KR100614515B1 - Adjusting device for a stator for an optical disk drive motor - Google Patents

Abstract

The optical disc drive motor includes a stator and a main board. At least one adjustment member is provided between the stator and the mainboard. The adjustment member enables the adjustment of the pressing force applied to any one of the stator and the main board to maintain a parallel relationship between the stator and the main board.

Optical disc, drive, motor, main board, stator, rotor, adjusting member

Description

Stator adjuster for optical disc drive motor {ADJUSTING DEVICE FOR A STATOR FOR AN OPTICAL DISK DRIVE MOTOR}

1 is a cross-sectional view showing a conventional optical disk drive motor.

FIG. 2 is a cross-sectional view similar to FIG. 1 illustrating the deflection correction of the disc tray. FIG.

3 is an exploded perspective view partially cut as an embodiment of an optical disk drive motor according to the present invention.

FIG. 4 is a cross-sectional view of the stator and the main board of the optical disc drive motor of FIG. 3 and illustrates the adjustment of the stator position by the adjusting screw.

FIG. 5 is a cross-sectional view of the optical disc drive motor of FIG. 3, illustrating the adjustment after.

6 is a sectional view of a second embodiment of an optical disk drive motor according to the present invention.

7 is an exploded perspective view partially cut as the third embodiment of the optical disk drive motor according to the present invention.

8 is a cross-sectional view of the optical disc drive motor of FIG. 7.

9 is a sectional view of a fourth embodiment of an optical disk drive motor according to the present invention.

The present invention relates to a stator adjustment apparatus for an optical disc drive motor.

The conventional optical disc drive motor illustrated in FIG. 1 includes a disc tray 10, a shaft 20, a rotor 30, and a stator 40. The disc tray 10 is equipped with holding means 11 for holding an optical disc. The shaft 20 is connected to the disc tray 10 and the rotor 30. The stator 40 is fixed to the axle tube 41 and controlled by a main board (such as the circuit board 42) to generate an alternating magnetic field induced by the ring magnet 31 on the rotor 30. By forming, the disk tray 10 and the optical disk are rotated.

In general, the disc tray 10 is inclined with respect to the rotor 30 when mounted on the shaft 20. That is, the disc tray 10 is likely to be positioned in a posture that is not parallel to the rotor 30. In order to prevent unbalanced rotation of the optical disk drive motor and to reduce the product defect rate due to the deflection of the disk tray 10, the disk tray 10 is subjected to grinding processing to reduce the thickness from "a" to "b". As a result, it is necessary to maintain the surface of the disc tray 10 in parallel with the rotor 30. Although the grinding process could correct the deflection of the disc tray 10, the inclination of the stator 40 or the axle tube 41 with respect to the circuit board 42 could not be corrected. Inclination of the axle tube 41 may cause deflection of the shaft 20, the disc tray 10, or the rotor 30. In addition, the balance of the disc tray 10 must be repeatedly checked during the grinding process. As a result, the grinding process takes considerable time. Excessive grinding may also impair the strength and rotational stability of the disc tray 10.

It is an object of the present invention to provide an adjusting device for a stator for an optical disc drive motor for providing a parallel relationship between a main board and a stator.

An optical disc drive motor according to the present invention includes a stator and a main board. At least one adjustment member is provided between the stator and the motherboard. The adjusting member is capable of adjusting the pressing force applied to one stator and the main board, thereby maintaining the stator and the main board in a parallel relationship.

In the first embodiment of the present invention, the optical disc drive motor includes a stator and a main board. The stator includes a plurality of screw holes spaced at regular angles. A plurality of adjustment screws are provided, each having a first end engaged with one of the associated threaded holes of the stator and a second end pressing the motherboard. Each adjusting screw is capable of adjusting the pressing force applied to the main board so as to keep the stator and the main board in a parallel relationship.

In a second embodiment of the present invention, the optical disc drive motor includes a stator and a main board. The motherboard includes a plurality of screw holes spaced at regular angles. A plurality of adjustment screws are provided, each having a first end engaged with one of the associated screw holes of the motherboard and a second end pressing the stator. Each adjusting screw is capable of adjusting the pressing force applied on the stator to keep the stator and the motherboard in a parallel relationship.

In a third embodiment of the invention, an optical disc drive motor includes a mainboard, an axle tube rigidly mounted on the mainboard, and a stator rigidly mounted around the axle tube. The axle tube includes a flange on the outer circumference. The flange includes a plurality of screw holes spaced apart from the motherboard and spaced at an angle. A plurality of adjustment screws are provided, each having a first end that engages one of the associated threaded holes of the flange and a second end that presses the motherboard. Each adjusting screw is capable of adjusting the pressing force applied to the main board so as to keep the stator and the main board in a parallel relationship.

