KR20000044153A - Disc driving motor - Google Patents

Abstract

PURPOSE: A disc driving motor is provided to enhance the assembly work efficiency with the reduction of the number of assembly work processes by incorporating a disc-seating unit with a rotor. CONSTITUTION: A rotor(200) is provided with a case(210) on which a magnet(211) is attached. A disc-seating unit(300) is provided on the case(210) in one body. A rotation shaft(100) is inserted into the center of the disc-seating unit(300). A boss(310) having a through hole(311) is provided on the center portion of the disc-seating unit(300). A stator(400) generates a rotation force through the interaction with the rotor(200). A stator core(420) is provided on the stator(400) and the stator core(420) has a coil for generating an electromagnetic force together with a magnet(211) of the rotor(200).

Description

Disc drive motor

The present invention relates to a drive motor, and more particularly, to a disc drive motor for mounting and rotating the disc in a disc player.

1 and 2 show a typical disc drive motor.

This is provided with the rotating shaft 10, and for rotating-driving this rotating shaft 10, The rotor 20 and the stator 30 are provided.

The rotor 20 has a case 21 having a magnet M attached to an inner circumferential surface thereof, and a bearing press-fitting hole 22a is inserted into the center upper surface of the case 21 so that the upper surface of the rotating shaft 10 can be forcibly inserted. The boss 22 having an extension is formed.

The stator 30 acts as a rotor 20 to generate a rotational force, and the bearing holder 40 is inserted into the center surface, and the magnet M of the rotor 20 is inserted into the outer circumferential surface of the bearing holder 40. The yoke 31 is wound around the coil 32 to generate an electromagnetic force.

An upper and lower bearing 50 for slidingly supporting the rotating shaft 10 is interposed between the upper and lower inner peripheral surfaces of the bearing holder 40 and the rotating shaft 10.

The turn table 60 is positioned at the upper end of the rotation shaft 10.

The turn table 60 has a boss 61 formed therethrough with a bearing indentation hole 61a through which the rotating shaft 10 can be inserted into the center thereof, and a magnet M is inserted into the center surface of the boss 61. Insertion groove 61b is formed to be.

From the outer circumferential surface of the boss 61, a flange 62 having a seating surface 62a is formed so that the disk D can be seated.

From the upper part of the turn table 60, the clamper 70 which presses the disk D mounted on the seating surface 62a of the flange 62 which comprises the turn table 60 so that it may not flow is located.

In the conventional disc drive motor having such a configuration, the rotor 20 is rotated by the electromagnetic force generated by the coil 31 of the stator 30 and the magnet M of the rotor 20, and at the same time, the rotor 20. Rotating shaft 10 coupled to the rotation is driven.

Therefore, the turn table 60 provided at the upper end of the rotating shaft 10 is to rotate to drive the disk (D).

However, in such a conventional disk drive motor, since the turntable 60 and the rotor 20 are each provided as separate parts, and a plurality of bearings 50 must be provided, the unit cost increases with the increase in the number of parts. The problem which causes the fall of workability by the increase of an assembly time is caused.

The present invention was created to solve such a conventional problem, to provide a disk drive motor that can not only reduce the unit cost due to the reduction of the number of parts but also improve the assembly workability according to the reduction of the assembly labor. The purpose is.

1 and 2 are a front view and a cross-sectional view of a conventional disk drive motor,

3 is a cross-sectional view of a disk drive motor according to the present invention.

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

100: rotation axis 200: rotor

210: (rotor) case 211: magnet

300: (disk) mounting means 310: boss

311 through hole 320 flange

330: seating table 340: guide

341: guide surface 342: insertion groove

400: Stator 420: (Stator) Core

410: coil 500: support means

510: bearing holder 511: bearing indentation hole

520: bearing 521,522: upper and lower support surfaces

530: shaft support 531: washer

600: Clamper M: Magnet

W: Washer

Disc drive motor according to the present invention to achieve the above object, the rotation shaft; A rotor having a case with a magnet attached to an inner circumferential surface thereof; It is provided integrally on the case, the center surface is inserted into the upper end of the rotary shaft is inserted, the disk mounting means for mounting the disk on the upper surface; A stator positioned below the rotor and having a stator core and a coil wound around the stator core to generate an electromagnetic force together with a magnet of the rotor; And support means interposed between the stator and the rotating shaft to support the rotating shaft rotatably.

Such a characteristic configuration and the resulting effects of the present invention will become more apparent from the following detailed description of the invention with reference to the accompanying drawings.

3 is a cross-sectional view of a disc drive motor according to the present invention.

As shown therein, the disc drive motor according to the present invention is roughly divided into a rotating shaft 100, a rotor 200, a disc seating means 300, a stator 400, and a support means 500.

The rotor 200 has a case 210 having a magnet 211 attached to an inner circumferential surface thereof.

The seating means 300 is integrally provided on the case 210, and the rotary shaft 100 is inserted into the center surface as a kind of turntable on which the disk D is seated and rotated.

The seating means 300 is injection molded integrally with the rotor case 210.

Looking at the detailed structure of such a mounting means 300, it has a boss (310) formed with a through hole 311 in the center surface so that the upper end of the rotary shaft 100 is inserted.

The flange 320 extends from the lower outer circumferential surface of the boss 310 to closely contact the inner lower surface of the rotor case 210.

The flange 320 may be formed to extend to support the upper surface of the magnet 311 attached to the inner circumferential surface of the rotor case 210.

In this way, when the flange 320 is extended to support the upper surface of the magnet 311, the entire height of the magnet 311 can be easily adjusted.

That is, the height of the magnet 311 may be adjusted by adjusting the thickness of the flange 320.

