KR20040076919A - Optical Pick-up actuator - Google Patents

Abstract

PURPOSE: An optical pickup actuator is provided to process a gap for cutting off heat in a lens holder between a lens holder adjacent coil and an objective lens, thereby reducing heat transmitted to the objective lens while improving driving reliability. CONSTITUTION: An objective lens(201) is mounted on a center of a lens holder(202). Focusing coils(205) are wound at right/left edges, and tracking coils(206) are attached to side centers, respectively. A magnet(203) is attached to a yoke(204) in a pickup base opposite to the focusing coils(205) and the tracking coils(206). Fixing substrates(208) are coupled with upper/lower side centers of the lens holder(202). One end of wire suspensions(207) is soldered on each fixing substrate(208). The other end of the wire suspensions(207) is fixed through a damper of a damper holder(209).

Description

Optical pick-up actuator

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical pickup actuator, and more particularly, to an optical pickup actuator that can minimize the transfer of heat generated from an adjacent coil of a lens holder to an objective lens.

A general optical pickup actuator moves a moving part for mounting an objective lens to maintain a constant position between the objective lens and the disc, and tracks / records information recorded on the disc by following the disc track. do. The actuator moves in the form of a movable coil by a permanent magnet magnetic field to move the objective lens to a desired position. At this time, the movable part must translate in two directions perpendicular to each other, focusing and tracking direction, and to be made without unnecessary vibration, such as rotation or twisting to reduce the error of the optical signal.

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

Referring to FIG. 1, a lens holder 102 in which an objective lens 101 is mounted at a center portion and coils 105 and 106 are wound around the outer peripheral surface for tracking and focusing, and a coil of the lens holder 102 is formed. Magnets (103) and yokes (Yoke, 104) installed in the base (105) facing the 105 and 106, and the upper and lower plurality of one end is fixed to the upper and lower sides of the lens holder 102 to support it A wire suspension 107 and a damper holder 109 provided at one side of the lens holder 102 to which the other end of the wire suspension 107 is fixed are provided.

Reference numeral 108 is a fixed substrate, which is formed on and under the lens holder 102 so that one end of the wire suspension 107 is soldered and fixed.

Referring to the accompanying drawings, a conventional optical pickup actuator as described above is as follows.

The objective lens 101 is mounted at the center of the lens holder 102, and a focusing coil 105 is wound around each corner portion of the lens holder 102 for focusing, and the left side of the lens holder 102 for tracking. The tracking coil 106 is wound around the right side center portion.

In addition, a plurality of yokes 104, which are ferromagnetic materials, protrude from the left and right sides of the lens holder 102 at positions opposite to the coils 105 and 106 to fix the magnets 103 to the front surfaces of the yokes. . The yoke 104 is integrated with the pickup base (not shown) by an integration means.

The fixing substrate 108 is coupled to the upper and lower side centers of the lens holder 102, and one end of two parallel wire suspensions 107 is soldered to each of the fixing substrates 108, and the wire suspension 107 is attached thereto. The other end of the damper holder 109 is fixed through a damper (not shown).

Here, a damper (not shown) is coupled to the damper holder 109 so as to have a rigid damping characteristic of the wire suspension 107, and a main substrate (not shown) is coupled to the outside so that the wire suspension 107 is connected to the damper holder 109. Make sure that the other end of is soldered.

The lens holder 102 is floated by the wire suspension 107, and a current is supplied to each of the wire suspensions 107.

In the above structure, the tracking coils 106 attached to the central portions of both sides of the lens holder 102 are wound in appropriate directions with each other, and generate magnetic flux in a predetermined direction when current flows thereto, which is fixed to the magnet 103 and the electromagnetic force. Repulsion and repulsive force is generated by. By the repulsive force and the repulsive force, the movement of the lens holder 102 moves in the tracking direction (before and after), so that the tracking servo for correcting the tracking error is operated.

In addition, the focusing coil 105 is wound in a horizontal direction differently from the tracking coil, and when the current flows, the magnetic flux is generated in the up and down directions, and electromagnetically acts on the magnetic flux of the fixed magnet so as to be perpendicular to the coil. By generating a force, the lens holder 102 is moved in the focusing direction (up and down), so that a focusing servo for correcting this is operated.

The coils 105 and 106 are wound on the outer circumferential surface of the lens holder 102, and the coil moves together with the lens holder 102, which is referred to as a moving coil method. The movement of the magnet with the lens holder 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.

