KR100266737B1 - Spindle motor for digital video disk - Google Patents

Abstract

PURPOSE: A spindle motor for a DVD(Digital Video Disk) is provided to reduce an unbalance state of a rotor and to match a center of the rotor with a center of a disk by preventing the rotor from being lifted up with a housing and a core insulator. CONSTITUTION: A hollow sleeve(11) is coupled inside a housing(10), and a core(14) having a wound coil(15) is joined outside the housing. The core adopts a core insulator(16) for insulation with the housing and has a shaft(12) rotatable in the sleeve. A space between the shaft and the sleeve is filled with oil for generating dynamic pressure. A hub(17) is assembled to the upper end of the shaft to rotate a rotor(18). A fitting plate(26) is mounted outside the hub, and plural fitting grooves(25) are formed radially at the core insulator to inhibit the fitting plate from being lifted up. The fitting protrusions keep a distance of 1mm from the fitting plate. Thereby, the rotor is rotated smoothly without interference therebetween. When the rotor is lifted up, the distance gets smaller and the fitting plate is inhibited by the protrusions. Therefore, the rotor is not lifted up.

Description

Spindle Motors for Digital Video Discs

The present invention relates to a spindle motor for a digital video disc, and more particularly, by using a core insulator to prevent the rotor from axially deviating and to automatically adjust the center of the disc when the disc is placed on top of the rotor, A spindle motor for digital video discs is improved.

In general, the spindle motor for a digital video disc has a state in which the sleeve 1a is assembled by force fitting in the upper center of the housing 1 as shown in FIG. 1 and the shaft 2 is rotatable inside the sleeve 1a. It is provided with. The core 1b constituting the stator is provided at the upper outer circumference of the housing 1, and the rotor 3 in the form of a cap is provided at the upper end of the shaft 2. The rotor 3 is provided with a magnetic body 3a surrounding the core 1b at its inner circumference. When power is applied to the coil 1c wound on the core 1b, a magnetic force is generated on the magnetic body 3a, and the rotor 3 Is rotated about the axis (2). In addition, the disk 4 is placed on the upper part of the rotor 3, and the disk clamp 5 holding the disk 4 is provided at the bottom of the door 6 that opens and closes the rotor 3.

The conventional spindle motor configured as described above uses a hydrodynamic bearing so that a dynamic pressure generating groove 2a is formed on the outer circumferential surface of the shaft 2. In other words, when the shaft 2 is rotated at a high speed, the oil filled between the sleeve 1a generates pressure by the dynamic pressure generating groove 2a. Thus, the shaft 2 is supported to rotate radially. In addition, while the shaft 2 is rotated, the disk 5 placed on the top of the rotor 3 is rotated together to reproduce the information of the disk. However, there is a fear that the rotor 3 is separated in the axial direction by using a hydrodynamic bearing.

That is, because the minute gap is formed between the shaft 2 and the sleeve 1a, and oil is filled in the gap to generate dynamic pressure, the shaft 2 cannot be restrained in the axial direction. Therefore, when the disc clamp 5 for extracting the disc 4 is opened, the rotor 3 may be lifted up together by the magnetic material 23 formed on the bottom thereof. In order to compensate for this, a conventional structure is added between the rotor 3 and the housing 1. However, since the unbalance of the rotating rotor 3 is relatively large, there is a disadvantage that can not produce a low vibration, low noise motor.

In addition, conventionally, when the disk 4 is placed on the upper portion of the rotor 3, there is a fear that unbalance occurs because there is no means for matching the center between them. This occurs when the user puts the disk 4 on the upper part of the rotor 3 and fits the hole formed in the center of the disk 4 to the protrusion part of the upper part of the rotor 3. Therefore, there is a disadvantage such as lowering the loadability.

The present invention was developed in view of various problems in the related art, and an object of the present invention is to prevent the rotor from being lifted up by using a core insulator that insulates the housing and the core, thereby reducing the bias force of the rotor and also allowing the disk to rotate. It is to provide a spindle motor for a digital video disk to improve the reliability by placing the center of the automatic matching when placed on the top of.

In order to achieve the above object, the present invention provides a housing having a hollow sleeve fitted thereon and having a core at its outer circumference; A shaft rotatably fitted in the sleeve; A rotor having a magnetic body coupled to the upper end of the shaft through the hub and surrounding the core at an inner circumference; A core insulator that insulates the core from the housing; And a lifting suppression means provided between an upper end of the core insulator and a lower end of the hub to suppress lifting of the rotor.

1 is a cross-sectional view of a conventional spindle motor.

2 is a cross-sectional view of the spindle motor of the present invention.

Figure 3 is an exploded perspective view of a part of the spindle motor of the present invention.

