KR100716822B1 - Hydrodynamics bearing motor - Google Patents

Abstract

The dynamic bearing motor 100 of the present invention includes a rotor hub 110 for driving a recording medium and a sleeve 120 for rotatably supporting the rotor hub 110, and a base for fixing the sleeve 120 ( 130, the sleeve 120 has a coupling portion 123 that is press-bonded to the base 130 and at the same time adhesively coupled, the coupling portion 123 is formed with a plurality of coupling grooves formed at regular intervals on the outer peripheral surface ( 124). The plurality of coupling grooves 124 are formed to be inclined with respect to the axial direction of the coupling portion 123 so as to extend from the top to the bottom of the coupling portion 123 and the adhesive is injected therein.

Dynamic Bearing Motor, Press-fitting, Bonding, Coupling Groove, Coupling Force

Description

Hydrodynamic Bearing Motors {Hydrodynamics bearing motor}

1 is a schematic view of a dynamic bearing motor according to a first embodiment of the present invention;

2 is an enlarged schematic view of the sleeve of FIG. 1;

3A and 3B are enlarged schematic views of the coupling groove of FIG. 1;

4 is a schematic view of a dynamic bearing motor according to a second embodiment of the present invention;

5 is an enlarged schematic view of the sleeve of FIG. 4; And

6 is a schematic view of a conventional dynamic bearing motor.

<Explanation of symbols for main parts of drawing>

100, 200: dynamic bearing motor 110, 210: rotor hub

120, 220: sleeve 123, 223: coupling portion

124, 224: coupling groove 226: connection groove

130, 230: base 140, 240: housing

The present invention relates to a dynamic bearing motor, and more particularly to a dynamic bearing motor that can increase the coupling force between the sleeve and the base.

The hydrodynamic bearing motor is installed with a hydrodynamic bearing for generating dynamic pressure therein, and is used in a hard disk drive or the like. In recent years, as such dynamic bearing motors are used in portable products such as MP3 players and mobile phones, there has been a large movement to miniaturize dynamic bearing motors, and an example of such dynamic bearing motors is shown in FIG. 6.

As shown in FIG. 6, the conventional dynamic bearing motor 300 includes a rotor hub 310, a sleeve 320, and a base 330.

The rotor hub 310 is a driving means for mounting and rotating the recording medium, such as a hard disk (not shown) on the top, and has a disc portion 311 and a cylindrical portion 313.

The disc portion 311 is formed integrally with the shaft portion 312 in the inner center, and extends radially with respect to the shaft portion 312 to form a disc shape.

The cylindrical portion 313 extends from the outer periphery of the disc portion 311 toward the distal end of the shaft portion 312 so that the end portion is formed in a cylindrical shape longer than the end portion of the shaft portion 312, and has a mounting portion 314 on which a recording medium is mounted. The magnet 315 is fixedly installed below the mounting portion 314.

Sleeve 320 is a support means for rotatably supporting the rotor hub 310, has a dynamic pressure generating portion 321 and the coupling portion 323.

Dynamic pressure generating unit 321 is a portion for generating dynamic pressure between the rotor hub 310, the shaft coupling groove 322 for rotatably supporting the shaft portion 312 is formed in the upper center.

The coupling part 323 is a part press-fitted to the base 330, and is integrally formed under the dynamic pressure generating part 321 to have a diameter smaller than that of the dynamic pressure generating part 321.

The base 330 is a fixing means for fixing the sleeve 320, and has a bottom portion 331 and a sleeve support 333.

The bottom part 331 is substantially disk-shaped, and the core 332 which rotates the rotor hub 310 in conjunction with the magnet 315 is installed in the upper surface. The sleeve support part 333 is formed to protrude substantially in a hollow cylinder shape from the center of the bottom part 331, and the coupling part 323 is press-fitted.

In this case, the sleeve 320 may be installed in the base 330 through a separate housing 340, the housing 340 is a metal material that is expanded when heated to a predetermined temperature, the heated and expanded housing 340 After the sleeve 320 is press-fitted to the) may be installed on the base 330.

In the coupling of the sleeve 320 and the base 330 in the conventional dynamic pressure bearing motor 300, the conventional hot pressing method to press-fit the sleeve 320 after the metal housing 340 is expanded and expanded. Alternatively, an epoxy bond was injected between the housing 340 and the sleeve 320, and then an adhesive bonding method of heating and curing in a high temperature chamber was used.

However, in the dynamic bearing motor 300 having the above-described configuration, since the area of the coupling portion between the sleeve 320 and the housing 340 is small and the coupling force is small, the sleeve 320 can be easily removed from the housing 340 by an external impact. There was a separate issue.

