KR101009191B1 - Spindle motor - Google Patents

Abstract

The present invention relates to a spindle motor in which the grounding structure can be simplified by directly grounding the ground of a circuit board for driving the spindle motor to a plate made of metal. The spindle motor of the present invention has a magnet mounted to rotate by mounting a recording medium. The rotor case is provided, the rotary shaft fixedly coupled to the central portion of the rotor case, the shaft for supporting the rotor case, the bearing for rotatably supporting the rotating shaft, and the bearing is fixed to accommodate the electromagnetic force between the magnet and the magnet A bearing holder having an armature forming a shape, a metal plate in which the bearing holder is fixedly installed, and a ground portion which is electrically connected to the plate by being pressed by a part of the bearing holder to transfer electricity to the armature. It includes a flexible circuit board.

Spindle motor, bearing holder, circuit board, ground part, ground

Description

Spindle motor

The present invention relates to a spindle motor, and more particularly, to a spindle motor in which the grounding structure can be simplified by directly grounding a ground of a circuit board for driving the spindle motor to a metal plate.

In general, the spindle motor can maintain a high rotational characteristic by rotatably supporting the rotating shaft by maintaining a constant contact section between the bearing and the rotating shaft, which can be used for hard disk drives, optical disk drives and other recording media that require high speed rotation. It is widely used as a driving means.

 Spindle motors that require such high speed rotation are required to be thinner and lighter to meet the development of electronic devices that are miniaturized day by day, and an example of such a conventional motor is described in [Document 1].

In the motor of the prior art described in [Document 1], an exposed copper foil is formed around a central hole formed in a printed circuit board in order to seat a bearing housing, and the exposed copper foil is formed by a ground portion and a pattern on the printed circuit board. It is connected. Therefore, the ground portion on the printed circuit board is formed to be electrically connected to the bottom metal portion of the printed circuit board through the bearing housing seated on the exposed copper foil.

However, in the grounding structure of the motor of the prior art having the above-described configuration, since the grounding portion on the printed circuit board is indirectly grounded with the metal portion of the printed circuit board through the bearing housing, the bearing housing is made of a material which can be electrically conductive. That is, the bearing housing should be made only of a conductive material, and therefore, the technology of [Document 1] had a problem in that compatibility or versatility was very low.

In addition, in the technique of [Document 1], a printed circuit board is a metal circuit board on which a circuit pattern is formed directly on a metal plate, which has higher manufacturing cost, manufacturing time, and manufacturing difficulty than a general rigid or flexible circuit board. That is, in order to manufacture the metal circuit board of [Document 1], the circuit layer should be integrally formed on the metal plate by pressing an insulating layer on the metal plate and then forming and etching a plating layer thereon. There was a problem that was very difficult to produce.

In addition, the metal circuit board of [Document 1] has to discard the entire metal circuit board when a defect occurs in the process of forming the circuit, and thus there is a problem that the unit cost of the product and the yield decrease are inevitable.

[Document 1]

KR Seal 2000-0003671 Feb 25, 2000, drawing 3, drawing 4

The present invention has been made to solve the above-mentioned problems of the prior art, an object of the present invention is to independently ground the ground pattern of the circuit pattern to the metal plate independently of the bearing holder material spindle motor that can be very high compatibility or versatility To provide.

In addition, by attaching a flexible circuit board having a lower manufacturing cost, manufacturing time and manufacturing difficulty than the metal circuit board of the prior art on the upper surface of the metal plate to provide a spindle motor that can reduce the cost of the product and increase the yield.

In order to achieve the above object of the present invention, the present invention is a rotor case equipped with a magnet to be mounted to rotate the recording medium, and a fixed shaft coupled to the central portion of the rotor case and the shaft for supporting the rotor case, A bearing holder provided with a bearing for rotatably supporting the rotating shaft, an armature accommodating and supporting the bearing and forming an electromagnetic force between the magnet, and a metal material in which the bearing holder is fixedly installed. It is possible to provide a spindle motor, characterized in that it comprises a flexible circuit board having a plate and a grounding portion which is pressed by a part of the bearing holder and electrically connected directly to the plate for transferring electricity to the armature.

