KR19980057959A - Lens holder position adjustment structure of optical pickup device - Google Patents

Abstract

According to the present invention, by adjusting the distance between the tracking coil and the focusing coil and the magnet bonded to both sides of the lens holder in the same manner, the lens holder of the optical pickup apparatus which generates the same electromagnetic force on both sides of the lens holder to operate the lens holder uniformly. A position adjustment structure.

The present invention forms a screw hole 53 and a through hole 57 in the second yoke 52 formed in the yoke plate 50 and the suspension PCB 56 fixed thereto, and the yoke plate 50 is seated. A guide 82 having a through hole 84 corresponding to the screw hole 53 of the second yoke 52 is formed at one side of the pickup base 80, and the through hole 84 of the guide 82 is formed. By passing through the fastening screw 92 of the compression spring 92 is fastened to the through hole 57 of the suspension PCB 56 and the screw hole 53 of the second yoke 52.

According to the present invention, since the electromagnetic force generated by the tracking coil 74 and the focusing coil 72 bonded to the left and right sides of the lens holder 70 are the same, the lens holder 70 is uniformly moved in the tracking direction and the optical axis direction. In the objective lens 76, it is possible to accurately focus on the disk.

Description

Lens holder position adjustment structure of optical pickup device

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a structure for adjusting the position of a lens holder of an optical pickup apparatus, and more particularly, by adjusting a position of a second yoke of a yoke plate by forming a guide on a pickup base and engaging an adjustment screw fitted with a compression spring. And a lens holder position adjusting structure of the optical pickup device for adjusting the distance between the lens holder provided on the second yoke and both magnets by the suspension wire.

In general, an optical pickup device is a device installed in a CD player for irradiating laser light to the disc and receiving the light reflected from the disc to reproduce the recording contents of the disc. And an objective lens for focusing the laser light emitted from the hologram element on the disk surface.

When an error occurs in the focus of the laser light formed on the disk in the objective lens of the optical pickup device, the objective lens is moved in the optical axis and tracking direction to correct the error. An actuator for driving the lens holder to which the objective lens is fixed is As shown in FIG. 1, the lens holder 20 to which the objective lens 32 is fixed is provided so as to be movable to the yoke plate 10 with a plurality of suspension wires 40.

The objective lens 32 is attached to the center of the lens holder 20, the focusing coil 34 for winding the objective lens 32 in the optical axis direction is wound around the side of the lens holder 20, A pair of tracking coils 36 are attached to the two focusing coils 34 of the lens holder 20 to move the objective lens 32 in the radial direction.

In addition, the coil PCs 38 to which the tracking coils 36 and the focusing coils 34 are connected are provided at the opposite sides of the lens holder 20, and the coils 38 are provided with the focusing coils 34 and the tracking coils. A suspension wire 40 is attached to the input / output signal of the servo system, to support the oscillation of the lens holder 20, and to attenuate the vibration when an impact from the outside is transmitted.

On the upper side of the yoke plate 10, a pair of inner yokes 12 are formed to be fluidly fitted to the focusing coil wound around the lens holder 20 to form a magnetic closure circuit. The outer side of the inner yoke 12 is formed. And a pair of outer yokes 14 to which the magnets 18 are attached, and a second yoke for fixing the suspension PC 46 to which the suspension wires 40 are connected to the outer side of the one outer yoke 14. 16 is formed.

In addition, the second yoke 16 is provided with a gel holder 42 into which a viscous damping gel 44 is injected, and the suspension wire 40 adhered to the coil PC 38 of the lens holder 20. Connected to the suspension PCB 46 via the gel holder 42, the objective lens 32 adhered to the lens holder 20 is focused by the focusing coil 34 and the tracking coil 36 on the recording pit on the disc. When vibrating while moving to form, the suspension wire 40 supporting the lens holder 20 is reduced by the damping gel 44 so that the objective lens 32 can stably focus on the disk. have.

Meanwhile, as shown in FIG. 2, the focusing coil 34 and the tracking coil 36 wound and bonded to both sides of the lens holder 20 are spaced apart from the magnet 18 as shown in FIG. 2. It is floated by the suspension wire 40 while maintaining. Therefore, the magnetic flux from the magnet 18 passes through the tracking coil 36 and the focusing coil 34 in turn, passes through the inner yoke 12, passes through the bottom of the yoke plate 10, and enters the magnet 18 again. Is formed.

