KR0137302B1 - Fricative drive actuator - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an actuator used to transfer an optical pickup for reading information stored in a storage medium in a compact disc player (CDP) to a focusing or tracking direction, and in particular, a lead flexible printed circuit (FPC). It relates to a friction drive actuator for supplying current to the focus coil and the tracking coil without using a. The friction drive actuator of the present invention attaches conductive metal films to the optical axis and the blade, and supplies current to the coil by contact between these metal films, thereby preventing performance degradation of the optical pickup caused by the failure or damage of the lead FPC. Can be. In addition, by simplifying the production process, it provides an effect that can reduce the process time.

Description

Friction driven actuator

1 is a perspective view showing an embodiment of a general shaft actuator,

2 is a view showing the structure of the optical axis in the friction drive actuator according to the present invention,

3 is a view showing an embodiment of a friction drive actuator according to the present invention.

* Explanation of symbols for the main parts of the drawings

10, 30: blade 11: objective lens

12: focus coil 13: tracking coil

14, 20: optical axis 15: magnet

16 magnetic circuit 17 lead FPC (Flexible Printed Circuit)

18 fixed plate 21 first metal film

22: second metal film 31: third metal film

32: fourth metal film W ₁ to W ₂ : wire

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical pick-up actuator used in optical devices such as CDP, LDP, and the like, and particularly to a focus coil and a tracking coil in an axial actuator. It relates to a friction drive actuator to improve the manner of supplying to prevent the performance degradation of the optical pickup.

The actuator is an optical system driving device used to transfer an optical pickup for reading information stored on a disc in a focusing direction or a tracking direction in an optical application such as a CDP or LDP.

1 is a perspective view showing an example of a general shaft actuator. In the apparatus of FIG. 1, the objective lens 11 is mounted on one side of the upper surface of the blade 10 and performs focusing and tracking adjustment by the movement of the blade 10. The focus coil 12 for driving the objective lens 11 in the focusing direction is wound on the blade 10, and the tracking coil 13 for driving the objective lens 11 in the tracking direction is the focus coil 12. It is attached to the side of the. At this time, the focus coil 12 and the tracking coil 13 are arranged to be orthogonal to each other. The lead coil 12 and the tracking coil 13 are connected to a lead flexible printed circuit (FPC) 18 for receiving a drive current from an external power source (not shown). The inner and outer magnetic circuits 16 are attached to the upper surface of the fixing plate 17 to effectively draw the magnetic flux generated by the magnet 15. The magnet 15 is attached to the inner wall surface of the magnetic circuit 16. The fixing plate 17 is also equipped with an optical axis 14 for supporting the blade 10 for driving.

In the axial actuation actuator of FIG. 1, the magnetic field formed in the magnet 15 acts perpendicular to the focus coil 12 and the tracking coil 13. When a constant current flows on a photo equipment such as a CDP set (not shown), a driving current for driving the actuator is supplied to the focus coil 12 and the tracking coil 13 through the lead FPC 18. The lead FPC 18 is made by printing a figure on an insulator such as a copper plate having warpage properties and inserting a lead wire into the printed portion.

It is fixed by soldering (Printed Circuit Board, PCB). When current flows through the focus coil 12 and the tracking coil 13, the focus coil 12 and the tracking coil 13 placed in the magnetic field generate an electromagnetic force to drive the blade. The blade 10 moves in the focusing direction and / or the tracking direction by the generated electromagnetic force to adjust the focus and tracking.

However, the conventional optical device actuator which supplies the current to the coil by using the lead FPC in this way has an operational problem depending on the state of the lead FPC. That is, since the actuator is very sensitive and moves quickly, if the lead FPC is bent or bent during operation, the driving state becomes poor, such as vibration, and thus the pickup performance is degraded. In addition, when the lead FPC is attached to the lead FPC, there is a problem in that the blade is not smoothly driven by the remaining flux around the blade.

Accordingly, an object of the present invention for solving such a problem is to apply a conductive metal film to the outer surface of the optical axis and the inner surface of the blade in the axial actuator, and to apply a current to the coil by the contact of the metal film in the same position of the optical axis and the blade By providing a supply, the actuator eliminates the lead FPC.

