KR20090016284A - A skew adjusting apparatus for disk drive - Google Patents

Abstract

A skew adjusting apparatus of a disk drive is provided to prevent the deformation of the connection boss and improve skew adjustment accuracy by inducing dispersion of stress even if the slope of the motor plate is changed during the skew adjustment. A skew adjusting apparatus of a disk drive comprises an optical pick-up base in which an optical pick-up is installed to be movable, a spindle holder part provided with a skew boss in which a skew screw for skew adjustment is inserted, a motor plate(58) in which a spindle motor rotating a disc is equipped, and a connection boss(50) in which one or more chamfers are formed on the side contacting the motor plate.

Description

Skew adjusting apparatus for disk drive

The present invention relates to a disk drive, and more particularly, to a skew adjusting device of a disk drive that enables skew adjustment by adjusting the inclination and height of the spindle motor.

Optical discs, which are optical data recording media, generally include compact discs (CDs) and digital video discs that are compatible with existing compact discs and have increased recording capacities.

The optical disk is clamped in a state of being seated on a turntable rotated by a spindle motor to reflect the laser beam emitted from the optical pickup moving along the radial direction of the optical disk, so that the reflectance of the beam on which the optical pickup is reflected or the phase of the beam at the time of reflection Or read data through polarization change.

In order to record a signal on the signal recording surface of the disk and reproduce the recorded signal in the optical disk player for reproducing the optical disk, it is preferable that the light irradiated from the optical pickup is incident perpendicularly to the signal recording surface of the disk.

In practice, however, the optical path in the optical pickup is inclined, or the spindle motor portion to which the optical disk is mounted is inclined, so that an angular error occurs in which the optical axis of the optical pickup and the recording surface of the optical disk are not orthogonal to each other. It is called. This angular error causes optical aberration (a phenomenon in which the direction of the light source is different to the observer moving in a direction perpendicular to the direction of light), resulting in deterioration of the read signal. This is called Skew Adjustment.

1 and 2 show a perspective view from below of a skew adjusting device of a disk drive according to the prior art.

As shown in these figures, the optical pickup base 2 is installed so that its tip is elevated by the lifting base 4 provided in the main base (not shown). This is to prevent the optical pickup base 2 from interfering with the disc tray (not shown) during loading and unloading of the disc.

The optical pickup base 2 is formed so that the optical pickup transfer window 6 is opened up and down. A pair of guide shafts 8, 8 ′ are provided in parallel on the optical pickup base 2 corresponding to both ends of the optical pickup transfer window 6. The guide shafts 8 and 8 'serve to enable the linear reciprocating motion of the optical pickup 10 in the optical pickup transfer window 6. The optical pickup 10 shoots light onto the disc to record a signal on the disc or read a signal recorded on the disc.

The spindle holder 12 is provided at the front end of the optical pickup base 2. The spindle holder 12 is generally formed in the optical pickup base 2 by insert injection molding.

The spindle holder portion 12 is formed to protrude a fastening boss 13 through the center. The fastener B penetrates inside the fastening boss 13 to fix the spindle holder 12 to the motor plate 14 to be described below. When the optical pickup base 2 is viewed from the bottom of FIG. 1, the bottom surface of the fastening boss 13 is supported by the top surface of the motor plate 14.

On both sides of the spindle holder 12, a skewed boss 13 'having a center penetrated is formed to protrude. A skew spring S is mounted on the skew boss 13 ′, and a skew screw C is inserted into the skew spring S to couple the motor plate 14 to the optical pickup base 2. Therefore, the height of the spindle motor 18 to be described below is adjusted by adjusting the fastening degree of the screw (C).

A motor plate 14 is provided on the bottom of the spindle holder 12. The motor plate 14 has a plate shape and is fastened to the optical pickup base 2 through a fastener B.

On the other hand, the motor plate 14 is equipped with a spindle motor 18 that provides a driving force for rotating the disk. The rotary shaft of the spindle motor 18 is provided with a turntable 20 on which a disk is seated. The turntable 20 is rotated together with the disk seated by the drive of the spindle motor 18.

However, the above-described skew adjusting apparatus for a disk drive according to the prior art has the following problems.

In the related art, since the upper surface of the fastening boss 13 in contact with the motor plate 14 is designed to be flat as shown in FIG. 2, the fastening boss 13 may be changed due to a change in the inclination of the motor plate 14 during skew adjustment. Stress is concentrated on one side of the edge. Due to the stress concentration, the edge height of the fastening boss 13 is changed differently from the designed one, and an error occurs in the set distance between the optical pickup 10 and the disk, which is a problem such as deformation of the motor plate 14. Generates.

The present invention is to solve the problems of the prior art as described above, an object of the present invention is a skew adjusting device of the disk drive that can alleviate the concentration of stress on the fastening boss according to the change in the tilt of the motor plate during skew adjustment To provide.

According to a feature of the present invention for achieving the object as described above, the present invention includes an optical pickup base to which the optical pickup is movable; A spindle holder portion provided at one end of the optical pickup base and having a skew boss for inserting a skew screw for adjusting the skew on both sides; A motor plate mounted to the optical pickup base to support the spindle holder and provided with a spindle motor for rotating the disk; It is provided to the spindle holder portion is fastened to the motor plate, and comprises a fastening boss for forming at least one chamfer on the surface in contact with the motor plate.

