KR20050123347A - Optical pick-up actuator - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical pick-up actuator in which an optical pick-up actuator, in particular, consists of two directional coils on both sides of the lens holder, to shorten the manufacturing process of the actuator. .

An optical pickup actuator according to the present invention comprises: a lens holder for mounting an objective lens in a central portion thereof and moving in a multi-axis direction; A focusing coil provided at both left and right sides of the lens holder; A radial coil provided in close contact with one side of the focusing coil; A tracking coil provided at the center of both side surfaces of the lens holder; It characterized in that it comprises a magnet opposite the polarity and the coils located on both sides of the lens holder.

Description

Optical pick-up actuator

The present invention provides an optical pick-up actuator (optical pick-up actuator), in particular in the rolling mode of the lens holder caused by the imbalance between the center of gravity and the tracking force of the lens holder, the light to effectively eliminate the phase disturbance phenomenon It relates to a pickup actuator.

In general, the optical pickup actuator moves a structural element (bobbin, lens holder) including an objective lens to maintain a constant position between the objective lens and the optical recording medium (eg, a disk). Further, the optical pickup actuator records the information by following the track of the optical recording medium and also plays a role of reproducing the recorded information.

1 is a block diagram showing a conventional optical pickup actuator.

Referring to FIG. 1, the optical pickup actuator 100 includes a lens holder 101 for mounting and operating an objective lens 102 at a central portion thereof, and a magnetic circuit coupled to a side surface of the lens holder for operation. The magnetic circuit consists of tracking and focusing coils 105, 106, yoke 103, and a multipole magnetized magnet 104.

Focusing coils 105 are attached to the left and right sides of the lens holder 101 for focusing operation, and tracking coils 106 are attached to the centers of both sides of the lens holder 101 for tracking operation.

In addition, a radial coil 117 is attached to the upper circumferential surface of the lens holder 101 for radial tilt movement.

2 and 3, the focusing coil 105 faces the upper and lower polarity interfaces of the polarity of the magnet 104, respectively, and the tracking coil 106 and the radial coil 117 are of the polarity of the magnet 104. Opposite the left and right boundaries.

In addition, as shown in FIG. 3, the magnet 104 has “a” shaped magnets 104a and 104c disposed symmetrically with each other, and is opposite to the magnet polarity having a “a” shaped magnet at the lower left and right sides thereof. Magnets 104b and 104d having polarities of are arranged. As an example of such a magnet 104, one magnet may be magnetized in a multipole, or may be composed of four unipolar magnets or the like.

The magnet 104 has different polarities 104a and 104c opposite to the rotational center of the tracking coil 106 in the vertical direction, and different polarities 104a facing the rotational center of the focusing coil 105 in the left and right directions. 104b) is located.

In addition, the multi-pole magnetized magnet 104 is fixed to the inner surface of the "U-shaped yoke 103, which is a ferromagnetic material to the left and right of the lens holder 101, the yoke 103 is a pickup base (not shown) And are integrated by means of integration.

One end of two or three parallel wire suspensions 107 is fixed to upper and lower side central portions of the lens holder 101, and the other end of the wire suspension 107 is provided at one side of the lens holder 101. It is fixed to the substrate (not shown) through the frame 109. The wire suspension 107 floats the lens holder 101 and serves as a relay line for supplying current.

Here, a damper (not shown) is coupled to the inside of the frame 109 so as to have a rigid damping characteristic of the wire suspension 107, and the other end of the wire suspension 107 is fixed to the substrate bonded to the outside thereof. Be sure to

As shown in FIGS. 1 and 2, the focusing coil 105 attached to the left and right sides of the lens holder 101 is wound in a direction perpendicular to the tracking coil 106. When a current flows through 105, the direction of the magnetic flux is generated in the up and down directions. At this time, as the magnetic flux of the multi-pole magnet 104 opposite to the focusing coil 105 acts electromagnetically, a force is generated in a direction perpendicular to the focusing coil 105, so that the lens holder 101 moves in the focusing direction (vertical up / down). ), And the focusing servo is operated to correct it.

