner surface, and penetrates the center surface of the sleeve on the center lower surface, and herringbone shape grooves on the upper and lower outer surfaces thereof. A rotor having an additionally formed shaft integrally formed thereon; And an axial load supporting means interposed between the rotor and the sleeve to generate a repulsive force to support the load in the axial direction of the rotor.

One preferred feature of the present invention, the axial load supporting means, the first magnet is fixed to the outer peripheral surface of the lower shaft of the rotor; It is fixed to the upper and lower inner circumferential surface of the sleeve around the first magnet, the magnetic pole is magnetized in a direction opposite to the first magnet to generate a repulsive force around the first magnet; Is in.

According to another preferred aspect of the present invention, the axial load supporting means includes: fourth and fifth magnets fixed to the outer peripheral surface of the lower axis of the rotor and the lower inner surface of the rotor; It is fixed to the lower inner circumferential surface of the sleeve adjacent to the lower portion of the fourth magnet and the upper surface of the sleeve corresponding to the fifth magnet, respectively, and the magnetic pole is magnetized in the opposite direction to generate the repulsive force with the fourth and fifth magnets. And sixth and seventh magnets.

Hereinafter, a preferred embodiment of a spindle motor according to the present invention will be described in detail with reference to the accompanying drawings.

Figure 2 is a cross-sectional view of the spindle motor according to the present invention, Figures 3 to 6 are enlarged cross-sectional views showing the magnetized state of the magnets as a support means.

As shown therein, the spindle motor according to the present invention is roughly divided into a circuit board 100, a sleeve 200, a rotor 300, and an axial load supporting means 400.

The circuit board 100 is fixedly installed on the center lower surface of the sleeve 200, and a stator 210 formed of a core 211 and a coil 212 is fixedly installed on an outer surface of the sleeve 200.

The rotor 300 is located above the sleeve 200, and the polygon mirror 310 is fixedly installed by the leaf spring 320 on the upper surface, and generates a rotating electromagnetic force together with the stator 210 on the lower inner surface. As it is, the magnet 330 is fixedly installed through the yoke 340.

In addition, the sleeve 300 is formed on the center lower surface of the rotor 300 and the shaft 350 extends through the center surface. Herringbone-shaped grooves 351 and 352 are formed on the upper and lower outer peripheral surfaces of the shaft 350. Is formed.

The axial load supporting means 400 is interposed between the rotor 300 and the sleeve 200, and in particular, to secure the load supporting ability in the axial direction through mutual repulsive force.

Referring to the detailed structure of the axial load supporting means 400, as shown in Figure 3 and 4, the first magnet 410 is fixed to the outer peripheral surface of the lower portion of the shaft 350 of the rotor 300.

At this time, the magnetization direction of the first magnet 410 is magnetized up and down as shown in FIG. 3 or magnetized inward and outward as shown in FIG. 4.

The second and third magnets 420 and 430 are fixedly installed on the upper and lower inner circumferential surfaces of the sleeve 200 with the first magnet 410 as a center. In particular, the second and third magnets 420 and 430 may be the first. The magnetic poles are magnetized in opposite directions to generate a repulsive force with the magnet 410.

On the other hand, as another embodiment of the axial load supporting means 400, as shown in Figure 5 and 6, the outer peripheral surface of the lower portion of the shaft 350 of the rotor 300 and the lower inner surface of the rotor 300, the fourth and fifth magnets 440 and 450 are fixedly installed.

At this time, the magnetization directions of the fourth and fifth magnets 440 and 450 are magnetized up and down as shown in FIG. 5 or magnetized inward and outward as shown in FIG. 6.

The magnetic poles repulsed with the fourth and fifth magnets 440 and 450 are formed on the lower inner circumferential surface of the sleeve 200 corresponding to the fourth magnet 440 and the upper surface of the sleeve 200 corresponding to the fifth magnet 450. The magnetized sixth and seventh magnets 460 and 470 are fixedly installed.

In the spindle motor according to the present invention configured as described above, the rotor 300 rotates at high speed through a rotating electromagnetic force generated between the magnet 330 and the stator 210 of the rotor 300, and the load in the radial direction during the rotation process. Support capacity is given through the air film generated between the herringbone-shaped grooves 351 and 352 formed on the upper and lower outer peripheral surfaces of the shaft 350 and the inner peripheral surface of the sleeve 200.

On the other hand, the load bearing capacity in the axial direction is given through the axial load supporting means 400.

3 and 4, the first magnet 410 is installed on the lower outer circumferential surface of the shaft 350, and on the upper and lower inner circumferential surfaces of the sleeve 200 based on the first magnet 410. , 3 magnets (420,430) is fixedly installed.

In addition, a stimulus is formed to generate mutual repulsion between them. As a result, an air gap is formed between the first magnet 410, the second magnet 420, and the first magnet 410 and the third magnet 430. Is formed.

Therefore, it is possible to secure the load carrying capacity in the axial direction through the air gap, and in particular, the rotor 300 is prevented from leaving the air gap during an external impact, thereby preventing the possibility of departure.

Meanwhile, as shown in FIGS. 5 and 6, fourth and fifth magnets 440 and 450 are fixedly installed on the lower outer circumferential surface of the shaft 350 and the lower inner surface of the rotor 300, so as to have a repulsive force. Sixth and seventh magnets 460 and 470 are fixedly installed on the lower inner circumferential surface of the sleeve 200 and the upper surface of the sleeve 200.

Therefore, air gaps due to the repulsive force are generated between them, thereby ensuring the load jizz ability in the axial direction and stably preventing the departure of the rotor 300.

On the other hand, the above-described embodiment is merely described one preferred embodiment of the present invention, the scope of application of the present invention is not limited to such, and can be changed as appropriate within the scope of the same idea. For example, the shape and structure of each component shown in the embodiment of the present invention can be modified.

As described above, according to the spindle motor according to the present invention, a load supporting in a stable axial direction is provided by providing a plurality of magnets magnetized with magnetic poles having repulsive forces to form an air gap on a sleeve corresponding to the rotor and the fixed shaft. The ability to secure.

Therefore, there is an advantage that can improve the degree of rotation of the rotor.

In addition, since the air gap has sufficient rigidity, the rotor can be easily prevented from being released from the sleeve by an external impact.

Claims (3)

A circuit board; A sleeve fixedly installed at a center surface of the circuit board and having a stator including a core and a coil at an outer surface thereof; A polygon mirror is mounted on the upper surface, and a magnet that generates rotating electromagnetic force together with the stator is fixedly installed through the yoke on the lower inner surface, and penetrates the center surface of the sleeve on the center lower surface, and herringbone-shaped grain A rotor having an additionally formed shaft integrally formed thereon; A spindle motor interposed between the rotor and the sleeve to generate a repulsive force to support the load in the axial direction of the rotor; According to claim 1, wherein the axial load supporting means, and the first magnet fixed to the outer peripheral surface of the lower shaft of the rotor; It is fixed to the upper and lower inner circumferential surface of the sleeve around the first magnet, the magnetic pole is magnetized in a direction opposite to the first magnet to generate a repulsive force around the first magnet; Spindle motor, According to claim 1, wherein the axial load supporting means, and the fourth and fifth magnets are fixed to the outer peripheral surface of the lower axis of the rotor and the lower inner surface of the rotor, respectively; It is fixed to the lower inner circumferential surface of the sleeve adjacent to the lower portion of the fourth magnet and the upper surface of the sleeve corresponding to the fifth magnet, respectively, and the magnetic pole is magnetized in the opposite direction to generate the repulsive force with the fourth and fifth magnets. And a sixth and seventh magnets.