The chamfer is formed to be inclined in the direction in which the motor plate is inclined during skew adjustment.

The fastening boss is provided at a predetermined distance from the extension line connecting the skew boss to the front end of the optical pickup base.

The chamfer is formed in a pair symmetrical with respect to the through-hole formed in the fastening boss.

The chamfer is formed with one or more inclined surfaces having different inclinations.

The chamfer is curved and rounded.

According to the present invention, since the chamfer is formed in the fastening boss, the deformation of the fastening boss can be prevented by inducing stress distribution even if the inclination of the motor plate changes during skew adjustment, which increases the accuracy of the skew adjustment.

Hereinafter, a preferred embodiment of a skew adjusting apparatus for a disk drive according to the present invention having the configuration as described above will be described in detail with reference to the accompanying drawings.

3 is a perspective view of the configuration of a preferred embodiment of the disk drive according to the present invention, Figure 4 is a perspective view of the configuration of the spindle holder in the embodiment of the present invention, Figure 5 is a fastening boss in the embodiment of the present invention And the configuration of the motor plate is shown in side view. For reference, FIG. 3 is a view illustrating a lower portion of the optical pickup base in the embodiment of the present invention.

As shown in these figures, the optical pickup base 32 is installed so that its tip is elevated by the lifting base 34 provided in the main base (not shown). This is to prevent the optical pickup base 32 from interfering with the disc tray (not shown) during loading and unloading of the disc.

The optical pickup base 32 is formed so that the optical pickup transfer window 36 having a predetermined length and width is opened up and down. The optical pickup transfer window 36 is a portion where the optical pickup 40 to be described below is moved back and forth.

A pair of guide shafts 38 and 38 'are disposed in parallel on the optical pickup base 32 corresponding to both ends of the optical pickup transfer window 36. The optical pickup 40 is provided on the guide shafts 38 and 38 'to enable a linear reciprocating motion in the optical pickup transfer window 36. The optical pickup 40 shoots light onto the disk to record a signal on the disk or to read a signal recorded on the disk.

One side of the optical pickup base 32 is provided with a slad motor 42. The slad motor 42 is a driving source for rotating the lead screw 44, and serves to move the optical pickup 40 meshed with the lead screw 44 by a gear. That is, when the slad motor 42 is driven, the lead screw 44 is rotated and the optical pickup 40 in the optical pickup transfer window 36 in conjunction with the rotation of the lead screw 44 You will have a straight reciprocating motion.

A spindle holder 46 is provided at the tip of the optical pickup base 32. The spindle holder portion 46 is generally formed in the optical pickup base 32 by insert injection molding. However, the spindle holder portion 46 is not necessarily formed by insert injection molding, but may be formed in the optical pickup base 32 as a separate mold according to design conditions.

The spindle holder part 46 is generally made of a plastic material, a polyacetal resin (POM) that is easy to injection molding because of its excellent mechanical properties and excellent moldability.

The configuration of the spindle holder portion 46 is well illustrated in FIG. 4, and skew bosses 48 are formed at both ends of the spindle holder portion 46, and the fastening boss 50 is the spindle holder portion 46. ) Is formed in the center of the. The fastening boss 50 is provided to be spaced apart a predetermined distance in the front end direction of the optical pickup base 32 from the extension line connecting the skew boss 48. The skew boss 48 and the fastening boss 50 is formed to form a triangle as a whole when viewed from above for a stable fastening structure.

A through hole 52 is formed in the center of the fastening boss 50 to penetrate the spindle holder part 46. At least one chamfer 54 is formed on an upper surface of the fastening boss 50 in contact with the motor plate 58 to be described below. The chamfer 54 is formed to be inclined in the direction in which the motor plate 58 is inclined during skew adjustment. The chamfer 54 is formed symmetrically with respect to the through hole 52. That is, the chamfer 54 is formed symmetrically in the direction toward the front end and the direction toward the rear end of the optical pickup base 32, respectively.

The chamfer 54 consists of one or more inclined surfaces with different inclinations. In addition, the chamfer 54 may be rounded without curved corners. In the chamfer 54 having a plurality of inclined surfaces or curved surfaces, positions of supporting the motor plate 58 are sequentially changed according to an angle at which the motor plate 58 is inclined. In other words, this means that the optimal support surface for relieving the stress concentrated in the fastening boss 50 is automatically selected according to the inclination of the motor plate 58.

In addition, a plurality of reinforcing ribs 56 are formed in the spindle holder part 46 to maintain self rigidity. The reinforcing rib 56 is formed to be connected to the outer circumferential surface of the skew boss 48 or the fastening boss 50.

On the other hand, a plate-shaped motor plate 58 is provided on the bottom of the spindle holder 46. The motor plate 58 is equipped with a spindle motor 60 that provides a driving force for rotating the disk. The turntable 62 is mounted to the rotating shaft of the spindle motor 60. When the spindle motor 60 is driven, the turntable 62 rotates with the seated disk.