The plate has a coupling hole into which the bearing holder is inserted and coupled, and the ground portion of the flexible circuit board is in close contact with the coupling hole.

In addition, the bearing holder has a support extending in the radial direction to support the upper surface of the plate, the support portion is characterized in that the contact with the plate by pressing the ground of the flexible circuit board.

In addition, the flexible circuit board is characterized in that the circuit pattern is formed on the upper surface and the ground portion is formed on the rear surface.

In addition, the flexible circuit board may include an insulating layer; A circuit pattern formed on an upper surface of the insulating layer; A ground part formed on the rear surface of the insulating layer; A via hole formed through a portion of the circuit pattern and the ground portion; And a conductive paste filled in the via hole to electrically connect a portion of the circuit pattern to the ground portion.

In addition, the flexible circuit board is characterized in that the coverlay is formed on the upper surface of the insulating layer.

In the flexible circuit board, a coverlay may be formed on the top and bottom surfaces of the insulating layer, respectively, and the coverlay formed on the bottom of the insulating layer may expose the ground to the outside.

According to the present invention, by independently grounding the ground portion of the circuit pattern to the metal plate independently of the material of the bearing holder, it is possible to provide a spindle motor that can be highly compatible or versatile.

In addition, by using a flexible circuit board having a lower manufacturing cost, a manufacturing time, and a manufacturing difficulty than the metal circuit board of the prior art, it is possible to achieve cost reduction and increase in yield of a product.

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

As shown in FIG. 1, the spindle motor 100 according to an exemplary embodiment of the present invention includes a plate 110, a bearing holder 120, a bearing 130, an armature 140, a thrust washer 150, The rotating shaft 160, the rotor case 170 and the flexible circuit board 180 is included.

Plate 110 is for supporting the spindle motor 100 to be fixed as a whole, it is installed to be fixed to a device such as a hard disk drive in which the spindle motor 100 is installed. In addition, it is preferably made of a conductive material so as to be directly connected to the ground portion 183 of the flexible circuit board 180 to form a ground of the circuit pattern, mainly made of a lightweight material such as aluminum plate or aluminum alloy plate It may be manufactured, but alternatively, made of steel sheet.

Here, the plate 110 is formed with a coupling hole 111 to which the bearing holder 120 is coupled, and the flexible circuit board 180 having a circuit pattern for applying electricity to the armature 140 on the upper surface of the plate 110. Is attached.

The bearing holder 120 is for supporting the bearing 130 to be fixed. The bearing holder 120 is inserted into the coupling hole 111 of the plate 110 and fixed to the plate 110 by caulking or spinning. Are combined.

More specifically, the bearing holder 120 has a hollow cylindrical shape as a whole, and has a support 122 formed stepwise so that a seating surface 121 on which the core 141 of the armature 140 is seated is formed on the outer circumferential surface thereof. The support part 122 supports the upper surface of the plate 110 through the ground part 183 of the flexible circuit board 180.

That is, the bearing holder 120 is seated on the upper portion of the ground portion 183 disposed to face the support portion 122 and presses the ground portion 183 so that the ground portion 183 is directly grounded to the plate 110.

As such, the bearing holder 120 presses the ground portion 183 of the flexible circuit board 180 onto the plate 110, so that the ground portion 183 is electrically connected directly to the plate 110, so that the plate 110 is connected to the circuit 110. It can function as the ground of the pattern, and thus, unlike the prior art, the bearing holder 120 of the present invention may not be limited to a material. That is, the bearing holder 120 of the present invention may be made of an electrically conductive material such as aluminum or an aluminum alloy, but may also be made of a non-conductive material.

