KR200171090Y1 - Piezoelectric actuator for optical pick-up device - Google Patents

Abstract

The present invention relates to an objective lens driving apparatus of an optical pickup, and more particularly, by applying a driving method having a sufficient driving force and a frequency response band, it is possible to advantageously cope with high-speed reproduction and recording.

The objective lens driving device of the present invention includes the objective lens holder 26 on which the objective lens is placed, the frame 24 positioned on the opposite side of the holder, and the holder for driving the objective lens 26 in the tracking / focusing direction. And a plurality of plate-shaped piezos 27 and 28 cross-fixed perpendicularly to each other between the frame and the frame.

Accordingly, high-speed driving of the objective lens required for increasing the speed of reproduction and recording is realized, and stability and reliability of the reproduction and recording operations are improved.

Description

Objective pick-up device for optical pickup {Piezoelectric Actuator for optical Pick-up Device}

The present invention relates to an objective lens driving apparatus of an optical pickup, and more particularly, by applying a driving method having sufficient driving force and frequency response band, it is possible to advantageously cope with high-speed reproduction and recording.

In general, an optical recording / reproducing apparatus using an optical recording medium (optical disk) such as an LDP (Laser Disk Player) or a CDP (Compact Disk Player) scans a beam of light such as a laser onto a disk surface and detects the light beam reflected from the disk. Optical pickup unit is installed. The optical pickup unit scans the light beam through the objective lens to the disk surface and reads the beam reflected therefrom as a binary signal. In order for the optical pickup unit to correctly read the signal, a certain distance, i.e., the focus, between the objective lens to which the light beam is scanned and the disk must be accurately focused, while the scanned light beam must follow the track formed on the disk precisely. It is possible.

The focusing of the objective lens according to the operation of driving the objective lens is called focusing, and the movement of the objective lens along the disc track is called tracking. Therefore, in the optical pickup unit, focusing is performed while driving the objective lens. There is an objective lens driving device for performing a tracking operation.

1 shows a typical wire spring-supported two-dimensional optical pickup actuator. The main part is a base (1) on which a magnet (2) and a yoke (3) are formed to form a magnetic field, a holder (4) fixed to the base (1), and one end is fixed to the holder (4) to be connected to a power source. A plurality of wires 5, which are coupled to the other end of the wires 5, are supported in a horizontal / vertically movable manner and wound around a coil holder 7 and a coil holder 7 on which an objective lens 6 is placed on one side of the magnet. (2) and focusing coil (8) and tracking coil (9) for generating electromagnetic force in interaction with the magnetic field formed by yoke (3), focusing coil (8) and tracking coil (9) through current (5) Is provided with a substrate 10 for delivery.

Therefore, the objective lens 6 and the focusing coil 8 / tracking coil 9 attached to the coil holder 7 are supported by several wires 5, and a magnet 2 at the lower part of the yoke 3 is supported. As shown in FIG. 2, the focusing coil 8 and the tracking coil 9 form a magnetic field and a magnetic circuit generated by the magnet 2, and according to the left-hand law of flaming, focusing direction and tracking are performed. Drive the objective lens 6 in the vertical direction. The magnitude of the force is determined in proportion to the relationship between the magnetic flux density of the magnet, the effective length of the coil, the number of turns, and the strength of the current.

The range in which the objective lens 6 is driven in the focusing direction is ± 1 to 2 mm, and the tracking direction is about ± 0.3 to 0.5 mm.

When the CD is reproduced with such a driving range, it is designed to follow ± 1 μm in the focusing direction and ± 0.1 μm in the tracking direction.

However, as the speed of reproduction and recording increases, in particular, in order to reproduce up to 40 times the speed, it is required to drive the objective lens 6 faster. Furthermore, it is necessary to drive in the tracking direction while maintaining 10 times the accuracy of focusing.

However, in the same manner as the wire spring-supported two-dimensional actuator (objective driving device), it is difficult and limited to drive the objective lens quickly and properly in the focusing / tracking direction.

It is also driven by coils that are only in the magnetic field, which leads to low efficiency, which is not more than about 50% numerically.