The tracking coils 106 attached to the central portions of both sides of the lens holder 101 are wound in proper directions to generate magnetic flux in a predetermined direction when current flows, which is caused by the fixed multipole magnet 104 and the electromagnetic force. And repulsive force is generated. By the repulsive force and the repulsive force, the movement of the lens holder 101 moves in the tracking directions (left and right), so that the tracking servo for correcting the tracking error is operated.

Then, the radial tilting coil 117 is attached to the circumferential surface of the lens holder 101, and the radial tilting coil 117 moves the lens holder 101 in the radial tilting direction by an electromagnetic force with the magnet 104 having the multipole magnetized. Get it running.

That is, when a current flows through the radial coil 117 wound on the circumferential surface of the lens holder as shown in FIG. 3, the lens holder 101 is formed by different polarities of the multipole magnets 104a and 104b facing the radial coil 117. Rotate the left / right side of) in opposite directions.

The optical pickup actuator 100 moves in the form of a movable coil by a permanent magnet magnetic field, and moves the objective lens to a desired predetermined position of the optical recording medium. In this case, a lens holder, which is a moving part of the optical pickup actuator, is fixed to a wire suspension having rigidity and attenuation characteristics and designed to have a predetermined desired frequency characteristic. In addition, the lens holder is translated in two focusing directions, a tracking direction and a tracking direction, which are perpendicular to each other, and in order to reduce the error of the optical signal, the lens holder is moved without any unnecessary vibration such as rotation or torsion. It should be done.

Such a lens holder 101 is called a moving coil method, which moves in the tracking and focusing direction together with the coils 105 and 106 attached to both sides. In contrast, a multi-pole magnet is attached to the outer circumferential surface of the lens holder and The movement of a multipole magnet together is called a moving magnet method. At this time, the moving method by magnet and coil uses Lorentz force of Fleming's left hand law.

However, conventionally, there is a problem that a new process is required by winding the radial coil to the outside of the lens holder of Bo-min. That is, the wire hole portion must be formed in the mold of the lens holder for winding the radial coil, which is added as a new process rather than an assembly process of the actuator.

In addition, there is a problem in that additional equipment for winding the radial coil is required.

A first object of the present invention is to provide an optical pick-up actuator which allows winding of a radial coil and a focusing coil continuously by allowing the radial coil to be wound to one side of the focusing coil.

A second object of the present invention is to provide an optical pickup actuator capable of winding a radial coil on the inner or outer circumference of the focusing coil.

A third object of the present invention is to provide an optical pickup actuator capable of winding a radial coil on the front side or the rear side of a focusing coil.

Optical pickup actuator according to the present invention for achieving the above object,

A lens holder for attaching an objective lens to the center and moving in the multi-axis direction;

A focusing coil provided at both left and right sides of the lens holder;

A radial coil provided in close contact with one side of the focusing coil;

A tracking coil provided at the center of both side surfaces of the lens holder;

It characterized in that it comprises a magnet opposite the polarity and the coils located on both sides of the lens holder.

Preferably, the focusing coil is wound on the outer side of the bobbin formed on both left and right sides of the lens holder, and the radial coil is wound around the inner side of the bobbin and the focusing coil.

Preferably, the focusing coil is wound on the inside of the bobbins formed on the left and right sides of the lens holder, and the radial coil is wound on the outer side of the bobbin and the outer periphery of the focusing coil.

Preferably, the focusing coil is wound on the outer surface of the bobbin formed on the left and right sides of the lens holder, and the radial coil is wound in close contact with the focusing coil on the inner surface of the bobbin.

Preferably, the focusing coil is wound on an inner surface of a bobbin formed on both left and right sides of the lens holder, and the radial coil is wound on the outer surface of the bobbin to be in close contact with the focusing coil.

Referring to the accompanying drawings, the optical pickup actuator according to the present invention configured as described above is as follows.

4 to 6, a lens holder 201 for mounting and operating an objective lens 202 at a central portion thereof, and coils 205, 206, 217 as magnetic circuits coupled to side surfaces for multi-axis movement of the lens holder 201, and It consists of a multipole magnet 204 and a yoke 203.