In a fourth embodiment of the present invention, the optical disc drive motor includes a main board, an axle tube rigidly mounted on the main board, and a stator rigidly mounted around the axle tube. The axle tube includes a flange on the outer periphery, which is spaced apart from the mainboard. The motherboard includes a plurality of screw holes spaced at regular angles. A plurality of adjustment screws are provided, each having a first end that engages one of the associated screw holes of the motherboard and a second end that presses the flange. Each adjusting screw is capable of adjusting the pressing force applied on the flange, so as to keep the stator and the motherboard in a parallel relationship.                         

Other objects, specific advantages, and improvements of the present invention will become apparent from the preferred embodiments described below with reference to the accompanying drawings.

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

3 to 5, the first embodiment of the optical disk drive motor according to the present invention generally includes a main board 42 (circuit board, etc.) on which an axle tube 41 is mounted, around an axle tube 41. A stator 40 mounted, and a rotor 30 mounted around the stator 40. The rotor 30 comprises a shaft 20 which is rotationally held in the axle tube 41. In addition, a ring magnet 31 is attached to the rotor 30 to guide the stator 40. The disc tray 10 includes a hole mounted on the rotor 30 and through which the shaft 20 of the rotor 30 passes. The holding means 11 is mounted on the upper side of the disc tray 10 and is firmly coupled to the upper end of the shaft 20 of the rotor 30. The optical disc (not shown) lying on the disc tray 10 is held in place by the holding means 11. And the optical disc and the holding means 11 are rotated together by the shaft 20 of the rotor 30. An anti-slip ring 12 may be mounted on the top of the disc tray 10 to prevent an undesirable sliding operation of the optical disc.

More importantly, the optical disc drive motor includes at least one adjusting member for adjusting the position of the stator 40 relative to the main board 42. In this embodiment, the stator 40 includes a plurality of screw holes 401 spaced at an angle and extending in the transverse direction with the plane in which the stator 40 is placed. The adjusting screw 43 extends through each screw hole 401. As shown in FIG. 5, the adjustment screw 43 extends into the space 44 between the stator 40 and the main board 42. In practice, each adjustment screw 43 is rotated to adjust the pressing force exerted by the end of each adjustment screw 43 relative to the motherboard 42, as shown in FIGS. 4 and 5. The relative position between the stator 40 and the main board 42 is adjusted by rotating the adjustment screw 43 until the stator 40 and the main board 42 are parallel to each other. The deflection of the stator 40 relative to the motherboard 42 can be easily corrected by rotating one or more adjustment screws 43. After adjustment, the adjustment screw 43 may be fixed by welding, fusion, adhesion, or the like according to the material (metal, alloy, plastic, etc.) of the adjustment screw 43. Loosening of the adjustment screw 43 and re-deviation of the stator 40 are prevented. The screw holes 401 may be formed in the central portion 402 of the stator 40 as shown in FIGS. 3 to 5. Alternatively, the screw hole 401 can be formed in the pole 403 of the stator 40 without adversely affecting its function.

6 shows a second embodiment of the present invention, wherein a screw hole 421 is formed in the motherboard 42 instead of the stator 40. Each adjusting screw 43 'presses down the stator 40 through the associated screw hole 421 to the end of each adjusting screw 43'. In practice, each adjusting screw 43 'is rotated to adjust the pressing force exerted by the end of each adjusting screw 43' with respect to the stator 40, as shown in FIG. The relative position between the stator 40 and the main board 42 is adjusted by rotating the adjustment screw 43 'until the stator 40 and the main board 42 are parallel to each other. The deflection of the stator 40 relative to the motherboard 42 can be easily corrected by rotating one or more adjustment screws 43 '. A plurality of bosses 422 are formed above or below the main board 42. Each boss 422 is located below or above the associated screw hole 421 and has a hole that is aligned with the associated hole 421 to reinforce the structure of the motherboard 42. The screw hole 421 of the motherboard 42 may be selected such that the adjusting screw 43 ′ presses the central portion 402 of the stator 40 or the pole 403 of the stator 40.