<Description of the code | symbol about the principal part of drawing>

10 housing 11 sleeve

12: axis 14: core

16 core insulator 17 hub

18: rotor 19: magnetic material

24: lifting means 25: jamming jaw

26: stopping plate 27: center adjusting means

28: spring 29: neck portion

30: lifting platform 31: guide surface

32: home

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

2 is a cross-sectional view of the spindle motor of the present invention, Figure 3 is an exploded perspective view of a part of the spindle motor of the present invention. A housing 10 having a hollow sleeve 11 coupled to the upper center is provided, and a core 14 wound around a coil 15 is provided at an upper outer circumference of the housing 10. In this case, the core 14 and the housing 10 are insulated by the core insulator 16. The core insulator 16 is provided with an insulated tube 16a formed of a hollow cylindrical shape, and covers 16b are provided on the upper and lower ends of the insulated tube 16a to cover the surface and the bottom of the core 14. In addition, the shaft 12 is rotatably fitted inside the sleeve 11, and oil is filled between the shaft 12 and the sleeve 11. In addition, dynamic pressure is generated in the oil while the shaft 12 is rotated by the dynamic pressure generating groove 13 formed on the outer circumferential surface of the shaft 12, and the shaft 12 is rotated and supported in the rotational radial direction.

In addition, the hub 17 is coupled to the upper end of the shaft 12 by interference fit, and the rotor 18 on the outer periphery of the hub 17 is provided to rotate with the hub 17. The rotor 18 is configured in the form of a cap with an open bottom and is provided on the top of the hub 17 in a form surrounding the core 14. In addition, a magnetic body 19 surrounding the core 14 is provided on the inner circumferential surface of the rotor 18. When power is applied to the coil 15, a magnetic force is generated on the magnetic body 19, and the rotor 18 together with the shaft 12. Rotates at high speed. The disc 20 is also placed on top of the rotor 18, and the disc 20 is opened and closed by the door 21. In addition, the bottom surface of the door 21 is provided with a disc clamp 22 having a magnetic body 23 so that the disk clamp 22 is applied to the magnetic force of the magnetic body 23 while the magnetic body 23 is stuck to the hub 17. The disk 20 is brought into close contact with the upper portion of the rotor 18.

In addition, the lifting suppression means 24 is provided to prevent the rotor 18 from flowing upward in the axial direction. The lifting suppression means 24 suppress the flow of the rotor 18 while the rotor 18 is being rotated or the moment the disc clamp 22 is detached from the disc 20. The lifting suppression means 24 is provided between the core insulator 16 and the hub 17. That is, a plurality of locking jaws 25 are radially provided on the upper end of the insulator tube 16a constituting the core insulator 16, and the bottom surface of the hub 17 has a disk-shaped locking plate which is caught by each locking jaw 25 ( 26).

In addition, the center adjusting means 27 is provided to match the center of the rotor 18 and the disk 20. The center adjusting means 27 is provided with a hollow cylindrical spring 28 inclined upwardly. The lower end of the spring 28 is supported by being caught on the surface of the locking plate 26 in a state of being fitted to the hub 17. And a plurality of lifting pieces 30 arranged radially on the upper end of the spring 28 is provided. These lifting pieces 30 have guide surfaces 31 on the outside. These guide surfaces 31 are in contact with the inner circumferential surface of the hole 20a formed in the center of the disk 20. When the corresponding lifting pieces 30 are fitted into the plurality of grooves 32 formed in the upper portion of the rotor 18, the respective guides Face 31 is exposed to the top of the rotor 18. And the spring 28 is made of synthetic resin of the plastic type and is provided with a V-shaped neck portion 29 in the center of the outer peripheral surface to give elasticity.

In the present invention configured as described above, the hollow sleeve 11 is coupled to the inside of the housing 10, and the core 14 wound around the coil 15 is coupled to the outer circumference of the housing 10. At this time, the core 14 is provided with a core insulator 16 to insulate the housing 10, and the shaft 12 is coupled to the inside of the sleeve 11 in a rotatable state. In addition, oil generating dynamic pressure is filled between the shaft 12 and the sleeve 11, and a hub 17 for rotating the rotor 18 is coupled to the upper end of the shaft 12. In addition, a locking plate 26 is provided on a lower outer circumferential surface of the hub 17, and a plurality of locking jaws 25 radially restrain the rising of the locking plate 26 on the core insulator 16.

In addition, the interval between the locking step 25 and the locking plate 26 is maintained about 1mm. Therefore, the rotor 18 is rotated without difficulty because they do not interfere with each other by the gap between the locking step 25 and the locking plate 26 while the rotor 18 is normally rotated. And when the rotor 18 is going to be lifted upwards, the gap between them is narrowed, and the locking plate 26 is caught by the locking jaw 25 so that the lifting of the rotor 18 is suppressed.

