KR20080044933A - Ultra slim spindle motor - Google Patents

Abstract

An ultra slim spindle motor is provided to prevent a plate from being deformed by pressing a bearing holder into the plate with vertical force orthogonal to the plate when the bearing holder is assembled into the plate. An ultra slim spindle motor(100) includes a plate(110), a bearing holder(120), a thrust washer cover(161), and a rotor case(180). A connection hole(111) is formed on the plate. A bearing(130) is installed on the bearing holder to rotatably support a rotational axis(170) therein. At least a portion of the bearing holder is pressed and inserted into the connection hole to support a bottom surface(112) of the plate. The thrust washer cover is pressed and inserted into the bearing holder to support the thrust washer cover being in contact with an end of the rotational axis in an axial direction. An armature(150) generates an electric field by external power. An armature holder(140) has a connection protrusion(146) connected with the armature. The rotational axis is fixed to a circular disk unit(181). The rotor case has an annular rim unit(182) installed therein a first magnet(186) at an inner peripheral surface thereof to face the armature from a rim of the circular disk unit.

Description

Ultra slim spindle motor

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

2 is a schematic cross-sectional view showing the coupling of the spindle motor of FIG.

3 is a schematic cross-sectional view of a conventional spindle motor; And

4 is a schematic cross-sectional view showing the coupling of the spindle motor of FIG.

<Explanation of symbols for main parts of drawing>

100: spindle motor 110: plate

120: bearing holder 130: bearing

140: armature holder 145: coupling projection

150: armature 160: thrust washer

170: axis of rotation 180: rotor case

181: disc portion 182: border portion

186: first magnet 187: back yoke

188: the second magnet 190: hook portion

The present invention relates to a spindle motor, and more particularly to an ultra-thin spindle motor that can maintain the overall thickness and at the same time increase the coupling force of the armature and to achieve a light weight by replacing the material of the rotor case.

The spindle motor maintains high precision rotational characteristics by rotatably supporting the rotating shaft by forming an oil film through lubricating oil between the bearing and the rotating shaft, thereby driving hard disk drives, optical disk drives and other recording media requiring high speed rotation. It is widely adopted as a means.

 Spindle motors that require high-speed rotation are required to be thinner and lighter to meet the development of electronic devices that are miniaturized day by day, and also to prevent the components of the spindle motor from being separated from each other by an impact applied from the outside. It is desired to maintain a high coupling force between them, an example of such a spindle motor is schematically shown in FIGS. 3 and 4.

3 and 4, the spindle motor 200 according to the prior art is composed of a support member and a rotating member rotatably supported by the support member.

The support member includes a plate 210, a bearing holder 220, a bearing 230, an armature 240, and a thrust washer 250.

The plate 210 is to fix the support member as a whole, and is fixedly installed to a device such as a hard disk drive in which the spindle motor 200 is installed.

The bearing holder 220 is for supporting the bearing 230 to be fixed. The bearing holder 220 is formed in a hollow cylinder shape and is fixed to the plate 210 by being caulked or spun in the direction of the arrow.

In addition, the bearing holder 220 is formed in a stepped portion of the core 241 is fixedly coupled to a portion of the inner circumferential surface 243 and a portion of the lower surface 244 of the core 241.

The bearing 230 is for rotatably supporting the rotating shaft 260, and is formed in a substantially cylindrical shape with a metal such as copper, and the central axis is installed to coincide with the central axis of the rotating shaft 260. In addition, the bearing 230 contains a predetermined lubricant between the rotation shaft 260 to allow the rotation shaft 260 to rotate more smoothly.

The armature 240 is for forming an electric field by receiving an external power source, and consists of a core 241 and a coil 242 wound around the core 241.

The core 241 is made of a predetermined metal material and is fixed to the outer circumferential surface of the bearing holder 220.

The coil 242 rotates the rotor case 270 with a force formed between the magnet 272 of the rotor case 270 by forming an electric field with power applied from the outside.