The present invention has been made to solve the above-mentioned problems of the prior art, the object of the present invention is to fix the sleeve, by using a conventional hot press bonding method and the adhesive coupling method of the dynamic bearing bearing with increased coupling force To provide.

In order to achieve the object of the present invention described above, the present invention includes a support means for rotatably supporting the drive means for driving the recording medium and a fixing means for fixing the support means, the support means is press-fit into the fixing means It is possible to provide a dynamic pressure bearing motor, characterized in that the bonded and bonded at the same time.

Here, the support means is characterized in that the area that is adhesively bonded to the fixing means non-contact.

In addition, the non-contacting region is characterized in that it is formed inclined with respect to the axial direction of the support means.

A dynamic bearing motor according to an embodiment of the present invention includes a rotor hub for driving a recording medium, a sleeve for rotatably supporting the rotor hub, and a base for fixing the sleeve, the sleeve being press-fitted to the base. It has a coupling portion, the coupling portion is characterized in that at least a portion is adhesively bonded to the base.

Here, at least a part of the adhesive bond is characterized in that the plurality of coupling grooves formed at a predetermined interval on the outer peripheral surface of the coupling portion.

In addition, the plurality of coupling grooves are characterized in that formed inclined with respect to the axial direction of the coupling portion.

In addition, the plurality of coupling grooves are characterized in that formed to extend from the top to the bottom of the coupling portion.

On the other hand, the dynamic bearing motor according to another embodiment of the present invention further comprises a connection groove formed in the circumferential direction on the outer circumferential surface of the coupling portion, the connection groove is characterized in that it intersects a plurality of coupling grooves.

Here, the coupling groove is characterized in that formed in a parallelogram consisting of two sides and the bottom side.

Further, the parallelogram has a relationship of tan (θ) ≦ H / Ｗ when 0 <θ <90 when the base side is Ｗ, the height is H and the inclination angle is θ, and when -90 <θ <0, -tan It is characterized by following the relationship of (θ) ≦ H / Ｗ.

Hereinafter, a dynamic pressure bearing motor according to preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

First embodiment

As shown in FIG. 1, the dynamic pressure bearing motor 100 according to the first embodiment of the present invention includes a rotor hub 110, a sleeve 120, and a base 130.

The rotor hub 110 is a driving means for rotating and driving a recording medium such as a hard disk (not shown) on the top, and has a disc portion 111 and a cylinder portion 113.

The disc portion 111 is formed integrally with the shaft portion 112 in the inner center, and extends radially with respect to the shaft portion 112 to form a disc shape. The shaft portion 112 axially supports the disc portion 111 with respect to the sleeve 120, and the end portion is inclined to facilitate driving.

The cylindrical portion 113 extends from the outer periphery of the disc portion 111 toward the distal end of the shaft portion 112 and has an end portion formed in a cylindrical shape longer than the end portion of the shaft portion 112, and has a mounting portion 114 on which a recording medium is mounted. . The mounting portion 114 extends outwardly from the outer circumferential surface of the cylindrical portion 113 in a ring shape, and a magnet 115 is fixed to the bottom thereof.

In addition, the rotor hub 110 generates dynamic pressure by the fluid stored between the sleeve 120 and, more specifically, forms a dynamic pressure generating space between the inner side of the rotor hub 110 and the outer side of the sleeve 120. .

Sleeve 120 is a support means for rotatably supporting the rotor hub 110, the cross section is formed in a cylindrical shape of Y overall, has a dynamic pressure generating portion 121 and the coupling portion 123.

Dynamic pressure generating unit 121 is a portion for generating dynamic pressure between the rotor hub 110, the shaft coupling groove 122 for rotatably supporting the shaft portion 112 is formed in the upper center. The shaft coupling groove 122 is formed to a depth corresponding to the length of the shaft portion 112 and the lower end is inclined to match the shaft portion 112 is inclined.

In addition, the dynamic pressure generating unit 121 forms a dynamic pressure generating space between the inner side of the rotor hub 110, more specifically, between the disc 111 and the cylindrical portion 113 to store a predetermined fluid therein, and the rotor An unshown dynamic pressure generating groove is formed to be opened in the dynamic pressure generating space so as to generate dynamic pressure when the hub 110 rotates.

Alternatively, the dynamic pressure generating groove may be formed in the disc 111 and the cylindrical portion 113 to open in the dynamic pressure generating space.

The coupling part 123 is a part that is press-coupled to the base 130 and adhesively bonded at the same time, and is integrally formed at the lower side of the dynamic pressure generating part 121 to have a diameter smaller than that of the dynamic pressure generating part 121, and a plurality of coupling grooves are provided. Has 124.

