KR20010064317A - Spindle motor of operation disk - Google Patents

Abstract

PURPOSE: A spindle motor for driving disk is provided to minimize vibration and noise by placing each magnet forming at least more than one groove at an upper and lower part of a rotating axis and a metal bearing. CONSTITUTION: A rotating axis(210) is equipped. A rotor yoke is fixed by a bush installed at the rotor axis(210). A driving magnet is installed at the inside of the rotor yoke. An armature core generates rotating magnet and is placed at position corresponding to the driving magnet. A metal bearing(220) is placed at the rotating axis(210). More than one inserting groove(212,214) is formed at the external diameter of the rotating axis(210) at least. More than one internal groove(222,224) is formed at a surface corresponding to the rotating axis(210) at the metal bearing(220) at least. The metal bearing(220) includes each magnet(230,240) inserted in an inserting groove of the rotating axis(210) and an internal diameter groove of the metal bearing(220) separately. The magnet of the rotating axis(210) and the magnet of the metal bearing is installed so that same polarity is facing each other.

Description

Spindle Motors for Disk Drives {SPINDLE MOTOR OF OPERATION DISK}

The present invention relates to a disk drive spindle motor, and in particular, the magnets are mounted on the inner diameter of the metal bearing rotating in combination with the rotating shaft and the outer diameter groove of the rotating shaft to use magnetic repulsive force, thereby causing frictional forces during rotation of the spindle motor. Disc drive spindle motor for preventing wear and current consumption of metal bearings and extending the life of the spindle motor.

A general conventional disk drive spindle motor is described with reference to FIGS. 1 to 3 as follows. As shown, the rotating shaft 110 is supported by a metal bearing (122) fitted to the bearing holder 120, the rotor 110 is fixed to the rotating shaft 110 by a bush (Bush: 150) The yoke 130 is mounted. In addition, a driving magnet 132 is installed inside the rotor yoke 130, and an armature core 134 for generating a rotating magnetic force is mounted at a position corresponding to the driving magnet 132.

In addition, a turntable 140 is mounted at an upper end of the rotary shaft 110, and a tee bush (T-Bush: 160) is mounted on the outer ring of the center of the turntable 140 to seat an inner ring of a central hole of a disc (not shown). It is.

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

First, when the rotating shaft 110 including the rotor yoke 130 rotates by the rotor force of the driving magnet 132 and the armature core 134, the tee bush 160 mounted on the upper end of the rotating shaft 110 The turntable 140 coupled by the rotation is rotated. At this time, the disk seated on the turntable 140 is rotated. At this time, oil is introduced between the metal bearing 122 and the rotating shaft 110 in a vacuum state so that the metal bearing 122 and the rotating shaft 110 can rotate smoothly. Then, due to the heat generated when the spindle motor 100 rotates, the oil flows upward of the rotation shaft 110 to form a lubrication film 124 between the rotation shaft 110 and the metal bearing 122. At this time, the rotation of the rotating shaft 110 and the metal bearing 122 is smooth, when the oil is consumed more than half the life of the spindle motor 100 is shortened. That is, the oil is further introduced into the metal bearing 122 to minimize the friction between the rotating shaft 110 and the metal bearing 122.

However, in the conventional disk drive spindle motor having the above configuration, the oil is further applied to the inside of the metal bearing 122 to prolong the life of the spindle motor 100. As the spindle motor increases in speed, Inertia or other external forces may act on the electronic assembly. For this reason, when the rotating shaft 110 rotates, frictional force is generated in the narrow gap with the metal bearing 122, and abrasion occurs at upper and lower edges (a) and (b) of the metal bearing 122. The oil is consumed by volatilization and solidification by heat and the lubrication effect is lowered. Further, the friction surface of the metal bearing 122 is worn and the life of the spindle motor 100 is shortened.

The present invention is to solve the problems of the prior art as described above, the object of the present invention, by using the magnetic repulsion by mounting the respective magnets in the inner diameter and the outer diameter groove of the rotating shaft of the metal bearing in combination with the rotating shaft Accordingly, to provide a disk drive spindle motor for preventing the wear of the metal bearing and current consumption due to the frictional force during rotation of the spindle motor, and to extend the life of the spindle motor.

1 is a cross-sectional view showing a conventional spindle motor,

2 is a cross-sectional view showing a metal bearing inserted into a rotating shaft of a conventional spindle motor,

Figure 3 is a cross-sectional view showing the wear resistance between the conventional rotating shaft and the metal bearing,

4 is a cross-sectional view showing a spindle motor according to an embodiment of the present invention,

5 is a cross-sectional view showing a metal bearing coupled to the rotating shaft of the spindle motor of the present invention.

Explanation of symbols on the main parts of the drawings

100,200: Spindle motor 110,210: Rotating shaft

120: bearing holder 122,220: metal bearing

124: lubricating film 130: rotor yoke

132: driving magnet 134: armature core

140: turntable 150: bush

160: tea bush 212,214: insertion groove

222,224: Inner diameter groove 230,240: Magnet

a: upper corner b: lower corner

In order to achieve the above object, the disk drive spindle motor 200 provided by the present invention includes a rotating shaft, a rotor yoke fixed by a bush provided on the rotating shaft, and a driving magnet installed inside the rotor yoke. In the disk drive spindle motor comprising an armature core which is mounted at a position corresponding to the drive magnet and generates a rotating magnetic force, and a metal bearing mounted to the rotating shaft,

At least one insertion groove is formed in the outer diameter of the rotating shaft,

The metal bearing has at least one inner diameter groove formed on a surface corresponding to the rotation shaft, and the metal bearing includes a magnet inserted into the insertion groove of the rotation shaft and the inner diameter groove of the metal bearing, respectively.