The bearing 130 is for rotatably supporting the rotating shaft 160, and is formed in a substantially cylindrical shape such as a metal, and the inside of the bearing holder 120 so that the central axis is coincident with the central axis of the rotating shaft 160. It is fixedly installed.

The armature 140 is for forming an electric field by receiving an external power source, and consists of a core 141 and a coil 142 wound around the core 141.

The core 141 is fixedly installed after being seated on the seating surface 121 of the support part 122 of the bearing holder 120. The coil 142 is configured to rotate the rotor case 170 by a force formed between the magnet 173 of the rotor case 170 by forming an electric field with a power source applied from the outside, and a plurality of cores 141. Winding times.

The thrust washer 150 supports the rotation shaft 160 in the axial direction, but is in contact with the lower portion of the rotation shaft 160 to reduce friction during rotation of the rotation shaft 160, and is supported by a bearing holder (151) by the thrust washer cover 151. 120 is fixedly installed.

The rotary shaft 160 is for supporting the rotor case 170, and is rotatably inserted into the inner diameter of the bearing 130 so that the central axis coincides with the central axis of the bearing 130.

The rotor case 170 is for mounting and rotating an optical disk (not shown), and an annular edge portion 172 extending from an end of the disc portion 171 and the disc portion 171 to which the rotating shaft 160 is fixed. Has

The disc portion 171 is inserted and coupled to the rotation shaft 160 is fixed to the central portion, the edge portion 172 is extended so that its inner peripheral surface facing the armature 140, between the electric field formed in the coil 142 Magnet 173 for rotating the rotor case 170 by the force generated in the fixed to the inner peripheral surface of the edge portion 172 is installed.

The flexible circuit board 180 is electrically connected to the coil 142 of the armature 140 to generate an electromagnetic force for rotating the rotor case 170 to transfer electricity, and is fixedly attached to the upper surface of the plate 110. do. The detailed configuration of such a flexible circuit board 180 is shown in more detail in FIG. 2.

As shown in FIG. 2, the flexible printed circuit board 180 according to the exemplary embodiment of the present invention may include an insulating layer 181, a circuit pattern 182, a ground portion 183, a via hole 184, and a conductive paste 185. ) And a coverlay 186.

The insulating layer 181 becomes a core of the flexible circuit board 180 and is generally formed of a polyimide material having high flexibility. The copper foil layer for forming the circuit pattern 182 is formed on the insulating layer 181, and the circuit pattern 182 is formed by etching the copper foil layer according to a general method of manufacturing the flexible printed circuit board 180.

Meanwhile, the circuit pattern adjacent to the coupling hole 111 of the plate 110 of the circuit pattern 182 forms the ground portion 183. More specifically, a circuit pattern for the ground portion 183 is formed on the rear side of the portion pressed by the support portion 122 of the bearing holder 120, and the ground portion 183 includes the via hole 184 and the conductive paste. 185 is electrically connected to the circuit pattern formed on the upper surface.

A coverlay 186 is formed on the upper surface of the flexible circuit board 180 to protect the circuit pattern 182, and the ground portion 183 is exposed on the rear surface of the flexible circuit board 180. That is, the coverlay 186 is not formed on the rear surface of the flexible circuit board 180.

As shown in FIG. 3, the flexible circuit board 280 according to another embodiment of the present invention may include an insulating layer 281, a circuit pattern 282, a ground portion 283, a via hole 284, and a conductive paste 285. ) And two coverlays 286a and 286b, wherein the coverlays 286a and 286b are formed on both top and bottom surfaces of the insulating layer 281 to protect the flexible circuit board 180.

On the other hand, the coverlay 286b formed on the back side of the flexible circuit board 180 is preferably formed by exposing the ground portion 283 to the outside so that the ground portion 283 is in close contact with the plate 210.