The coupling groove 124 is formed on the outer circumferential surface of the coupling portion 123 to be inclined with respect to the axial direction of the coupling portion 123 at regular intervals, the lower end of which is open from the lower side of the coupling portion 123 to the outside. Thus, a predetermined adhesive may be injected into the coupling groove 124 under the coupling portion 123.

The sleeve 120 having such a coupling groove 124 will be described in more detail with reference to FIGS. 2 and 3.

The base 130 is a fixing means for fixing the sleeve 120, and has a bottom portion 131 and a sleeve support 133.

The bottom portion 131 is substantially disk-shaped, and the core 132 for rotating the rotor hub 110 in conjunction with the magnet 115 is installed on the upper surface. The sleeve support part 133 is formed to protrude substantially in a hollow cylindrical shape from the center of the bottom part 131, the diameter is formed to be the same as the coupling part 123 of the sleeve 120, the coupling part 123 is press-fitted do.

In this case, the sleeve 120 may be installed in the base 130 through a separate housing 140, and the housing 140 is a metal material that is expanded when heated to a predetermined temperature, and the heated and expanded housing 140. After the sleeve 120 is press-fitted to the) may be installed on the base 130.

In the above-described dynamic pressure bearing motor 100 of the present invention, as shown in FIGS. 2, 3A, and 3B, a plurality of coupling grooves 124 are formed in the coupling portion 123 of the sleeve 120.

Coupling portion 123 has a cylindrical shape as a whole, a plurality of coupling grooves 124 is formed over the outer peripheral surface of the coupling portion 123, the non-contact area non-contact with the contact area 125 in contact with the base 130 or the housing 140 124 is formed. Here, the contact region 125 represents a portion to be press-fitted, and the non-contact region 124 represents a coupling groove 124 that is adhesively bonded by a predetermined adhesive after the press-fitting.

Here, the coupling groove 124 is formed to be inclined with respect to the axial direction AA of the sleeve 120, it is formed to extend from the top to the bottom of the coupling portion 123.

In addition, in the present embodiment, the coupling groove 124 is formed to the left side, otherwise it may be formed to the right side. In this case, the inclination direction of the coupling groove 124 may be determined in consideration of the direction of the rotational force or torque applied to the sleeve 120 as the rotor hub 110 is rotated.

In addition, the coupling groove 124 has a parallelogram (□ abcd) shape consisting of two sides and a bottom side in the coupling portion 123.

Here, the contact area 125 and the non-contact area 124 are formed inside the rectangle? Aa'd'd, which is indicated by a dotted line, by extending the two points a and d on the upper side of the parallelogram □ abcd. At the same time, the indentation and adhesive bonding are simultaneously generated. Similarly, in the square (□ b'bcc ') on the right side of the parallelogram (□ abcd), indentation and adhesive bonding occur at the same time, thereby increasing the overall bonding force.

In addition, a part of the contact area 125 is a non-contact area inside a rectangle? Dd'bb ', which is vertically extended with two points d and b positioned at the center of the parallelogram? Abcd. Since it is disposed on the upper and lower sides of the 124, press-fitting and adhesive bonding may occur at the same time, thereby press-fitting and adhesive bonding throughout the coupling portion 123 is to increase the overall binding force.

At this time, when the bottom side of the coupling groove 124, the height is H, the inclination angle is θ, the width and the inclination angle of the coupling groove 124 is preferably in accordance with the relationship of the following equation (1) and (2), Equation 1 corresponds to the case where the coupling groove 124 is designed to the left, Equation 2 is designed to the right.

If 0 <θ <90,

H / tan (θ) -W ≥ 0, H-Wtan (θ) ≥ 0 (∵ tan (θ)> 0),

Wtan (θ) ≤H

tan (θ) ≦ H / W.

When -90 <θ <0,

H / tan (-θ) -W ≥ 0, H-Wtan (-θ) ≥ 0 (∵ tan (-θ)> 0),

Wtan (-θ) ≤H

tan (-θ) ≦ H / W.

Therefore, the inclination angle θ can be set in the relation of | tan (θ) | ≦ H / W (−90 <θ <90), and θ is preferably 35 ° in this embodiment.

Second embodiment

Next, a dynamic bearing motor 200 according to a second embodiment of the present invention will be described with reference to FIG. 4. Since the dynamic bearing motor 200 of the present embodiment is substantially the same as the dynamic bearing motor 100 described above except for a part of the sleeve 220, a description of the same configuration will be omitted.

The coupling part 223 of the sleeve 220 is a part that is press-coupled to the base 230 and adhesively bonded at the same time, and is integrally formed under the dynamic pressure generating part 221 to have a diameter smaller than that of the dynamic pressure generating part 221. , Has a plurality of coupling grooves (224).