The thrust washer 250 is for supporting the rotation shaft 260 in the axial direction and contacts the end of the rotation shaft 260 by a thrust washer cover 251 coupled to the inner circumferential surface of the bearing holder 220 by coking or spinning. It is installed as fixed as possible.

On the other hand, the rotating member is provided with a rotating shaft 260, the rotor case 270 and the hook portion 280.

The rotating shaft 260 is for rotatably supporting the rotating member with respect to the supporting member. The rotating shaft 260 is rotatably inserted into the inner diameter of the bearing 230 so that the central axis coincides with the central axis of the bearing 230.

In addition, the end of the rotation shaft 260 is axially supported by the thrust washer 250 and the outer peripheral surface is rotatably supported by the bearing 230.

The rotor case 270 is mounted to rotate the recording medium, not shown, and is fixedly installed on the rotating shaft 260 and has a chucking assembly 271 for fixing the optical disk, not shown.

In addition, the rotor case 270 is installed to be fixed to the inner circumferential wall of the rotor case 270, the magnet 272 for generating a rotational force facing the armature 240. Here, when a current is applied to the coil 242, the rotating member is rotated by the force generated between the coil 242 and the magnet 272.

In addition, the rotor case 270 is fixedly attached along the outer periphery of the ring-shaped rubber turn table 273 to support the optical disk (not shown).

Hook portion 280 is to prevent the separation of the rotating member from the support member, is formed in an annular shape is fixed to the rotor case 270, the end is formed to be bent toward the outer peripheral surface of the bearing holder 220 Engagement with the protrusion 221 formed in the bearing holder 220 prevents the rotor case 270 from being separated.

However, the spindle motor 200 having the above-described configuration has a small coupling area of the bearing holder 220 to which the core 241 is coupled, so that the coupling force between the core 241 and the bearing holder 220 is small. The core 241 is easily separated from the bearing holder 220 by the impact transmitted from the outside.

In addition, in order to achieve the weight reduction of the conventional spindle motor 200, when replacing the plate 210 with a lightweight material such as aluminum plate 210 by the force applied during the coking or spinning process of the bearing holder 210 There was a problem that is transformed.

In addition, since the rotor case 270 is made of a heavy material such as a steel plate, there is a problem that the total weight of the spindle motor 200 is increased.

The present invention has been made to solve the above-mentioned problems of the prior art, an object of the present invention is to achieve a reduction in the weight of the spindle motor by manufacturing a plate and the rotor case of a lightweight material such as aluminum, and to maintain the height of the spindle motor and At the same time to provide an ultra-thin spindle motor that can increase the binding force of the core.

In addition, the bearing holder is press-fitted in a direction perpendicular to the plate to prevent deformation of the plate when assembling the spindle motor, thereby preventing the skew of the rotating shaft or the bearing, thereby providing an ultra-thin spindle motor that can ensure more stable driving characteristics. It is.

In order to achieve the above object of the present invention, the present invention is a plate in which a coupling hole is formed, and a bearing for rotatably supporting a rotating shaft therein is installed therein and at least a part of the plate is press-fitted to the coupling hole to support the lower surface of the plate The bearing holder, the thrust washer cover press-fitted to the bearing holder to support the thrust washer in contact with the end of the rotating shaft, and the bearing holder to support the upper surface of the plate. An armature holder having a coupling protrusion that is fixedly coupled to the armature, and a rotor case having an annular edge portion extending from the edge of the disc and the disc portion where the rotating shaft is fixed and facing the armature, the first magnet being installed on the inner circumferential surface thereof. It can provide an ultra-thin spindle motor comprising a.

Here, the bearing holder is characterized in that it is press-fitted to the coupling hole by a vertical force perpendicular to the plate in order to prevent deformation of the plate.

In addition, the first magnet is characterized in that it is fixed to the inner circumferential surface of the rim portion through the annular back yoke of the metal material.

In addition, the engaging projection of the armature holder is characterized in that it extends adjacent to the rotor case in order to increase the coupling area with the armature.