The spring-supported two-dimensional actuator is structurally integrated with a tracking / focusing drive unit, so that interference and crosstalk between each other occur, so that the separation of the drive is not complete. This generates a series of unnecessary vibration modes, which degrades the stability of the playback and recording operations.

Accordingly, an object of the present invention is to realize a high speed driving of the optical pickup actuator objective required for increasing the speed of reproduction and recording.

Another object of the present invention is to provide an optical pickup actuator that has a stable frequency response while maintaining a sufficient driving force of the objective lens.

The optical pickup objective lens driving apparatus for achieving the object of the present invention,

(1) an objective lens holder on which an objective lens is placed;

(2) a frame located on the opposite side of the holder and connected to the holder by a wire;

(3) several plate-shaped piezos which are vertically cross fixed to each other between the holder and the frame for driving the objective lens in the tracking / focusing direction,

(4) The piezo is characterized in that it is composed of a fixing member for vertically connecting the reference surface by dividing the tracking / focusing piezo.

Optionally, the piezo is a plate-shaped tracking piezo having a thin thickness, a narrow width relative to a length, and a vertical direction in the thickness direction;

Characterized in that it comprises a focusing piezo having a shape corresponding to the tracking piezo and horizontally in the thickness direction.

Optionally, the focusing piezo tip is connected to the objective lens holder.

1 is a conventional wire-supported two-dimensional actuator

FIG. 2 is a diagram illustrating the focusing actuator structure of FIG. 1. FIG.

3 is a view showing a configuration of an optical pickup objective lens driving apparatus according to the present invention

4 is a view showing another embodiment of FIG.

5 is a cross-sectional view of the piezo for explaining the driving principle according to the present invention

6 is a displacement diagram of FIG.

* Description of the symbols for the main parts of the drawings *

21: tracking piezo 22: focusing piezo

23: fixing member 24: frame

25: objective lens holder 26; objective lens

27.28: ceramic layer 29: intermediate core material

When the piezo is used as the driving source in the optical pickup objective driving, the objective lens can be driven efficiently and quickly in the desired focusing direction and tracking direction with respect to the information string recorded in the pit form on the optical disk.

Hereinafter, an optical pickup objective driving device according to an embodiment of the present invention will be described with reference to the drawings.

Figure 3 is a structural example of the present invention to show an actuator model of another method modified to a wire spring-supported two-dimensional actuator model. 4 is a model of another embodiment according to the present invention. 5 is for explaining the driving principle according to the present invention shows the driving of the tracking direction.

Referring to FIG. 3, the present invention has a prepared piezo having a thin thickness in the tracking direction and a narrow width compared to the length, and is arranged in the tracking piezo 21 with the thickness direction perpendicular to the tracking direction. The prepared piezo having the same to similar shape is arranged in the thickness direction horizontally and applied to the focusing piezo 22.

The two piezos, which are classified as tracking / focusing piezos (21) and (22), have a holding member (23) between them.

The fixing member 23 is formed of a plate shape having a '+' shape or a concave-convex shape corresponding to a surface on which the tracking / focusing piezos 21 and 22 are in contact with each other.

At the tip of the focusing piezo 22, which is one of the tracking / focusing piezos 21 and 22 disposed between the frame 24 and the holder 25, an objective lens holder 25 for fixing the objective lens 26 is provided. Fixed or vice versa tracking piezo 21 is fixed to frame 24. Of course, there is a possibility that the arrangement position is reversed with respect to the thickness and width in the form as shown in FIG.

The fixing member 23 is not necessarily on the tangential surface where the tracking / focusing piezos 21 and 22 meet. The fixing member 23 provides the fixing force with respect to the two planar piezos intersecting with each other, but there is no reason to install the fixing member 23 separately if the supporting member can give the supporting force even with the application of another supporter, for example, a more stable adhesive. .

The tracking / focusing piezos 21 and 22 existing between the objective lens holder 25 and the frame 24 give a potential difference on both sides to repeat expansion and contraction to generate displacement from a certain reference position to a certain range. To perform the operation.

5 shows a more detailed driving principle thereof.