In order to achieve the above object, the friction drive actuator according to the present invention includes a fixed plate, a plurality of fixed coils for driving an objective lens in a desired direction, in an axial sliding actuator for transferring an objective lens in a desired direction on an optical storage medium, Magnetic field generation to generate an optical axis coated with metal films on the surface so as to supply a driving current to the fixed coil, a blade coated with conductive metal films on the inner wall surface to receive the optical axis and contact the metal film on the optical axis, and a magnetic field for driving the blades. Means;

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

FIG. 2A is a front view of the improved optical axis 20 and FIG. 2B is a plan view of the optical axis 20 in the friction drive actuator according to one embodiment of the invention. As shown, the first metal film 21 for applying current to the focus coil 12 is attached to the upper end of the outer surface of the optical axis 20 improved by the present invention, the lower end with the tracking coil 13 A second metal film 22 for applying a current is attached. The first metal film 21 and the second metal film 22 are respectively connected to an external power source (not shown) through the inside of the optical axis 20. 3 is a cross-sectional view of the friction drive actuator according to an embodiment of the present invention, Figure 3 is a plan view of the friction drive actuator according to the present invention. In the apparatus of FIG. 3, a third metal film for contacting the first metal film 21 described above and applying current to the focus coil 12 is formed on the upper end of the inner surface of the blade 30 to which the optical axis 20 is fitted. 31) is attached, and a fourth metal film 32 for attaching a current to the tracking coil 13 in contact with the second metal film 22 described above is attached to the lower end. The third metal film 31 and the fourth metal film 32 are connected to the focus coil 12 and the tracking coil 13 through the conductive wires W ₁ and W ₂ .

The operation of the friction drive actuator according to the present invention configured as described above will be described in detail.

In the friction drive actuator shown in FIG. 3, when the blade 30 is fitted to the optical axis 20, the first metal film 21 on the optical axis 20 contacts the third metal film 31 on the blade 30. The second metal film 22 is in contact with the fourth metal film 32. First, when driving the objective lens 11 in the focusing direction, a focus signal is applied to the first metal film 21 from an external power source (not shown). When the focus signal is applied to the first metal film 21, the third metal film 31, which is in contact with the first metal film 21, detects it and focuses the detected focus signal through the conductive wire W ₁ . Applied to the coil 12. When the focus signal is applied, electromagnetic force is generated by the interaction between the current flowing through the focus coil 12 and the magnetic field generated from the magnet 15. At this time, the generated electromagnetic force moves the blade 30 in the focusing direction so that the objective lens 11 attached to the upper surface of the blade 30 can focus on the optical disk. On the other hand, when driving the objective lens 11 in the tracking direction, the tracking signal is applied to the second metal film 22 from an external power source (not shown). When the tracking signal is applied to the second metal film 22, the fourth metal film 32 in contact with the second metal film 22 detects the tracking signal and tracks the detected tracking signal through the conductive wire W ₂ . It is applied to the coil 13. When the tracking signal is applied, an electromagnetic force is generated by the interaction between the current flowing through the tracking coil 13 and the magnetic field generated from the magnet 15. At this time, the generated electromagnetic force moves the blade 30 in the tracking direction so that the objective lens 11 attached to the upper surface of the blade 30 can move in the radial direction on the optical disk.

As described above, the friction drive actuator according to the present invention is configured to apply conductive metal films to the optical axis and the blade in the shaft contact actuator, and to drive by applying a driving current to the focus coil and the tracking coil by friction of the metal films at the same position. do.

Therefore, since the friction drive actuator according to the present invention does not use the lead FPC in supplying power for driving the optical pickup actuator, the performance of the optical pickup caused by a poor soldering or bending of the lead FPC is prevented. Can be. In addition, it is possible to drive simply by inserting the blade in the optical axis, so that the operation time and the effect of reducing the process time in the production of the actuator.

Claims (6)

In the axial sliding actuator for transferring the objective lens in the desired direction on the optical storage medium, Fixing plate; A plurality of fixed coils for driving the objective lens in a desired direction; An optical axis coated with metal films on a surface thereof to supply a driving current to the fixed coil; A blade accommodating the optical axis and coated conductive metal films on an inner wall thereof so as to contact the metal film of the optical axis; And And a magnetic field generating means for generating magnetic fields for driving said blade. The focusing coil of claim 1, wherein the fixed coil comprises: a focus coil wound around the blade to drive the objective lens in a focusing direction of an optical storage medium; And And a tracking coil attached to a side of the focus coil to drive the objective lens in a tracking direction of an optical storage medium. The optical system of claim 2, wherein the optical axis comprises: a first metal film for supplying current to the focus coil; And And a second metal film on the outer surface for supplying current to the tracking coil. The optical device of claim 3, wherein the blade comprises: a third metal film contacting the first metal film of the optical axis to supply a driving current to the focus coil; And And a fourth metal film on an inner surface of the inner surface of the fourth metal film in contact with the second metal film of the optical axis to supply a driving current to the tracking coil. 5. The friction drive actuator according to claim 4, wherein a conductive wire for supplying current to the focus coil and the tracking coil is connected to the third metal film and the fourth metal film. According to claim 1, wherein the magnetic field generating means is attached to both side ends of the fixing plate magnet for generating a magnetic field; And Friction drive actuator, characterized in that consisting of a magnetic circuit for effectively drawing the magnetic flux generated in the magnet.