In addition, the plate is characterized in that made of a lightweight aluminum material.

In addition, the rotor case is characterized in that made of a lightweight aluminum material.

In addition, the bearing holder is characterized in that the annular projection is formed at the upper end.

The ultra-thin spindle motor of the present invention further includes a hook portion engaged with the annular protrusion of the bearing holder to prevent the rotor case from being separated, and the hook portion is disposed between the outer peripheral surface of the bearing holder and the engaging protrusion of the armature holder. It is characterized by.

In addition, the spindle motor of the present invention further includes a second magnet that forms an attraction force between the armature to prevent the floating and flow of the rotor case, the second magnet is installed in the rotor case to be in close contact with one side of the hook portion It is characterized by.

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

1 and 2, the ultra-thin spindle motor 100 according to a preferred embodiment of the present invention includes a support member and a rotating member rotatably supported by the support member.

The support member has a plate 110, a bearing holder 120, a bearing 130, an armature holder 140, an armature 150, and a thrust washer 160.

Plate 110 is for supporting the support member as a whole fixed, it is installed to be fixed to a device such as a hard disk drive, the spindle motor 100 is installed. In addition, the plate 110 is mainly made of a lightweight material such as an aluminum plate or an aluminum alloy plate, but can be made of a steel plate otherwise, the coupling hole 111 is formed in the central portion.

In addition, the plate 110 has a lower surface 112 supported by at least a portion of the bearing holder 120 and an upper surface 113 supported by the armature holder 140.

The bearing holder 120 is for supporting the bearing 130 to be fixed. The bearing holder 120 is press-fitted to the coupling hole 111 by a vertical force in the direction of the arrow orthogonal to the plate 110 in order to prevent deformation of the plate 110. It is preferable.

Here, the bearing holder 120 is composed of a plate coupling portion 121, the holder coupling portion 122, the extension portion 123 and the plate support portion 125.

The plate coupling portion 121 is a portion that is press-fitted to the coupling hole 111, preferably having the same diameter as the coupling hole 111 or have a diameter slightly larger than the coupling hole 111. In the present embodiment, the plate coupling part 121 is press-fitted to the coupling hole 111, but alternatively, the plate coupling part 121 may be press-coupled to the coupling hole 111 and adhesively bonded by a predetermined adhesive.

In addition, after the plate coupling portion 121 is coupled to the coupling hole 111, it is preferable to have the same thickness as the plate 110 so that its upper surface does not protrude to the upper surface 113 of the plate (110).

The holder coupling portion 122 extends integrally from the plate coupling portion 121 and is a portion to which the armature holder 140 is coupled, and is preferably formed to have an outer diameter smaller than that of the plate coupling portion 121.

The extension part 123 integrally extends from the holder coupling part 122 to have an outer diameter smaller than the holder coupling part 122, and has an annular protrusion 124 formed at an upper end thereof.

The annular projection 124 is engaged with the hook portion 190 of the rotating member to prevent the separation of the rotating member.

Here, the upper end of the extension portion 123 to the upper portion of the holder engaging portion 122 is preferably kept constant to form the working space of the hook ring 190.

The plate support part 125 extends radially integrally from the plate coupling part 121 so as to support the lower surface 112 of the plate 110, and supports the lower surface 112 of the plate 110 to support the bearing holder 120. By the impact transmitted from the bottom of the function to prevent the departure of the bearing holder 120.

The bearing 130 is for rotatably supporting the rotating shaft 170, and is formed in a substantially cylindrical shape such as a metal, and the central axis is installed to coincide with the central axis of the rotating shaft 170. In addition, the bearing 130 contains a predetermined lubricating oil between the rotating shaft 170 and the rotating shaft 170 so as to rotate more smoothly.

The armature holder 140 is press-fit fixed to the holder coupling portion 122 of the bearing holder 120 and is fixedly coupled to the armature 150, the inner peripheral surface 141 in close contact with the outer peripheral surface of the holder coupling portion 122 , An outer circumferential surface 142 whose end is collinear with an end of the plate support 125, a lower ground surface 143 supporting at least a portion of the plate 110, and a core 151 of the armature 150 are coupled; Has an upper coupling surface 144.