The focusing coil 205 is attached to the left and right sides of the lens holder 201 so as to face the upper and lower polarity boundary surfaces of the multipole magnet 204, and the tracking coil 306 is attached to the center of both sides of the lens holder 201. Opposite the left and right polarity (N: S) interfaces of the multipole magnets, respectively.

The radial coil 217 is wound close to one side of each focusing coil 205. For example, the radial coil 217 is wound around an inner circumference of the focusing coil 205 and has a vertical polarity (N: S) of the multipole magnetized magnet 204. , S: N) faces the interface. At this time, when the coil is wound, the radial coil is first wound on the bobbin, and then a focusing coil is wound around the radial coil.

Here, the radial coil 217 is connected in series with the radial coil facing each other on both sides of the lens holder 201, and in parallel with the adjacent coil in parallel, it is possible to operate the lens holder in the radial direction. . Alternatively, the coils may be independently wound to control the current magnitude and the direction.

The focusing coil 205 and the radial coil 217 are wound around respective bobbins formed on both sides of the lens holder 201 on the left and right sides of the lens holder 201. Two coils are wound tightly. The width or winding width of the focusing coil 205 may be wider than that of the radial coil 217.

In addition, as shown in FIG. 5, in the multi-pole magnetized magnet 204 spaced apart from both sides of the lens holder, the magnets 204a and 204b of the "-" shape are disposed symmetrically with each other, and the "a" at the lower left and right sides thereof. "Magnets 204c and 204d having polarities opposite to the magnet shape magnet polarities are disposed. As an example of such a magnet 204, one magnet may be formed by magnetizing in multiple poles, or four monopolar magnets or the like.

In the multi-pole magnet 204, the polarity boundary in the horizontal direction of the left / right direction is opposite to the rotational center of the tracking coil 206 and the polarity boundary in the vertical direction is rotated between the focusing coil 205 and the radial coil 217. It is placed opposite the center.

Here, the tracking coil 206 attached to the left / right side center of the lens holder 201 is wound in a trapezoidal or quadrangular shape in which the lower winding width is wider than the upper winding width.

In addition, the multi-pole magnetized magnet 204 is fixed to the inner surface of the ferromagnetic "U" shaped yoke 203 to the left and right of the lens holder 201, the yoke 203 is a pickup base (not shown) ) Is integrated by means of integration.

In addition, one end of three wire suspensions 207 are fixed to upper and lower side central portions of the lens holder 201, and the other end of the wire suspension 207 is connected to one side of the lens holder 202 through a frame. It is fixed to a substrate (not shown). The wire suspension 207 is preferably provided in two or more pairs, it floats the lens holder 202, and serves as a relay line for supplying current.

As shown in FIGS. 4 and 7, the focusing coil 205 attached to the left and right sides of the lens holder 201 is wound in a direction orthogonal to the tracking coil 206 as shown in FIGS. 4 and 7. When the current flows through), the direction of the magnetic flux is generated in the up and down directions. At this time, as the magnetic flux of the multi-pole magnet 203 facing the focusing coil 205 acts electromagnetically, a force is generated in a direction perpendicular to the focusing coil 205, so that the lens holder 202 moves in the focusing direction (vertical up / down). ), And the focusing servo is operated to correct it.

In addition, the trapezoidal tracking coils 206 attached to the central portions of both sides of the lens holder 201 are wound in a proper direction to generate magnetic flux in a predetermined direction when current flows thereto, which is fixed to the multipole magnet 203. And repulsive force and repulsive force are generated by the electromagnetic force. By the repulsive force and the repulsive force, the movement of the lens holder 202 moves in the tracking directions (left and right), so that the tracking servo for correcting the tracking error is operated.

Then, when a current flows through the radial coil 217 wound around the inner side of the focusing coil 205 of the lens holder 201, the multi-pole magnets 204a and 204c facing the radial coil 117 (204b and 204d). The left and right sides of the lens holder 201 are rotated in opposite directions by the different polarities of

8 and 9 illustrate another embodiment of the present invention.

8 and 9, the focusing coil 255 is wound around the inner circumference of the bobbin formed at both the left and right sides of the lens holder, and the radial coil 257 is brought into close contact with the outer circumference of the focusing coil 255. It is a wound structure. The tracking coil 256 is configured at both side centers of the lens holder.

