KR100288981B1 - Damping Structure of Optical Pickup Actuator - Google Patents

Abstract

The present invention is intended to improve the recording and reproduction sensitivity of a disc by quickly stabilizing the lens holder by damping negative resonance such as torsion generated during driving of the lens holder with a magnet that turns off the lens holder.

The present invention is the annular groove 41 formed on the bottom surface of the lens holder 40, the magnetic ring 50 is inserted into the annular groove 41, the yoke 10 of the yoke 10 in close proximity to the magnetic ring 50 A damping structure of an optical pickup actuator including an annular core 20 protruding from an upper surface thereof and a coil 21 wound around a circumference of the annular core 20. A magnetic flux is generated in the annular core 20 to generate a lens holder 40. By acting as a force to constrain the lens holder 40 to a certain point by dragging the magnetic ring 50 fixed to the), the lens holder 40 is structurally damped and quickly stabilized, thereby improving the disc recording and reproduction sensitivity of the optical system. It is effective.

Description

Damping Structure of Optical Pickup Actuator

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a damping structure of an optical pickup actuator. In particular, by damping negative resonance such as torsion generated during driving of a lens holder with a magnet that turns off the lens holder, the lens holder is quickly stabilized to improve the recording and reproduction sensitivity of the disc. The damping structure of the optical pickup actuator for making.

In general, the optical pickup actuator moves the objective lens in the radial direction when the error of the optical axis or the radial direction occurs at the focal point of the laser beam formed on the recording pit of the disc through the objective lens in the hologram element. It is used as a driving means for correcting the error of the focus of the laser beam by finding the, and adjusting the size of the focus by moving in the focus direction.

A wire driving actuator generally used among these optical pickup actuators is shown in FIG. 1.

The actuator has a shape in which the lens holder 140 fixing the objective lens 142 is installed to the yoke 110 with a suspension wire 130 so as to be movable. The objective lens 142 is located at the center of the lens holder 140. ), And a focusing coil 144 was wound around the lens holder 140, and then a tracking coil 146 wound in a rectangular shape on the front was attached thereto. The coil PC 148 was fixed to both sides of the lens holder 140 to connect the tracking coil 146 and the focusing coil 144.

In addition, a pair of symmetrical outer bent pieces 114 are formed on the yoke 110, and a magnet 118 for generating an electromagnetic force by applying magnetic flux to the tracking coil 146 and the focusing coil 144 is bonded and fixed. In addition, a pair of inner bent pieces 112 which are symmetrical to the inside of the outer bent piece 114 is bent upwardly in the yoke 110 to induce the flow of the magnetic flux of the magnet 118. Therefore, a magnetic closure circuit in which the magnetic flux of the magnet 118 passes strongly through the tracking coil 146 and the focusing coil 144 horizontally, passes through the planes of the inner bent pieces 112 and the yoke 110, and enters the magnet 118 again. Formed.

In addition, the support 116 is formed at one edge of the yoke 110 to fix the suspension PCB 122 with the screw 124, and one end of the suspension wire 130 is bonded to the lens holder 140 with the coil PCB ( 148) and the other end to a suspension PCB 122. Therefore, while the lens holder 140 is lifted by the suspension wire 130, a current applied from the signal processor to the suspension PCB 122 is applied to the tracking coil 146 and the focusing coil 144 through the suspension wire 130. To be delivered.

Meanwhile, as a damping structure for attenuating the negative resonance of the suspension wire 130 of the actuator, conventionally, two gel holders 120 are integrally connected between the suspension PCB 122 and the support 116 so that the center is connected together. Fixed. Then, two suspension wires 130 pass through the inside of each gel holder 120, and the viscous silicon gel 121 is injected into the gel holder 120, thereby providing suspension wire 130. Negative resonance of the silicon gel 121 was rapidly reduced by the viscous force of the.