Coupling groove 224 is formed on the outer circumferential surface of the coupling portion 223 to be inclined with respect to the axial direction of the coupling portion 223 at a predetermined interval, the lower end is opened to the outside from the lower side of the coupling portion 223. As a result, a predetermined adhesive may be injected into the coupling groove 224 under the coupling portion 223.

In addition, the plurality of coupling grooves 224 may be connected to each other by a connection groove 226 formed in the circumferential direction of the coupling portion 223.

The sleeve 220 having the coupling groove 224 and the connection groove 226 will be described in more detail with reference to FIG. 5.

As shown in FIG. 5, the coupling portion 223 has a cylindrical shape as a whole, and a plurality of coupling grooves 224 are formed on the outer circumferential surface of the coupling portion 223 to contact the base 230 or the housing 240. A non-contact area 224 is formed that is not in contact with 225. Here, the contact region 225 represents a portion to be press-fitted, and the non-contact region 224 represents a coupling groove 224 to be adhesively bonded by a predetermined adhesive after the press-fitted.

Here, the coupling groove 224 is formed to be inclined with respect to the axial direction AA of the sleeve 220, in the present embodiment, the coupling groove 224 is formed to the left, but may be formed to the right otherwise.

In addition, the coupling groove 224 is not formed over the entirety of the coupling portion 223 along the axial direction AA, and the upper side of the coupling groove 224 is formed with a predetermined distance from the upper end of the coupling portion 223.

In addition, the coupling part 223 further includes a connection groove 226 formed on the outer circumferential surface in the circumferential direction, and the connection groove 226 crosses the plurality of coupling grooves 224 to connect the coupling grooves 224 with each other. .

Since the plurality of coupling grooves 224 are connected to each other through the coupling groove 226, when the adhesive is injected through one coupling groove 224, the adhesive is connected to the other coupling grooves 224 through the coupling groove 226. It may be pushed and injected, and when the adhesive is injected, air that may exist inside the coupling groove 224 may be discharged to the outside.

Thus, the adhesive can be more easily injected into the plurality of coupling grooves 224.

Here, the coupling groove 224 of the present embodiment preferably follows the relationship of Equations 1 and 2 of the above-described first embodiment.

The dynamic pressure bearing motor of the present invention has been described above with reference to preferred embodiments of the present invention, but 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 dynamic pressure bearing motor of the present invention, since a plurality of coupling grooves are formed in the coupling portion of the sleeve to be hot press-fitted to the base or the housing, the adhesive force of the sleeve is mixed because the conventional hot press-fitting method and the adhesive coupling method are mixed. This can be increased.

In addition, the adhesive injection process may be smooth since the adhesive injected into one coupling groove may be injected into the other coupling grooves through the coupling groove by forming a connection groove crossing the plurality of coupling grooves and connecting to each other.

In addition, the bubbles present in the coupling groove may be discharged to the outside through the connection groove, the adhesive may be injected into the coupling groove.

Claims (10)

Support means for rotatably supporting drive means for driving the record carrier; And A fixing means for fixing the support means, The support means is a dynamic bearing motor, characterized in that the pressure-bonded and adhesively coupled to the fixing means at the same time. The method of claim 1, The support means is a dynamic bearing motor, characterized in that the adhesively bonded area is in contact with the fixing means. The method of claim 2, The non-contacting region is a dynamic bearing motor, characterized in that formed inclined with respect to the axial direction of the support means. A rotor hub for driving the recording medium; A sleeve for rotatably supporting the rotor hub; And A base for fixing the sleeve, The sleeve has a coupling portion that is press-fitted to the base, the coupling portion is a dynamic bearing motor, characterized in that at least a portion is adhesively bonded to the base. The method of claim 4, wherein At least a portion of the adhesive bond is a dynamic bearing motor, characterized in that a plurality of coupling grooves formed at regular intervals on the outer peripheral surface of the coupling portion. The method of claim 5, The plurality of coupling grooves are dynamic bearing motor, characterized in that formed inclined with respect to the axial direction of the coupling portion. The method of claim 6, The plurality of coupling grooves is a dynamic bearing motor, characterized in that formed to extend from the upper end to the lower end. The method of claim 6, And a coupling groove formed in the circumferential direction on the outer circumferential surface of the coupling portion, wherein the coupling groove crosses the plurality of coupling grooves. The method according to any one of claims 6 to 8, The coupling groove is a dynamic pressure bearing motor, characterized in that formed in a parallelogram consisting of two sides and the base. The method of claim 9, The parallelogram has a relationship of tan (θ) ≦ H / Ｗ in the case of 0 <θ <90 when the base side is Ｗ, the height is H and the inclination angle is θ, and when -90 <θ <0, -tan ( A dynamic pressure bearing motor according to the relationship θ) ≦ H / Ｈ.

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