From the upper outer circumferential surface of the boss 310, the mounting table 330 is formed to be in close contact with the upper surface of the rotor case 210, the mounting table 330 may be formed as a separate component.

Mounting table 330 is a portion where the disk (D) is substantially mounted.

A guider 340 having an inclined guide surface 341 formed at an upper end thereof is formed on a central upper surface of the boss 310 to guide the disk D so that the shaft center is coincident with the upper surface of the mounting table 330.

The upper surface of the guider 340 is formed with an insertion groove 342 in which the magnet (M) or other components can be seated.

The magnet M inserted into the insertion groove 342 of the guider 340 serves to pressurize and support the disk D through an attraction force generated between the iron pieces (not shown) provided on the clamper 600. . On the contrary, even if the magnetic body is inserted into the insertion groove 342 and the function of generating the magnetic force in the clamper 600 may serve to pressurize the disk.

The stator 400 generates a rotational force by working with the rotor 200, and includes a stator core 420, which generates an electromagnetic force together with the magnet 211 of the rotor 200. Coil 410 is wound.

The support means 500 is interposed between the stator 400 and the rotation shaft 100, and serves to slide the rotation shaft 100.

Looking at the detailed structure of such a support means 500, it is roughly divided into a bearing holder 510, a bearing 520 and a shaft support 530.

The bearing holder 510 is provided on the center upper surface of the stator 400, and the inner bearing press-fitting hole 511 is formed therethrough.

The bearing holder 510 is integrally formed with the stator 400 in view of cost reduction.

As described above, in forming the bearing holder 510 integrally with the stator 400, the center surface of the stator 400 can be easily formed by deep drawing the upper surface thereof.

The bearing 520 is interposed between the bearing holder 510 and the rotating shaft 100 to slide and support the rotating shaft 100.

The bearing 520 is formed of a single part, and upper and lower support surfaces 521 and 522 are formed on the inner circumferential surface to support the upper and lower surfaces of the rotating shaft 100.

As an inner surface between the upper and lower support surfaces 521 and 522, an oil forming an oil film is interposed when the bearing 520 is sintered.

The shaft support 530 is located on the lower surface of the center of the bearing holder 510 and is provided with a washer 531 that supports the lower end of the rotation shaft 100.

On the other hand, in the case of using the bearing containing the sintered bearing 520 as described above to prevent the leakage of oil during the rotation of the rotating shaft 100, the outer peripheral surface of the rotary shaft 100 adjacent to the upper and lower surfaces of the bearing 520 The washer W is interposed.

Disc drive motor according to the present invention having such a configuration, the rotor 200 is rotated by the electromagnetic force generated between the magnet 211 of the rotor 200 and the coil 420 of the stator 400, the rotor at the same time The disk mounting means 300 integrally provided in the case 210 rotates to drive the disk D.

The rotary shaft 100 is rotated together by the rotary drive of the disc seating means 300, and the rotary shaft 100 is slidably supported by the integral bearing 520 interposed between the rotary shaft 100 and the bearing holder 510 to smoothly rotate. Driven.

As described above, according to the disc drive motor according to the present invention, since the disc seating means, which is a turntable, is integrally provided in the rotor, and at the same time, the bearing is provided as a single part, the number of parts is reduced when compared with the conventional disc drive motor. It is possible to reduce the unit cost, in particular, there is an advantage to improve the assembly workability by reducing the number of assembly times.

Claims (10)

A rotating shaft; A rotor having a case with a magnet attached to an inner circumferential surface thereof; It is provided integrally on the case, the center surface is inserted into the upper end of the rotary shaft is inserted, the disk mounting means for mounting the disk on the upper surface; A stator positioned below the rotor and having a stator core and a coil wound around the stator core to generate an electromagnetic force together with a magnet of the rotor; And a support means interposed between the stator and the rotating shaft to support the rotating shaft rotatably. The disk mounting means according to claim 1, further comprising: a boss having a through hole formed in a center surface thereof so that the upper end portion of the rotation shaft is inserted into the disk mounting means; A flange extending from an outer circumferential surface of the boss to be in close contact with a lower surface of the rotor case; A seating unit extending from an outer circumferential surface of the boss to be in close contact with the upper surface of the rotor case, and having a disk seated on the upper surface; The guide is formed extending from the upper surface of the boss, the guide surface is inclined so that the disk is seated on the upper surface of the seating portion on the outer circumferential surface of the boss, and the guide groove formed with an insertion groove to insert the magnet on the center upper surface; motor. The disk drive motor according to claim 2, wherein the flange is in close contact with the inner circumferential surface of the rotor case to be in contact with the upper end of the magnet. 4. The disk drive motor according to claim 3, wherein the magnet has an overall height determined by the flange. The disc drive motor according to claim 1, wherein the disc seating means is integrally molded to the rotor case through outsting. 2. The bearing assembly of claim 1, wherein the support means comprises: a bearing holder provided on the stator and having a bearing press-through hole in a center surface thereof; A bearing interposed between the bearing holder and the rotating shaft for slidingly supporting the rotating shaft; And a shaft support provided on a lower center surface of the bearing holder and having a washer supporting a lower end of the rotating shaft. The method of claim 6, wherein the bearing is composed of a sintered bearing, the upper and lower inner peripheral surface is formed to extend the upper and lower support surfaces in contact with the upper and lower outer peripheral surface of the rotary shaft, the space between the upper and lower support surfaces Disc drive motor, characterized in that the oil is interposed in the portion. 7. The disk drive motor according to claim 6, wherein the bearing holder is provided integrally with the stator. The disk drive motor of claim 8, wherein the bearing holder is formed by deep drawing the center surface of the stator. The disk drive motor according to claim 6, wherein washers for preventing leakage of the oil are interposed on upper and lower surfaces of the bearing.