However, in the conventional damping structure, the gel holder 120 is fixed together to the suspension PCB 148 for fixing the suspension wire 130, and the silicon gel 121 stored in the gel holder 120 is suspended in the suspension PCB 148. The damping of the suspension wire 130 in the vicinity of. However, since the flow of the suspension wire 130 is very fine on the suspension PCB 122 side, which is a fixed end, the effect of the silicon gel 121 damping the minute portion of the flow is very small.

Therefore, in the conventional damping structure, since the sub resonance, such as the torsion phenomenon occurring in the tracking operation and the focusing operation of the lens holder 140, cannot be damped efficiently, the disc recording of the optical system is performed by the sub resonance of the lens holder 140. There was a problem of low reproduction sensitivity.

SUMMARY OF THE INVENTION The present invention has been made to solve the conventional problems, and an object of the present invention is to dampen a negative resonance such as torsion generated during driving of a lens holder with a magnet which pulls out the lens holder, thereby quickly stabilizing the lens holder, This is to improve recording and reproduction sensitivity.

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

2 is a perspective view of an optical pickup actuator according to an embodiment of the present invention.

3 is a side view of the coupling state of the optical pickup actuator shown in FIG.

<Explanation of symbols for main parts of drawing>

10: yoke 12: inner bending piece

14: outer bending piece 16: support

18: magnet 20: annular core

21: coil 22: suspension PCB

24: screw 30: suspension wire

40: lens holder 41: annular groove

42: objective 44: focusing coil

46: tracking coil 48: coil PC

50: magnetic ring

The present invention for achieving the above object is a lens holder fixed to the objective lens and the coil PC on both sides, a plurality of suspension wires one end is connected to the coil PC on both sides, and the other end of the suspension wire An optical pickup actuator having a yoke having a suspension PC ratio connected thereto and a support for fixing the suspension PC ratio; An annular groove formed on a bottom surface of the lens holder; A magnetic ring inserted into the annular groove; An annular core protruding from the upper surface of the yoke to be proximate to the magnetic ring; And a coil wound around the circumference of the annular core.

In such a damping structure, when a current is applied to the coil wound on the annular core, magnetic flux is generated in the annular core to attract the magnetic ring fixed to the lens holder, thereby acting as a force to restrain the lens holder at a predetermined point. It will damp the negative resonance. This damping is a structural damping forcibly preventing the negative resonance of the lens holder, and the negative resonance such as torsion generated from the driving of the lens holder is rapidly attenuated.

Therefore, by effectively damping the negative resonance of the lens holder, it is possible to improve the disc recording and reproduction sensitivity of the optical system.

Hereinafter, preferred embodiments of the present invention will be described to facilitate implementation of the present invention.

The configuration of the optical pickup actuator according to the present embodiment will be described with reference to FIG. The present embodiment is applied to a wire drive type optical pickup actuator in which the lens holder 40 on which the objective lens 42 is fixed is installed to be movable to the yoke 110 by the suspension wire 30.

The focusing coil 44 is wound around the lens holder 40, and the tracking coil 46 wound in a rectangular shape is bonded thereto. The coil PC 48 is fixed to both sides of the lens holder 40, and the tracking coil 46 and the focusing coil 44 are connected to the coil PC 48.

A pair of symmetrical outer bent pieces 14 is formed on the yoke 10, and a magnet for generating an electromagnetic force by applying magnetic flux to the tracking coil 46 and the focusing coil 44 to the outer bent pieces 14. (18) is bonded and fixed. At the same time, the inner bending piece 12 is bent upwardly in the yoke 10 inside each of the outer bending pieces 14 to induce the flow of the magnetic flux of the magnet 18. Therefore, the magnetic closing circuit of the magnetic flux of the magnet 18 passes strongly through the tracking coil 46 and the focusing coil 44 horizontally, passes through the planes of the inner bent pieces 12 and the yoke 10 and enters the magnet 18 again. Is formed.