The magnet of the rotating shaft and the magnet of the metal bearing are installed so that the same polarity is opposite to each other, so that a repulsive force is generated between each other, so that the friction force generated in the metal bearing is reduced when the rotating shaft rotates.

Preferably the insertion groove of the rotary shaft is formed in the upper end and the lower end of the rotary shaft,

The inner diameter groove of the metal bearing is formed at a position corresponding to the insertion groove formed in each of the upper end and the lower end of the rotating shaft.

More preferably the rotating shaft and the metal bearing,

It is characterized by being a nonmagnetic material.

Hereinafter, a configuration including a disk drive spindle motor according to an exemplary embodiment of the present invention will be described with reference to FIGS. 4 and 5. In the following description, the same reference numerals are used for the same parts as those used in Figs.

As shown, the disk drive spindle motor 200 according to the preferred embodiment of the present invention, as shown, the rotating shaft 210 supported by the metal bearing 220 fitted to the bearing holder 120 Is provided, the rotor yoke 130 is fixed to the rotating shaft 210 by the bush 150 is mounted. In addition, at least one or more insertion grooves 212 and 214 are formed at the upper and lower ends of the outer diameter of the rotating shaft 210 to minimize the frictional force between the rotating shaft 210 and the metal bearing 220. do. In addition, inner diameter grooves 222 and 224 are formed in upper and lower portions of the metal bearing 220 coupled to the rotating shaft 210, and magnets 240 are mounted in the inner diameter grooves 222 and 224.

In addition, a driving magnet 132 is installed on the inner upper and lower portions of the rotor yoke 130, and an armature core 134 for generating a rotating magnetic force is mounted at a position corresponding to the driving magnet 132. A turntable 140 is mounted at an upper end of the rotary shaft 110, and a tee bush 160 for seating an inner ring of a central hole of a disc (not shown) is mounted at an outer ring of the center of the turntable 140. The rotary shaft 210 is formed by digging a groove in the upper and lower outer circumference of the friction generated, each magnet 230 is mounted, the rotary shaft 210 is assumed to be a non-magnetic material. In addition, the magnet 230 is inserted lower than the surface in order to prevent foreign matters due to breakage.

The magnet 240 mounted to the metal bearing 220 sinters the ferromagnetic material together. In addition, the magnets 240 mounted on the metal bearing 220 are mounted to face the magnets 230 mounted on the rotating shaft 210 and mounted with the same polarity. Therefore, mutual repulsive force between the same polarity is generated so that the rotating shaft 210 does not tilt to either side.

Referring to the operation of the disk drive spindle motor of the present invention made of the above configuration is as follows.

First, when the rotating shaft 210 including the rotor yoke 130 is rotated by the rotor force of the driving magnet 132 and the armature core 134, the upper end of the rotating shaft 210 is coupled with the tee bush 160 The turntable 140 is rotated. At this time, the disk seated on the turntable 140 is to rotate. At this time, since the magnet 240 mounted on the metal bearing 220 and the magnet 230 mounted on the rotating shaft 210 have the same polarity, the repulsive force is generated so that the rotating shaft 210 does not tilt to either side. Will rotate.

In the spindle motor 200 according to the exemplary embodiment of the present invention as described above, the magnets 230 and 240 are formed by forming at least one groove in the upper and lower ends of the rotating shaft 210 and the metal bearing 220. By mounting a), since the repulsive force is generated between the magnets when the spindle motor rotates, the rotation shaft 210 is prevented from tilting to either side. And by correcting the rotor assembly can minimize the vibration and noise generated by the inertial force of the rotor. In addition, it minimizes mutual frictional force and prevents uneven wear of the metal bearing 220, and has a useful effect of preventing oil consumption due to excessive heat generation and extending the life of the spindle motor and durability.

Accordingly, the present invention is equipped with a metal bearing and a rotating shaft in combination with the rotating shaft to use the magnetic repulsive force when the spindle motor rotates to prevent wear and current consumption of the metal bearing due to the friction force and to extend the life of the spindle motor It provides a spindle motor for driving the disk.

In addition, it will be apparent to those skilled in the art that various modifications, changes, additions, and the like are possible within the scope of the present invention defined by the claims.

Claims (3)

A rotating shaft, a rotor yoke fixed by a bush provided on the rotating shaft, a driving magnet installed inside the rotor yoke, an armature core mounted at a position corresponding to the driving magnet and generating a rotating magnetic force, and the rotating shaft In the disk drive spindle motor comprising a metal bearing mounted to the, At least one insertion groove is formed in the outer diameter of the rotating shaft, The metal bearing has at least one inner diameter groove formed on a surface corresponding to the rotation shaft, and the metal bearing includes a magnet inserted into the insertion groove of the rotation shaft and the inner diameter groove of the metal bearing, respectively. The magnet of the rotating shaft and the magnet of the metal bearing are installed so that the same polarity is opposite to each other, a reaction force is generated between each other, and the friction force generated in the metal bearing is reduced when the rotating shaft is rotated. Spindle motor. The method of claim 1, Insertion groove of the rotary shaft is formed in the upper end and the lower end of the rotary shaft, The inner diameter groove of the metal bearing is a disk drive spindle motor, characterized in that formed in a position corresponding to the insertion groove formed in each of the upper end and the lower end of the rotating shaft. The method of claim 2, The rotating shaft and the metal bearing, A disk drive spindle motor, characterized in that the nonmagnetic material.