The flexible circuit boards 180 and 280 according to the embodiments of the present invention are attached to the upper surfaces of the plates 110 and 210 so that the ground parts 183 and 283 are in close contact with the plates 110 and 210 of the metal material, and at this time, the ground parts 183 and 283. May be formed in an annular shape so as to surround the periphery of the coupling holes 111 and 211 of the plates 110 and 210, and an upper portion thereof is pressed by the bearing holders 120 and 220. That is, the ground parts 183 and 283 of the flexible circuit boards 180 and 280 are pressed by the support parts 122 and 222 of the bearing holders 120 and 220 during the caulking or spinning operation of the bearing holders 120 and 220, thereby closely contacting the plates 110 and 210 to the plates 110 and 220. It is electrically connected directly to form a ground.

While the spindle motor of the present invention has been described above with reference to preferred embodiments of the present invention, it is apparent to those skilled in the art that modifications, changes, and various modifications can be made without departing from the spirit of the present invention.

1 is a schematic cross-sectional view of a spindle motor according to a preferred embodiment of the present invention;

FIG. 2 is a schematic enlarged cross-sectional view of the ground portion and plate of FIG. 1; FIG. And

3 is a schematic cross-sectional view of a flexible printed circuit board having a ground part according to another exemplary embodiment of the present invention.

<Explanation of symbols for main parts of drawing>

100: spindle motor 110,210: plate

111,211: Coupling hole 120,220: Bearing holder

122,222: support 130: bearing

140: armature 141: core

142: coil 160: rotating shaft

170: rotor case 173: magnet

180,280: flexible circuit board 181,281: insulation layer

182,282 circuit pattern 183,283 ground part

184,284: Via Hole 185,285: Paste

186: Coverlay 286a, 286b: Coverlay

Claims (7)

A rotor case provided with a magnet to rotate by mounting a recording medium; A rotary shaft fixedly coupled to a central portion of the rotor case to support the rotor case; A bearing for rotatably supporting the rotating shaft; A bearing holder having an armature configured to receive and support the bearing and to fix the bearing and to form an electromagnetic force therebetween; A metal plate having a coupling hole into which the bearing holder is inserted to be coupled so that the bearing holder is fixedly fixed, and a ground portion of the flexible circuit board directly adhered to the coupling hole; And And a flexible circuit board for transmitting electricity to the armature, the flexible circuit board being pressed by a part of the bearing holder and directly connected to the plate. A rotor case provided with a magnet to rotate by mounting a recording medium; A rotary shaft fixedly coupled to a central portion of the rotor case to support the rotor case; A bearing for rotatably supporting the rotating shaft; A bearing holder having an armature configured to receive and support the bearing and to fix the bearing and to form an electromagnetic force therebetween; A metal plate on which the bearing holder is fixed; And And a flexible circuit board configured to transfer electricity to the armature, the flexible circuit board having a ground portion pressed by a portion of the bearing holder and directly connected to the plate. The bearing holder has a support extending in the radial direction to support the upper surface of the plate, the support portion is a spindle motor, characterized in that the pressing of the ground portion of the flexible circuit board in close contact with the plate. The method according to claim 1, The bearing holder has a support extending in the radial direction to support the upper surface of the plate, the support portion is a spindle motor, characterized in that the pressing of the ground portion of the flexible circuit board in close contact with the plate. The method according to claim 2 or 3, The flexible circuit board is a spindle motor, characterized in that the circuit pattern is formed on the upper surface and the ground portion is formed on the rear surface. The method according to claim 2 or 3, The flexible circuit board Insulating layer; A circuit pattern formed on an upper surface of the insulating layer; A ground part formed on the rear surface of the insulating layer; A via hole formed through a portion of the circuit pattern and the ground portion; And a conductive paste filled in the via hole and electrically connecting a portion of the circuit pattern to the ground portion. The method according to claim 5, The flexible circuit board has a spindle motor, characterized in that the coverlay is formed on the upper surface of the insulating layer. The method according to claim 5, The flexible circuit board has a coverlay is formed on the top and back of the insulating layer, respectively, the coverlay formed on the back of the insulating layer is a spindle motor, characterized in that to expose the ground to the outside.

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