The support 16 is formed at one edge of the yoke 10, and the suspension PCB 22 is fixed to the rear of the support 6 with a screw 24. Subsequently, two ends are connected to both coil PCs 48 provided with the four suspension wires 36 and adhered to the lens holder 40, and the other end is connected to the suspension PCS 22. As shown in FIG.

Accordingly, the lens holder 40 is floated by the suspension wire 36, and a current applied from the signal processing unit to the suspension PCB 22 is transferred to the tracking coil 46 and the focusing coil 44 through the suspension wire 30. It becomes transferable.

Meanwhile, in order to damp the lens holder 40, an annular recess 41 is formed on the bottom surface of the lens holder 40, and the magnetic ring 50 is inserted into the annular recess 41 and bonded to fix the annular recess 41. Then, the annular core 20 protrudes from the upper surface of the yoke 10 to correspond to the magnetic ring 50, and the coil 21 is wound on the circumference of the annular core 20.

Hereinafter, the operation of the damping structure having the above configuration will be described.

The external driving voltage input through the suspension PCB 22 is transmitted to the coil PC 48 via the suspension wire 30, and the signal is applied to the tracking coil 46 and the focusing coil 46 to provide a lens holder ( Drive 40).

As a result, the tracking error and focusing error caused by the focus of the laser beam formed on the recording pit of the disc in the objective lens 42 fixed to the lens holder 40 is corrected.

The operation of the lens holder 40 consists of an operation in the optical axis direction for adjusting the focus of the laser beam, and an operation in the radial direction for correcting the tracking error. Here, since the operation in the optical axis direction and the operation in the radial direction are performed at the same time, a torque is generated, and a negative resonance phenomenon such as an unintended twist occurs in the lens holder 40.

At this time, when a current is applied to the coil 21 wound on the annular core 20 formed in the yoke 10, magnetic flux is generated in the annular core 20 to fix the magnetic ring 50 fixed to the lens holder 40. Since it is dragged, it acts as a force to restrain the lens holder 40 at a certain point, thereby damping the negative resonance generated in the lens holder 40.

This damping is a structural damping forcibly inhibiting the negative resonance of the lens holder 40, and generates a much stronger damping force than the damping which only damps the vibration of the suspension wire 30. Therefore, the negative resonance such as torsion generated from the driving of the lens holder 40 is rapidly attenuated.

As the negative resonance of the lens holder 40 is rapidly attenuated and stabilized in this manner, the objective lens 42 stably forms the focus of the laser beam on the recording pit of the disc.

As described in the above embodiment, the present invention provides an annular groove 41 formed on the bottom surface of the lens holder 40, a magnetic ring 50 inserted into and attached to the annular groove 41, and a magnetic ring 50. A damping structure of an optical pickup actuator including an annular core 20 protrudingly formed on an upper surface of the yoke 10 and a coil 21 wound on a circumference of the annular core 20 in a close correspondence. As magnetic flux is generated and the magnetic ring 50 fixed to the lens holder 40 is pulled to act as a force to restrain the lens holder 40 at a predetermined point, the lens holder 40 is structurally damped and quickly stabilized. There is an effect of improving the disc recording / reproducing sensitivity of the optical system.

Claims (1)

The lens holder 40 having the objective lens 42 fixed thereto and the coil PC 48 fixed to both sides, a plurality of suspension wires 30 having one end connected to the coil PC 48 of the both sides, and the suspension wire An optical pickup actuator provided with a suspension PCB 22 to which the other end of the 30 is connected and a yoke 10 having a support 16 for fixing the suspension PCB 22; An annular recess 41 formed in a bottom surface of the lens holder 40; A magnetic ring 50 inserted into and attached to the annular groove 41; An annular core 20 protruding from the upper surface of the yoke 10 so as to be proximate to the magnetic ring 50; And Damping structure of the optical pickup actuator comprising a; coil 21 wound on the circumference of the annular core (20).