Accordingly, the tracking coil 36 generates an electromagnetic force for driving the lens holder 20 in the tracking direction under the influence of the magnetic flux of the magnet 18 when the current is applied, and the magnet (when the current is applied in the focusing coil 34). Under the influence of the magnetic flux of 18), an electromagnetic force for moving the lens holder 20 to the optical axis is generated.

If the second yoke 16 of the yoke plate is deformed, the position of the suspension PCB 46 fixed to the second yoke 16 is also deformed together, thus the suspension wire connected to the suspension PCB 46. The position of the lens holder 20 injured by the 40 is moved so that the focusing coil 34 and the tracking coil 36 wound on the side of the lens holder 20 are moved closer or farther toward one magnet 18. do. In addition, even when the length of the suspension wire 40 is not balanced when the suspension wire 40 is connected to the lens holder 20, the lens holder 20 moves away from or toward the magnet 18 on one side.

Therefore, the distance d ₁ of the one tracking coil 36 and the focusing coil 34 and the magnet 18 bonded to the lens holder 20 as described above, the other tracking coil 36 and the focusing coil 34 and the magnet If the interval d ₂ of the 18 is different, the magnitude of the electromagnetic force generated at both sides of the lens holder 20 when the current is applied to the tracking coil 36 and the focusing coil 34 is different, the lens holder 20 ) Is inclined to move in the tracking and focusing direction, and thus the objective lens 32 does not accurately form the focus of the laser light on the disk.

SUMMARY OF THE INVENTION The present invention has been made to solve the conventional problems, and an object of the present invention is to equally adjust the distance between the tracking coil and the focusing coil and the magnet bonded to both sides of the lens holder, thereby applying the same electromagnetic force to both sides of the lens holder. It is for generating the lens holder to operate uniformly.

In order to achieve the above object, the present invention provides a screw hole and a through hole in the second yoke formed on the yoke plate of the optical pickup device and the suspension PCB fixed thereto, and on one side of the pickup base on which the yoke plate is seated An optical pickup apparatus having a guide having a through hole corresponding to the screw hole of the second yoke, and passing through the through hole of the guide and fastening an adjustment screw fitted with a compression spring to the through hole of the suspension PCB and the screw hole of the second yoke. It can be achieved by providing a lens holder position adjusting structure of.

1 is a perspective view showing a general optical pickup actuator.

2 is a cross-sectional view showing a general optical pickup actuator.

3 is a cross-sectional view showing a lens holder position adjusting structure of the optical pickup device according to the present invention;

Figure 4 is a perspective view showing a lens holder position adjustment structure of the optical pickup device according to the present invention.

〈Description of the symbols for the main parts of the drawings〉

50: yoke plate 52: second yoke

53: screw hole 54: gel holder

55, 57: through hole 58: suspension wire

60: magnet 70: lens holder

72: focusing coil 74: tracking coil

80: pickup base 82: guide

84: through hole 90 adjustment screw

92: compression spring

Hereinafter, a preferred embodiment of the lens holder position adjusting structure of the actuator according to the present invention will be described in detail with reference to the accompanying drawings.

First, as shown in FIG. 3, the gel holder in which the damping gel for damping the suspension wire 58 is injected into the rear surface of the second yoke 52 formed on the yoke plate 50 of the optical pickup device is illustrated in FIG. 3. A 54 is fixed, and a suspension PC 56 to which the suspension wire 58 is connected is fixed to the back of the gel holder 54. A through hole is provided at the upper center of the suspension PC 56 and the gel holder 54. 55 and 57 are formed, and the second yoke 52 is formed with a screw hole 53 corresponding to the through holes 55 and 57.

The pickup base 80 on which the yoke plate 50 is seated forms a guide 82 to be positioned outside the second yoke 52 of the yoke plate 50, and the second yoke 52 is attached to the guide 82. The through hole 84 corresponding to the screw hole 53 is formed.

Then, the second yoke passes through the through hole 55 of the guide 82 and passes through the adjustment screw 90 with the compression spring 92 inserted therethrough through the suspension PC 56 and the through hole 55 of the gel holder 54. To the threaded hole 53 of 52.

The compression spring 92 uses a product having a strong elasticity enough to elastically push the second yoke 52.