7 and 8 show a third embodiment of the present invention. In this embodiment, the axle tube 41 mounted to the main board 42 includes a flange 412 on the outer periphery, and the flange 412 is spaced apart from the main board 42. A plurality of screw holes 411 are formed in the flange 412 and spaced apart at a predetermined angle. The adjusting screw 43 "extends through each screw hole 401. As shown in Fig. 8, each adjusting screw 43" is actually an adjusting screw 43 "with respect to the motherboard 42. As shown in FIG. And the relative position between the stator 40 and the main board 42 is adjusted until the stator 40 and the main board 42 are parallel to each other. ") By rotating it. The deflection of the stator 40 relative to the motherboard 42 can be easily corrected by rotating one or more adjustment screws 43 ".

Stator 40 has a plurality of through holes 404 that align with associated threaded holes 411 of flange 412. A tool (not shown) may be inserted into each through hole 404 to rotate each adjustment screw 43 ". Although not specifically shown in FIGS. 7 and 8, the top or bottom of the flange 412 is not shown. A plurality of bosses may be formed in. Each boss is positioned below or above the associated threaded hole 411 and has a hole aligned with the associated hole 411 to reinforce the structure of the flange 412. 412 is preferably formed integrally with the axle tube 41.

9 shows a fourth embodiment of the invention in which the third embodiment is modified, wherein a screw hole 423 is formed in the motherboard 42 instead of the flange 412 of the axle tube 41. Each adjustment screw 43 "extends beyond the associated threaded hole 423 and presses down the flange 412 to the distal end of each adjustment screw 43". In practice, each adjusting screw 43 "is rotated to adjust the pressing force exerted by the distal end of each adjusting screw 43" with respect to the flange 412, as shown in FIG. And the relative position between the stator 40 and the main board 42 is adjusted by rotating the adjustment screw 43 "until the stator 40 and the main board 42 are parallel to each other. The deflection of the stator 40 with respect to can be easily corrected by rotating one or more adjustment screws 43 ". A plurality of bosses 424 are formed above or below the main board 42. Each boss 424 is positioned below or above the associated threaded hole 423 and has a hole aligned with the associated threaded hole 423 to enhance the structure of the motherboard 42. The flange 412 is preferably formed integrally with the axle tube 41.

The adjusting screws 43. 43 ', 43 "and the screw holes 401, 411, 421, 423 may be replaced by other suitable means without departing from the scope of the present invention. The adjusting means may be of different lengths, for example. Columns, various elastic members having different moduli of elasticity, and the like.

Comparing FIG. 1 with FIG. 3, the stator is provided by providing an adjusting member (adjusting screw; 43, 43 ', 43 ") and a screw hole 401, 411, 421, 423 to adjust the pressing force provided by the adjusting member. The 40 and the main board 42 may be parallel to each other to correct the deflection of the stator 40 with respect to the main board 42. Damage of the disc tray 10 due to excessive grinding as in the prior art and Time-consuming processing of the disc tray 10 can be avoided.Grinding processing of the disc tray 10 in the prior art also makes it impossible to correct the deflection of the stator 40 relative to the motherboard 42. In conclusion, The stator 40 and the main board 42 of the optical disk drive motor according to the present invention are adjusted in a parallel relationship with each other by non-destructive means The adjustment process is simple, easy and can be made in a relatively short time.

As described above, while the present invention has been described through preferred embodiments, it should be understood that various modifications and changes can be made without departing from the scope of the present invention. Therefore, the matters set forth in the claims mean that such modifications and variations are within the true scope of the present invention.

According to the present invention, there is provided an adjusting device of a stator for an optical disc drive motor for providing a parallel relationship between a main board and a stator.

Claims (22)