The lifting phenomenon of the rotor 18 is generated as follows. That is, when the door 21 is closed while the disk 20 is placed on the upper portion of the rotor 18, the disk clamp 22 presses the upper portion of the disk 20. The disk clamp 22 is provided with a magnetic body 23 on the bottom thereof, and the disk clamp 22 presses the upper portion of the disk 20 by the force of the magnetic body 23 sticking to the hub 17. When power is applied to the coil 15 in such a state, a magnetic force is generated on the magnetic body 19 formed on the inner circumferential surface of the rotor 18, and the rotor 18 is rotated at high speed together with the shaft 12 and the information of the disk 20 is provided. Is played. In addition, when the door 21 is opened while the rotation of the rotor 18 is stopped, the disc clamp 22 is lifted together. In this process, the magnetic body 23 lifts the hub 17 together, and the lifting phenomenon of the rotor 18 occurs at this time. As soon as the rotor 18 is lifted, the locking plate 26 formed at the lower end of the hub 17 is restrained by the locking step 25 and only the door 21 and the disc clamp 22 are opened.

In addition, when the disk 20 is placed on the upper portion of the rotor 18, the center thereof is automatically matched by the center adjusting means 27. The center adjusting means 27 is exposed to the upper side of the rotor 18, the lifting piece 30 provided with a plurality of radially on the upper end of the spring (28). When the disk 20 is placed in the upper portion of the rotor 18 in such a state, the holes 20a thereof are fitted into the guide surfaces 31 of the respective lifting pieces 30. At this time, the lifting piece 30 is slightly lowered about the spring 28 by the force for releasing the disk 20. In this process, the hole 20a is completely inserted into each guide surface 31, so that the center of the disk 20 is It coincides with the center of the rotor 18 automatically. In addition, when the laying force of the disk 20 is transmitted to the spring 28, it is buffered in the neck portion 29.

As described above, according to the present invention, a plurality of locking jaws are formed radially on the upper end of the insulator tube of the core insulator that insulates the core and the housing, and a disk-shaped locking plate is provided at the bottom of the hub connecting the rotor to the shaft. do. Therefore, when the rotor is lifted up, the stopping plate is caught by the stopping jaw and the reliability is improved, and in particular, by not using a separate structure, the unbalance of the rotor is reduced. In addition, when the holes of the disk are fitted to a plurality of lifting pieces protruding to the upper portion of the rotor, the center of these disks and the rotor is automatically matched, and thus there is an effect that the disk is easy to place.

Claims (5)

A housing 10 having a hollow sleeve 11 fitted thereon and having a core 14 at its outer periphery; A shaft (12) rotatably fitted in the sleeve (11); A rotor 18 coupled to the top of the shaft 12 via a hub 17 and having a magnetic body 19 surrounding the core 14 at its inner circumference; A core insulator (16) that insulates the core (14) from the housing (10); And a lifting suppression means (24) provided between an upper end of the core insulator (16) and a lower end of the hub (17) to suppress lifting of the rotor (18). According to claim 1, The lifting means 24 is provided with a plurality of radially on the upper end of the core insulator 16, a plurality of engaging jaw (25) and at the lower end of the hub (17) Spindle motor for a digital video disc, characterized in that it is provided with a locking plate (26) which is inhibited to be caught. A housing 10 having a hollow sleeve 11 fitted thereon and having a core 14 at its outer periphery; A shaft (12) rotatably fitted in the sleeve (11); A rotor 18 coupled to the top of the shaft 12 via a hub 17 and having a magnetic body 19 surrounding the core 14 at its inner circumference; A disk 20 placed on top of the rotor 18; And a center adjusting means (27) provided at an outer circumference of the hub (17) to align the center of the disc (20) with the rotor (18). According to claim 3, The center adjusting means 27 is provided with a disk-shaped locking plate 26 at the lower end of the hub 17, the lower end is supported by the locking plate 26 and at the same time inclined upwardly A cylindrical spring 28 having a cushioning property is provided, and a plurality of lifting pieces 30 are provided radially on the top of the springs 28, and the lifting pieces 30 are fitted on the upper part of the rotor 18. A plurality of grooves 32 which are lifted and lowered are provided, and a guide surface 31 into which the hole 20a of the disk 20 is fitted is provided on the outer circumferential surface of each lifting piece 30. Spindle motor. 5. The spindle motor as set forth in claim 4, wherein the spring (28) is made of a synthetic resin material and has a neck portion (29) at the center of the outer circumferential surface to impart elasticity.

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