Tracking / Focusing Piezo (21) (22) In view of the fact that the piezo has a multi-layered structure consisting of an intermediate core and the outer both sides of ceramic material without distinction, giving a potential to both sides of the piezo expands one side and shrinks the other side. A range of displacement is generated from the position as shown in FIG. 6. This displacement eventually appears as the physical force that moves the objective lens.

That is, when the ceramic layer 27, 28 made of a ceramic material on the upper and lower surfaces as shown in Figure 5 and the core member 29, which is an intermediate core material, is placed in the middle, the deformation does not occur when there is no potential difference on the upper and lower surfaces. When the potential difference occurs, one side expands and the other side contracts to obtain a driving force through a range of displacement from the reference position. If the end of the focusing piezo 22 is connected to the objective lens holder 25, the objective lens 26 is driven in the tracking / focusing direction with the obtained driving force.

The driving force varies depending on the degree of potential difference with respect to the piezo. Therefore, the driving force and the frequency response required for driving are sufficient and piezoelectric in nature, and the range of displacement and frequency characteristic necessary for driving are also sufficient.

The driving method of displacing the piezo via a potential difference to obtain direct driving force is to attach an objective lens to the coil holder, support the tracking / focusing coil on several wires, and attach a magnet to the yoke at the bottom so that the tracking coil and focusing coil The driving method is completely different from the wire spring-supported two-dimensional actuator that constitutes the magnetic field generated by the magnet and the magnetic circuit to drive the objective lens up, down, left and right in the focusing direction and the tracking direction.

The magnitude of the force represented by the driving force in the wire spring-supported two-dimensional actuator is determined in proportion to the relationship between the magnetic flux density of the magnet, the effective length and the number of turns of the coil, and the strength of the current, but is driven by the coil in the magnetic field. Fell and numerically did not exceed approximately 50%.

When the piezo is displaced to obtain the driving force, these variables are reduced and at the same time, the driving force is directly generated by the potential difference, so it is faster and stronger in the transmission of speed or force.

Therefore, set the driving range of the objective lens in the focusing direction to ± 1 to 2mm and the tracking direction to ± 0.3 to 0.5mm as the driving area.In the playback stage, ± 1µm in the focusing direction and ± 0.1µm in the tracking direction. The area can be larger than that of general actuators designed to follow. This results in an increase in the double speed of the objective lens for playback and recording, resulting in adaptation to high double speed.

In addition, the wire spring-supported two-dimensional actuator is structurally integrated with a tracking / focusing drive unit, so that the separation of the drive is not complete due to interference and crosstalk between each other, but the driving / separation drive is replaced by a piezo. Is possible. This appears to be a synergistic effect that suppresses the occurrence of unnecessary vibration modes and helps the stability of the playback and recording operations.

As such, the present invention enables high-speed driving of the objective lens required for double-speed increase for the reproduction and recording of the optical pickup head, and has an effect of being adapted to the increase of the double-speed, while maintaining the driving force of the objective lens sufficiently while maintaining stable frequency response. By doing so, there is an effect of improving the stability and reliability of the reproduction and recording operations.

Claims (4)

An objective lens holder on which an objective lens is placed, A frame located on the opposite side of the holder and connected to the holder by a wire Several plate-shaped piezos intersected and fixed perpendicularly to each other between the holder and the frame for driving the objective lens in the tracking / focusing direction, And a fixing means for dividing the piezo into a tracking / focusing piezo and connecting the piezo vertically with respect to a corresponding contact surface. The piezoelectric device of claim 1, wherein the piezo is a plate-shaped tracking piezo having a thin thickness, a narrow width relative to a length, and a vertical direction in the thickness direction; An optical pickup objective lens driving apparatus comprising a focusing piezo having a shape corresponding to a tracking piezo and having a horizontal thickness direction. The objective lens driving device of claim 1, wherein the focusing piezoelectric tip is connected to the objective lens holder. The optical pickup according to claim 1, wherein the fixing member (23) is formed of a plate shape having a '+' shape or a concave-convex shape corresponding to a surface where the tracking / focusing piezos (21) (22) contact each other. Objective lens drive device.