A stator having at least one screw hole, a main board, and at least one adjusting member provided between the stator and the main board and including an adjusting screw, The at least one screw hole of the stator receives the adjustment member, and at least one boss is provided at one end opening of the at least one screw hole, so that the stator and the main board are adjusted by the boss guiding the adjustment member. So that they are parallel to each other, The at least one adjusting member may rotate the adjusting member until the stator and the main board are parallel to each other, thereby adjusting the pressing force applied to any one of the stator and the main board. Kept in parallel relation to each other Optical disc drive motor. delete The method of claim 1, And said at least one adjustment member is fixed to said stator by any one of welding, fusion, and gluing when said stator and said mainboard are parallel to each other. The method of claim 1, And said stator comprises said at least one screw hole for engaging an end of said at least one adjusting screw. The method of claim 4, wherein And the one or more screw holes are formed in the center of the stator. The method of claim 4, wherein And said at least one screw hole is formed in at least one of a plurality of poles of said stator. The method of claim 4, wherein And at least one boss having a hole aligned with the at least one screw hole is formed above or below the stator. A stator, a motherboard having at least one screw hole, and at least one adjustment member provided between the stator and the motherboard so that an end thereof is engaged with the stator, the adjustment member comprising an adjustment screw, The one or more screw holes of the main board accommodate the adjusting member, and one or more bosses are provided at one end opening of the one or more screw holes such that the boss guides the adjusting member so that the stator and the main board are secured. To be parallel to each other when adjusting, The at least one adjusting member maintains the stator and the main board in a parallel relationship with each other by adjusting the pressing force applied between the stator and the main board. Optical disc drive motor. The method of claim 8, And one or more bosses having holes aligned with the one or more screw holes, above or below the main board. The method of claim 8, And said at least one regulating member presses a central portion of said stator. The method of claim 8, And said at least one regulating member presses at least one of said plurality of poles of said stator. A stator, a motherboard, and one or more adjustment members, The stator is firmly mounted on an axle tube spaced from the mainboard, the axle tube has a flange on an outer periphery, the flange having one or more threaded holes, The at least one adjustment member comprising an adjustment screw provided between the flange and the main board such that one end is coupled to at least one screw hole of the flange and the other end is pressed against the main board, The at least one adjustment member maintains the stator and the main board in a parallel relationship with each other by adjusting a pressing force applied between the flange and the main board. Optical disc drive motor. The method of claim 12, And the flange includes one or more bosses formed above or below and having holes aligned with the one or more screw holes. The method of claim 12, And the stator includes at least one through hole aligned with at least one screw hole of the flange. A stator, a motherboard, and one or more adjustment members, The stator is firmly mounted on an axle tube spaced from the mainboard, the axle tube has a flange on an outer circumference, the mainboard has one or more threaded holes, Said at least one adjustment member comprising an adjustment screw provided between said flange and said motherboard such that one end is coupled to at least one screw hole of said motherboard and the other end is pressed against said flange, The at least one adjustment member maintains the stator and the main board in a parallel relationship with each other by adjusting a pressing force applied between the flange and the main board. Optical disc drive motor. The method of claim 15, And said main board has at least one hole aligned with said at least one screw hole, said main board including at least one boss formed above or below said main board. A stator, a motherboard, and a plurality of adjustment screws, The stator comprises a plurality of threaded holes spaced at regular angles and a plurality of bosses provided in the plurality of screw holes, Said plurality of adjustment screws each having a first end engaged with an associated one of the screw holes of the stator and a second end pressed against the motherboard; The plurality of bosses guide the adjusting screw so that the stator and the main board are parallel to each other during adjustment, And the plurality of adjustment screws each enable adjustment of the pressing force applied to the main board to maintain the stator and the main board in a parallel relationship with each other. The method of claim 17, And the screw hole is formed in the center of the stator. A stator, a motherboard, and a plurality of adjustment screws, The main board includes a plurality of screw holes spaced at a predetermined angle and a plurality of bosses provided in the plurality of screw holes, Said plurality of adjustment screws each having a first end engaged with an associated one of the screw holes of the motherboard and a second end pressed against the stator, The plurality of bosses guide the adjusting screw so that the stator and the main board are parallel to each other during adjustment, And the plurality of adjusting screws each enable adjustment of the pressing force applied to the stator to maintain the stator and the main board in a parallel relationship with each other. A main board, an axle tube firmly mounted on the main board, a stator firmly mounted on the axle tube, and a plurality of adjustment screws; The axle tube includes a flange on an outer circumference, The flange comprises a plurality of screw holes spaced apart from the main board and spaced at an angle with respect to each other, The plurality of adjustment screws each have a first end coupled with an associated one of the threaded holes of the flange and a second end pressed against the main board, the plurality of adjustment screws respectively being connected to the main board. To allow adjustment of the applied pressure to maintain the stator and the main board in a parallel relationship with each other Optical disc drive motor. The method of claim 20, And the stator includes a plurality of through holes, each aligned with a screw hole of the flange. A main board, an axle tube firmly mounted on the main board, a stator firmly mounted on the axle tube, and a plurality of adjustment screws; The axle tube includes a flange on an outer circumference, The flange is spaced apart from the mainboard, The main board includes a plurality of screw holes spaced at an angle with respect to each other, The plurality of adjustment screws each have a first end engaged with an associated one of the screw holes of the motherboard and a second end pressed against the flange, each of the plurality of adjustment screws applied to the flange. It allows the adjustment of the pressing force to keep the stator and the main board in a parallel relationship with each other. Optical disc drive motor.

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