The operation of the lens holder position adjusting structure having the above configuration will be described with reference to Figs.

Suspension fixed to the second yoke 52 of the yoke plate 50 by a compression spring 92 fitted into the adjustment screw 90 inserted into the through hole 55 of the guide 82 formed in the pickup base 80. The PC 56 is subjected to elasticity and is pushed to the right side of FIG. 3. The tip of the adjusting screw 90 is fastened to the second yoke 52 to position the position of the second yoke 52 to the guide 82. By fixing against, the suspension PCB 56 and the second yoke 52 are fixed to the pickup base 80.

In this state, the tracking coil 74 and the focusing coil 72 bonded to the left side of the lens holder 70 and the distance d ₁ between the magnet 60 on the left side of the tracking holder adhered to the right side of the lens holder 70. If greater than the distance d ₂ between the coil 74 and the focusing coil 72 and the right magnet 60, the adjustment screw 90 is rotated to tighten the clamping force of the yoke plate 50 to the second yoke 52. The suspension yoke 52 is slightly tilted to the right by pushing the suspension PC 56 by the elasticity of the compression spring 92 to thereby release the suspension wire 58 and the lens holder 70 connected thereto to the right. Tracking coil 74 bonded to the left side of the lens holder 70 and the distance d ₁ between the focusing coil 72 and the left magnet 60 and the tracking coil bonded to the right side of the lens holder 70. 74 and the distance d ₂ between the focusing coil 72 and the right magnet 60 are adjusted to be equal.

In addition, the tracking coil 74 bonded to the left side of the lens holder 70 and the tracking coil 74 adhered to the right side of the lens holder 70 than the distance d ₁ between the focusing coil 72 and the left magnet 60. If the distance d ₂ between the focusing coil 72 and the right magnet 60 is large, the adjusting screw 90 is rotated in reverse to increase the tightening force of the yoke plate 50 to the second yoke 52. By pulling the suspension PCB 56 with the guide 82 to finely tilt the second yoke 52 to the right, the suspension wire 58 and the lens holder 70 connected thereto are finely moved to the right. The tracking coil 74 bonded to the left side of the holder 70 and the distance d ₁ between the focusing coil 72 and the magnet 60 on the left side and the tracking coil 74 bonded to the right side of the lens holder 70. And the distance d ₂ between the focusing coil 72 and the right magnet 60 are equal.

Therefore, the electromagnetic force generated by the tracking coil 74 and the focusing coil 72 adhered to the left side of the lens holder 70 and the tracking coil 74 and the focusing coil 72 adhered to the right side of the lens holder 70. Since the magnitude of the electromagnetic force generated by the same is the lens holder 70 is operated in a balanced posture in the tracking direction and the optical axis direction.

As described in the above embodiments, the present invention forms the guide 82 on the pickup base 80 and fixes the second yoke 52 of the yoke plate 50 by fixing the adjusting screw 90 to the lens holder. As a structure for adjusting the position of the 70, the lens holder 70 is uniformly adjusted by equally adjusting the electromagnetic force generated by the tracking coil 74 and the focusing coil 72 bonded to the left and right sides of the lens holder 70. By moving in the tracking direction and the optical axis direction, the focus can be accurately formed on the disk in the objective lens 76.

Claims (2)

In the structure for adjusting the position of the lens holder 70 floated by the suspension wire 58 connected to the suspension PCB 56 fixed to the second yoke 52 formed on the yoke plate 50 of the optical pickup device , The second yoke 52 formed on the yoke plate 50 and the suspension PCS 56 fixed thereto form a screw hole 53 and a through hole 57, respectively, and the pick-up of the yoke plate 50 is seated. A guide 82 having a through hole 84 corresponding to the screw hole 53 of the second yoke 52 is formed at one side of the base 80, and passes through the through hole 84 of the guide 82. And an adjusting screw 90 having a compression spring 92 fastened to the through hole 57 of the suspension PCB 56 and the screw hole 53 of the second yoke 52. Holder positioning structure. The gel holder (54) is fixed between the second yoke (52) of the yoke plate (50) and the suspension PCB (56), and the gel holder (54) of the second yoke (52). Lens holder position adjustment structure of the optical pickup device, characterized in that the through-hole 55 corresponding to the screw hole (53) is formed.