The optical pickup actuator is used to record / reproduce information on an optical disc. In recent years, due to the rapid development of multimedia devices and the active production and dissemination of related contents, the optical pickup system can be used for optical and movie media. Pickup reliability is required.

When the optical pickup is driven for a long time, heat is generated in the coil by a current applied to the driving coil of the actuator, and the generated heat is transferred to the objective lens through the lens holder structure.

As such, when heat is transferred to the objective lens for a long time, aberration becomes large, and when an excessive current is applied, a crack may occur in the objective lens due to thermal stress. Therefore, there is a need for an actuator that can reduce the heat transferred from the drive coil to the objective lens and improve the drive reliability of the pickup.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and an optical pickup actuator for processing a gap in the lens holder between the coil and the objective lens to block heat generated from the driving coil from being transferred to the objective lens. The purpose is to provide.

Another object of the present invention is to provide an optical pickup actuator in which a gap shape processed in the lens holder is processed into a shape capable of maximizing a heat transfer path between the coil and the objective lens and blocking direct heat transfer.

1A and 1B are schematic plan and front views of a conventional optical pickup actuator.

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

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

Figure 4 (a) is a view showing the heat transfer phenomenon in the conventional optical pickup actuator, (b) is a view showing the heat transfer phenomenon according to the present invention.

5 and 6 are a plan view showing an optical pickup actuator according to another embodiment of the present invention.

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

201.Objective lens 202.Lens holder

203 ... Magnet 204 ... York

205 ... focusing coil 206 ... tracking coil

207 ... wire suspension 208 ... fixed board

209 ... damper holder 211,221,231 ... gap

Optical pickup actuator of the present invention for achieving the above object,

A lens holder in which a heat shielding means is formed in a predetermined shape between the adjacent coil and the objective lens in order to attach an objective lens to the central part and to prevent heat generated from the adjacent coil from being directly transferred to the objective lens;

And a coil and a magnet for operating the lens holder outside the lens holder.

Preferably, the heat shield means is a cap machined in a predetermined shape on the left and right side of the lens holder body between the objective lens and the coil attached to the outer periphery of the lens holder.

Preferably, the heat shield means is characterized in that it comprises a gap processed in a rectangular shape having a predetermined length / width in the lens holder between the objective lens and the adjacent coil.

Preferably, the heat blocking means includes a gap formed on a left / right side of the lens holder having a length proportional to the size of the objective lens and a width inversely proportional to the distance between the objective lens and the adjacent coil. It is done.

Preferably, the gap is hemispherically processed along the radius of the objective lens in the lens holder between the objective lens and the adjacent coil.

Hereinafter, with reference to the accompanying drawings as follows.

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

Referring to FIG. 2, a lens holder 202 wound with an objective lens 201 mounted in a center portion and coils 205 and 206 wound for tracking and focusing to an outer circumferential surface thereof, and coils 205 and 206 of the lens holder 202. Magnet (203) and yoke (Yoke, 204) installed on the base opposite to the upper and lower wires, one end is fixed to the upper and lower sides of the lens holder 202 to support it A suspension (wire suspension) 207, a damper holder 209 provided at one side of the lens holder 202 and fixed to the other end of the wire suspension 107, and a lens holder between the objective lens 201 and the adjacent coil ( 202 is configured to include a gap 211 processed to a predetermined length / width.

Here, the gap 211 is a rectangular shape and has a length proportional to the size of the objective lens and is processed to a predetermined width.

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

Referring to FIG. 2, an objective lens 201 is mounted at the center of the lens holder 202, a focusing coil 205 is wound at the left and right edges thereof, and a tracking coil 206 is attached to the center of the side surface thereof. do. The magnet 203 is attached to the yoke 204 on the pickup base at the position opposite to the focusing and tracking coils 205 and 206.

In addition, fixed substrates 208 are coupled to upper and lower side central portions of the lens holder 202, and one end of two parallel wire suspensions 207 is soldered to each of the fixed substrates 208, and the wire suspension ( The other end of the 207 is fixed through a damper (not shown) of the damper holder 209. Current is supplied to each of the wire suspensions 207.