Here, the upper coupling surface 144 has a coupling protrusion 145 protruding toward the extension portion 123, the coupling protrusion 145 is formed in a right triangle shape as a whole, the hypotenuse facing the bearing holder 120 side. It is formed to see. In addition, one of the two sides forming a right angle is integrally formed on the upper coupling surface 144 and the inner circumferential surface of the armature 150 is tightly coupled to the other side 146, so that the armature 150 is the upper coupling surface 144. And fixedly coupled to the coupling protrusion 145 may increase the coupling force with the armature holder 140.

In addition, the coupling protrusion 145 extends close to the annular protrusion 124 formed in the extension portion 123 to increase the length of the side 146 of the coupling protrusion 145, thereby engaging the area with the armature 150. Can be increased. Therefore, the coupling force with the armature 150 can be increased without increasing the height of the entire spindle motor 100 in order to prevent the armature 150 from being detached, thereby making it possible to meet the thinning of the spindle motor 100.

In addition, the engaging projection 145 forms a predetermined working space 147 between the extension portion 123, the working space 147 is engaged with the annular projection 124 of the hook portion 190 of the rotating member. This means a space in which the hook part 190 is rotated when the rotor case 180 is rotated, and unless the length of the hook part 190 is reduced, the volume of the working space 147 is preferably kept constant.

The armature 150 is for forming an electric field by receiving an external power source, and consists of a core 151 and a coil 152 wound around the core 151.

The core 151 is made of a magnetic material that reacts with the magnet, more specifically, a predetermined metal material that forms an attractive force between the magnet, and the upper coupling surface 144 and the coupling protrusion 145 of the armature holder 140. It is fixedly installed on one side 146.

The coil 152 rotates the rotor case 180 by a force formed between the first magnet 186 of the rotor case 180 by forming an electric field with power applied from the outside.

The thrust washer 160 is for supporting the rotating shaft 170 in the axial direction, and the rotating shaft 170 by the thrust washer cover 161 is press-installed on the inner circumferential surface of the plate coupling portion 121 of the bearing holder 120. It is fixed to be in contact with the end of the.

Here, the thrust washer 160 is preferably disposed on the same line as the upper surface of the plate 110 so that the lower end of the rotation shaft 170 is located on the same line as the upper surface of the plate 110.

On the other hand, the rotating member is for rotating a recording medium such as an optical disk (not shown), and includes a rotating shaft 170, the rotor case 180 and the hook portion 190.

The rotating shaft 170 is for rotatably supporting the rotating member with respect to the supporting member. The rotating shaft 170 is rotatably inserted into the inner diameter portion of the bearing 130 so that the central axis coincides with the central axis of the bearing 130.

In addition, the end of the rotation shaft 170 is axially supported by the thrust washer 160 and the outer circumferential surface thereof is rotatably supported by the bearing 130.

The rotor case 180 is for mounting and rotating an optical disk (not shown), and the disc portion 181 in which the rotating shaft 170 is fixed and the annular edge portion 182 extending from the end of the disc portion 181 are fixed. It is preferable that the disc portion 181 and the edge portion 182 is made of a non-magnetic lightweight material, that is, made of aluminum.

The disc portion 181 is installed to surround the coupling holder 183 and the coupling holder 183 is fixedly inserted into the rotation shaft 170 is fixed to the central portion has a chucking assembly 184 for fixing the optical disk.

In addition, the disc portion 181 is a ring-shaped rubber turn table 185 to support the optical disk (not shown) without slipping is fixedly attached along the outer periphery of the upper surface, and attracts the attraction between the core 151 of the metal material The second magnet 188 to be generated is installed on the lower surface of the disc portion 181 to be in close contact with one side of the hook portion 190. Here, the second magnet 188 prevents the floating and moving of the rotor case 180 when the rotating member is rotated at a high speed.