The motor plate 58 is installed on the optical pickup base 32 by a fastener B. The fastener B is a screw thread is formed only at the end. Therefore, the fastener B is fastened to the optical pickup base 32 through the fastening boss 50 formed in the spindle holder 46 from the lower portion of the motor plate 58. The fastener B may be fastened to the motor plate 58 through the fastening boss 50 formed in the spindle holder 46 in the optical pickup base 32.

A skew spring S is seated on the skew boss 48 formed on the spindle holder 46. Both ends of the skew spring S are supported by the spindle holder 46 and the motor plate 58, respectively. Since the skew spring (S) is fitted to the outer circumferential surface of the skew screw (C), by adjusting the fastening degree of the skew screw (C) it is possible to adjust the height of the spindle motor 60 to be described below.

Hereinafter, the operation of the skew adjusting apparatus of the disk drive according to the present invention having the above configuration will be described in detail.

First, when the spindle motor 60 is mounted on the optical pickup base 32, the spindle holder part 46, which is a separate mold, is mounted on the bottom surface of the optical pickup base 32. The optical pickup base 32 is provided with guide shafts 38 and 38 'in parallel. Meanwhile, another skew adjusting device for adjusting the height of the guide shafts 38 and 38 'may be installed at one end of the guide shafts 38 and 38', thereby supporting the guide shafts 38 and 38 '. The skew of the optical pickup 40 to be adjusted can be adjusted.

Next, the spindle motor 60 is installed on the upper surface of the motor plate 58, and the motor plate 58 is coupled to the optical pickup base 32 by the fastener B. The skew screw 48 is coupled to the optical pickup base 32 through the skew spring S through the skew boss 48.

At this time, when the screw (C) is tightened or loosened for adjusting the skew, as shown in Figure 5, the motor on the basis of the front end of the motor plate 58 fixed by the fastener (B) The rear end of the plate 58 is raised or lowered.

As such, when the motor plate 58 has a predetermined inclination with respect to the spindle holder 46, the motor plate 58 is inclined in a state parallel to the upper surface of the fastening boss 50. do.

At this time, the front end of the motor plate 58 into which the fastener B is inserted is divided into a rising portion and a falling portion based on the upper surface of the fastening boss 50 during skew adjustment. If the chamfer 54 is not formed in the fastening boss 50, stress is concentrated on one end of the fastening boss 50, which is coupled to one side of the motor plate 58 which is lowered.

However, in the present embodiment, when the motor plate 58 is inclined to the surface adjacent to the fastening boss 50 due to skew adjustment, one bottom surface of the motor plate 58 into which the fastener B is inserted is It is supported by the chamfer 54 formed at the front end or the rear end of the fastening boss 50.

Therefore, stress concentration does not occur at the edge of the fastening boss 50 during skewing, thereby improving durability of the motor plate 58. In addition, since the motor plate 58 is supported by the chamfer 54, an error does not occur in the set distance between the optical pickup 40 and the disc due to the deformation of the fastening boss 50. As a result, the accuracy of the skew adjustment is increased. Is improved.

The rights of the present invention are not limited to the embodiments described above, but are defined by the claims, and those skilled in the art can make various modifications and adaptations within the scope of the claims. It is self-evident.

1 is a perspective view showing a main configuration of a disk drive according to the prior art.

FIG. 2 is an enlarged perspective view illustrating a main part of the disc drive in FIG. 1. FIG.

Figure 3 is a perspective view showing the configuration of a preferred embodiment of a disk drive according to the present invention.

Figure 4 is a perspective view showing the configuration of the spindle holder in the embodiment of the present invention.

Figure 5 is a side view showing the configuration of the fastening boss and the motor plate in the embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

32: optical pickup base 34: lifting base

36: optical pickup transfer window 38: guide shaft

40: optical pickup 42: slad motor

44: lead screw 46: spindle holder

48: skew boss 50: tightening boss

52: through hole 54: chamfer

56: reinforcement rib 58: motor plate

60: spindle motor 62: turntable

Claims (6)

An optical pickup base to which the optical pickup is movably installed; A spindle holder portion provided at one end of the optical pickup base and having a skew boss for inserting a skew screw for adjusting the skew on both sides; A motor plate mounted to the optical pickup base to support the spindle holder and provided with a spindle motor for rotating the disk; And a fastening boss provided on the spindle holder part to fasten the motor plate and having at least one chamfer formed on a surface in contact with the motor plate. The skew adjusting apparatus of claim 1, wherein the chamfer is formed to be inclined in a direction in which the motor plate is inclined during skewing. The skew adjusting apparatus of claim 1 or 2, wherein the fastening boss is provided to be spaced a predetermined distance away from an extension line connecting the skew boss to the front end of the optical pickup base. The skew adjusting apparatus of claim 3, wherein the chamfer is formed in a symmetrical pair with respect to the through hole formed in the fastening boss. 5. The skew adjusting apparatus of claim 4, wherein the chamfer is formed of one or more inclined surfaces having different inclinations. The skew adjusting apparatus of claim 4, wherein the chamfer is curved and rounded.

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