In the above structure, when the current is supplied to the tracking coils 206 attached to the central portions of both sides of the lens holder 202, magnetic flux is generated in a predetermined direction, which generates repulsive force and repulsive force by the fixed magnet 203 and the electromagnetic force. Then, the tracking servo for correcting the tracking error is operated by moving the lens holder 202 in the tracking direction (before and after).

When the current flows through the focusing coil 206, the direction of the magnetic flux is generated in the up and down directions, and acts electromagnetically with the magnetic flux of the fixed magnet 203 to generate a force in the direction perpendicular to the coil. The holder 202 is moved in the focusing direction (up and down) so that a focusing servo for correcting this is operated.

On the other hand, the lens holder 202 processes the gap 211 in the lens holder body to block the heat transfer path between the objective lens 201 and the adjacent coils (205, 206). The gap 211 has a rectangular shape having a length and a predetermined width proportional to the diameter of the objective lens 201 between the objective lens 201 and the tracking coil 206 located at the shortest distance.

In an embodiment, the gap 211 may be changed in length and width, and may be changed in shape according to a location or a heat transfer path where the coil is installed.

Therefore, the heat generated from the coils 205 and 206 is generated by the current applied to the drive coils 205 and 206 of the actuator, and the generated heat increases the temperature of the lens holder structure when the device is driven for a long time.

In this case, the gap 211 of the lens holder 202 blocks the heat transfer path between the objective lens 201 and the adjacent coils 205 and 206, and further aways the heat transfer path, thereby causing the temperature of the objective lens 202 to be reduced. The rise slows.

To this end, the gap 211 processed in the lens holder 201 is relatively far away from the transfer path of heat transferred to the objective lens 202 to block or minimize the heat transfer to the objective lens 202 Improves drive reliability due to thermal shutdown.

3 is a perspective view of the optical pickup actuator according to the present invention, Figure 4 (a) is a view showing the heat transfer phenomenon generated in the conventional optical pickup actuator, the heat generated from the coil is directly transferred to the objective lens temperature Indicates that is raised. 4 (b) is a structure in which a gap is formed in the lens holder according to the present invention, the heat is partially dissipated due to the increase in the cross-sectional area due to the gap, and the heat transfer path away from the coil may slow down the temperature rise of the objective lens. .

For example, the shape of the gaps 221, 231, and 241 formed in the lens holders illustrated in FIGS. 5 to 7 may be changed in width, length, and shape according to a heat transfer path between the objective lens 201 and the adjacent coils 205 and 206. to be.

5 is a structure in which the shape of the gap 221 of the lens holder is hemispherical along the radius of the objective lens, and FIG. 6 is a structure in which the width according to the distance of the gap is inversely proportional to the heat transfer path. That is, the width of the gap is inversely proportional to the heat transfer path, i.e., if the distance is short, the width of the gap is increased, and if the distance is long, the gap has a structure that can bring the width of the gap small. In an embodiment, a plurality of holes may be processed on the heat transfer path of the lens holder body for heat dissipation.

Therefore, since heat generated in the adjacent coils can be prevented from being transferred to the objective lens through the gap, driving reliability can be ensured even when driving the optical pickup for a long time. At the same time, the weight of the lens holder can be reduced by the gap weight.

According to the optical pickup actuator according to the present invention as described above, the heat transfer from the drive coil of the pickup actuator to the objective lens in a long time use environment such as movie, game media, etc. in a drive system for playing and recording a high density disk at high speed By reducing it, the driving reliability of the pickup can be secured.

Claims (5)

A lens holder in which a heat shield means having a predetermined shape is disposed between the adjacent coil and the objective lens in order to attach an objective lens to the central part and to prevent heat generated from the adjacent coil from being directly transferred to the objective lens; And a coil and a magnet for operating the lens holder outside the lens holder. The method of claim 1, And said heat shield means comprises a gap formed in a predetermined shape on the left / right side of the lens holder between the objective lens and the adjacent coil. The method of claim 1, And the heat shield means includes a gap processed in a rectangular shape having a predetermined length / width in a lens holder between an objective lens and an adjacent coil. The method of claim 1, The heat blocking means includes a gap in the lens holder between the objective lens and the adjacent coil, the gap having a length proportional to the size of the objective lens and a width inversely proportional to the distance between the objective lens and the adjacent coil. Optical pickup actuator. The method of claim 1, And said heat shield means comprises a hemispherical gap formed along the radius of the objective lens in the lens holder between the objective lens and the adjacent coil.