The edge portion 182 extends so that its inner circumferential surface faces the armature 150, and the first magnet 186 for rotating the rotor case 180 by a force generated between the electric field formed in the coil 152. The inner circumferential surface of the edge portion 182 is fixedly installed via the back yoke 187.

Here, since the first magnet 186 of the present embodiment is installed on the edge portion 182 via the back yoke 187 formed of a magnetic material made of a metal material, the first magnet 186 of the first magnet 186 is sufficient to rotate the rotor case 180. The magnetic field of one magnet 186 can be generated.

In this embodiment, since the rotor case 180 is made of aluminum, which is a nonmagnetic material, the first magnet 186 is installed on the rotor case 180 via a back yoke 187 made of a magnetic material. In contrast, if the rotor case 180 is made of a magnetic material, the first magnet 186 may be directly installed in the rotor case 180.

Hook portion 190 is to prevent the separation of the rotating member from the support member, is formed in an annular shape as a whole and is fixed to the disc portion 181 of the rotor case 180 adjacent to the outer peripheral surface of the bearing holder 120 .

In addition, the end of the hook portion 190 is formed to be bent toward the outer peripheral surface of the extension portion 123 is engaged with the annular projection (124).

While the ultra-thin 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.

According to the ultra-thin spindle motor of the present invention, by combining the bearing holder with a plate made of a lightweight material such as aluminum to achieve a reduction in the weight of the spindle motor, in order to prevent the armature from detaching, without increasing the height of the entire spindle motor In addition, it is possible to provide an ultra-thin spindle motor that can achieve a thinner thickness by increasing the engagement area with the core while maintaining the working space of the hook portion.

In addition, when assembling the bearing holder to the plate, by pressing the bearing holder with a perpendicular force perpendicular to the plate, it is possible to prevent the deformation of the plate, thereby preventing the skew of the rotating shaft or bearing to ensure a more stable driving characteristics Can provide ultra thin spindle motor.

Claims (9)

A plate in which coupling holes are formed; A bearing holder rotatably supporting a rotating shaft therein, the bearing holder being press-fitted into the coupling hole so that at least a portion thereof supports the lower surface of the plate; A thrust washer cover press-fitted to the bearing holder to axially support a thrust washer contacting the end of the rotating shaft; An armature holder press-coupled to the bearing holder to support an upper surface of the plate and having a coupling protrusion fixedly coupled to an armature that generates an electric field by an external power source; And And a rotor case having an annular edge portion extending from the edge of the disc to which the rotary shaft is fixed and facing the armature from an edge of the disc and having a first magnet installed on an inner circumferential surface thereof. The ultra-thin spindle motor according to claim 1, wherein the bearing holder is press-fitted to the coupling hole by a vertical force orthogonal to the plate to prevent deformation of the plate. The ultra-thin spindle motor according to claim 1, wherein the first magnet is fixed to the inner circumferential surface of the edge portion via a metal annular back yoke. The ultra-thin spindle motor according to claim 1, wherein the engaging projection of the armature holder extends adjacent to the rotor case to increase the engaging area with the armature. The ultra-thin spindle motor of claim 1, wherein the plate is made of lightweight aluminum. The ultra-thin spindle motor of claim 1, wherein the rotor case is made of a lightweight aluminum material. The ultra-thin spindle motor according to any one of claims 1 to 6, wherein the bearing holder has an annular protrusion formed at an upper end thereof. 8. The method of claim 7, further comprising a hook portion engaged with the annular projection of the bearing holder to prevent the rotor case from being separated, wherein the hook portion has an outer circumferential surface of the bearing holder and the armature holder. Ultra-thin spindle motor, characterized in that disposed between the engaging projection. The rotor of claim 7, further comprising a second magnet forming an attractive force between the armature to prevent floating and flow of the rotor case, wherein the second magnet is in close contact with one side of the hook portion. Ultra-thin spindle motor, characterized in that installed in the case.

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