In this configuration, since the coils 255, 256, 257 and the magnets 254 and the yoke 253 in each direction face each other, the above-described movement of the lens holder in the focusing, tracking, and radial tilt directions works in the same manner. Detailed description of the operation will be omitted.

10 and 11 are still another embodiment of the present invention.

Referring to FIGS. 10 and 11, the focusing coil 265 is wound around the outer surface of the bobbin at both left and right sides of the lens holder, and the radial coil 267 is disposed on the inner surface of the bobbin while facing the focusing coil 265. It is a configuration wound on the inner surface. The tracking coil 266 is configured at both centers of both side surfaces of the lens holder.

In this configuration, since the coils 265, 266, 267 in each direction, the magnets 204, and the yoke 203 face each other, the above-described movement of the lens holder in the focusing, tracking, and radial tilt directions works in the same manner. Detailed description of the operation will be omitted.

Thus, by combining two (two) coils having different directionality in the bobbin formed on the left and right sides of the lens holder, it is possible to install a radial coil together on the bobbin to which the focusing coil is wound. . That is, the two coils are horizontally wound by allowing one side of the focusing coil to be wound around the inner or outer side of the focusing coil, and the inner or outer surface of the focusing coil, so that the coil winding is convenient and additional equipment needs to be added. There will be no.

As described above, according to the optical pickup actuator according to the present invention, since the hole is not formed in the upper circumferential surface of the lens holder for winding the radial coil, the shape and mold structure of the lens holder can be simplified and the work process can be reduced. It works.

In addition, it is possible to wind the radial coil when winding the existing focusing coil, thereby simplifying the winding facility.

1 is a perspective view showing the structure of a conventional optical pickup actuator.

FIG. 2 is a perspective view showing the coil arrangement structure of FIG. 1. FIG.

3 is a view showing movable characteristics in each direction by the magnetic circuit of FIG. 1;

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

5 is a view showing a configuration example of a magnetic circuit according to FIG. 4 of the present invention;

Figure 6 is a perspective view of the coil arrangement structure of the present invention Figure 4;

FIG. 7 is a view showing movable characteristics in respective directions by the magnetic circuit of FIG. 4 of the present invention; FIG.

8 is another configuration diagram of the coil arrangement structure of the present invention.

9 is a diagram illustrating a magnetic circuit of FIG. 8.

10 is another configuration diagram of the coil arrangement structure of the present invention.

FIG. 11 is a diagram illustrating a magnetic circuit of FIG. 10. FIG.

<Description of the symbols for the main parts of the drawings>

201 Lens holder 202 Objective lens

203 ... York 204 ... Magnet

205,255,265 ... focusing coil 206,256,266 ... tracking coil

207 ... wire suspension 217,257,267 ... radial tilting coil

Claims (6)

A lens holder for attaching an objective lens to the center and moving in the multi-axis direction; A focusing coil provided at both left and right sides of the lens holder; A radial coil provided in close contact with one side of the focusing coil; A tracking coil provided at the center of both side surfaces of the lens holder; And a magnet having opposite polarities to the coils positioned at both sides of the lens holder. The method of claim 1, The focusing coil is wound on the outer side of the bobbin formed on the left and right sides of the lens holder, the radial coil is wound around the inner side of the bobbin and the focusing coil optical pickup actuator. The method of claim 1, The focusing coil is wound on the inside of the bobbin formed on the left and right sides of the lens holder, the radial coil is wound around the outer side of the bobbin and the focusing coil. The method of claim 1, The focusing coil is wound on the outer surface of the bobbin formed on the left and right sides of the lens holder, the radial coil is wound in close contact with the focusing coil on the inner surface of the bobbin. The method of claim 1, The focusing coil is wound around the inner surface of the bobbin formed on the left and right sides of the lens holder, the radial coil is wound on the outer surface of the bobbin to be in close contact with the focusing coil. The method of claim 1, The focusing coil and the radial coil are respectively wound on one bobbin formed on each of the left and right sides of the lens holder.