KR20060071252A - Attaching strustrues for objective lens of lens holder - Google Patents

Abstract

The present invention reinforces the adhesive structure of the objective lens attached to the lens holder in the optical pickup actuator, and the objective lens mounting structure of the lens holder according to the present invention, The lens holder is formed along the circumferential surface on which the objective lens is mounted, and a plurality of the lens lens guides are formed to face each other so that the two sides face each other so as to trap the lens adhesive applied therein. The lens holder itself can effectively reduce the magnitude of the higher-order resonance caused by the elastic mode.

Actuator, Lens Holder, Objective Lens

Description

Attaching strustrues for objective lens of lens holder

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

2 is a perspective view showing the objective lens mounting structure of the lens holder in the conventional optical pickup actuator.

3 is a graph showing a high-order resonance phenomenon of the conventional optical pickup actuator.

Figure 4 is a perspective view showing the objective lens mounting structure of the lens holder in the optical pickup actuator according to the embodiment of the present invention.

5 is a partially enlarged view of the objective lens mounting structure of the lens holder according to the embodiment of the present invention.

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

201.Objective lens 202.Lens holder

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

210 Lens mount 211 Lens adhesive guide

212 ... Adhesive groove 213 ... Adhesive reinforcement projection

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical pickup actuator, and more particularly, to an objective lens mounting structure of an optical pickup actuator in which an objective lens can be mounted and fixed to a lens holder.

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 can be configured to translate in two focusing directions and tracking directions perpendicular to each other, and to be capable of driving in the tilt direction, without unnecessary vibration such as rotation or torsion in order to reduce the error of the optical signal. Should be built.

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 denotes a fixed substrate, which is formed on and below 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.

Referring to FIG. 1, the objective lens 101 is mounted at the center of the lens holder 102, and a focusing coil 105 is wound around each corner of the lens holder 102 for focusing, and the lens is used for tracking. The tracking coil 106 is wound around the center of the left and right sides of the holder 102.

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.

2 is a block diagram illustrating a structure in which an objective lens is mounted on a conventional lens holder.

Referring to FIG. 2, an objective lens 101 is mounted at the center of the lens holder 102. In order to mount the objective lens 101, a lens seat 110 is formed at the center of the lens holder 102, a beam through hole is formed at the center of the lens seat 110, and the objective lens 101 is mounted. The lens guide boss 113 for supporting at a predetermined place (about 3 to 4 places) protrudes.

The lens guide boss 113 is formed in a simple upright structure, spaced apart from the objective lens 101 by a predetermined interval, and an adhesive is applied between the lens guide boss 113 and the objective lens 101 to apply the objective lens. The lens holder 102 was fixed.

As described above, even when the objective lens 101 is adhered due to the open structure of the lens guide boss 113, the rigidity of the adhesive is weakened, and when the actuator is resonated under the influence of the lens adhesive, high-order resonance characteristics appear at a specific frequency as shown in FIG. 3. Therefore, the resonance peak measured in the objective lens becomes larger than the resonance peak in the actual lens holder.

Further, as the actuator focuses on the reflecting surface on the disc, in order to have a smooth control for tracking the track on the disc, unnecessary vibration should not occur during the driving of the actuator. Especially in the recent high-speed optical storage device, this characteristic is further required because the control frequency range must be increased. However, due to the resonance caused by the self-elastic mode of the assembly of the moving lens holder, the gain margin is reduced, which adversely affects the control performance.

The present invention has been made to solve the above problems, and to provide a lens adhesive portion for reinforcing the rigidity with the lens holder at a certain portion of the outer surface of the objective lens.

In another aspect, the present invention is to the lens adhesive portion is formed in a structure to guide the lens adhesive to the inside, thereby reinforcing the rigidity of the lens adhesive portion.

Lens mounting structure of the optical pickup actuator of the present invention for achieving the above object,

In the optical pickup actuator having a lens holder which is mounted on the center of the objective lens and is movable,

The lens holder includes a plurality of lens adhesive guides formed along a circumferential surface on which the objective lens is mounted and formed in appropriate positions, the two surfaces facing each other so as to confine the lens adhesive applied therein. Characterized in that.

Preferably, the inside of the lens adhesive guide portion is characterized by protruding the adhesion reinforcing projection for nutrient the groove to which the lens adhesive is applied.

Preferably, the lens adhesive guide portion is characterized in that formed in one of "C" shape, "V" shape or "U" shape.

Hereinafter, with reference to the accompanying drawings as follows.

3 is a perspective view illustrating an objective lens mounting structure of a lens holder according to an exemplary embodiment of the present invention.

Referring to FIG. 3, a lens holder 202 mounted at a center portion and moving in a multi-axis direction, and a lens seating portion for supporting the objective lens 201 at a center portion of the lens holder 202. A lens adhesive guide portion 211 and a plurality of lens adhesive guide portions 211 protruding at a predetermined angle on the lens seating portion 210, the two surfaces facing each other and the direction of the objective lens are opened, are formed in the lens adhesive guide portion. It comprises a lens adhesive groove 212, and the adhesion reinforcing projections 213 protruding from the lens adhesive guide portion 211 in the direction of the objective lens for dividing the lens adhesive groove.

Referring to the accompanying drawings, the objective mounting structure of the lens holder according to the embodiment of the present invention as described above is as follows.

4 and 5, the lens holder 202 is formed with a beam through hole (not shown) so that the objective lens 201 can be mounted at the center thereof, and the objective lens 201 is disposed around the beam through hole. The lens seating portion 210 is formed to be seated. In addition, coils, for example, focusing and tracking coils 205 and 206 are wound on both sides for the operation of the lens holder 202.

The lens seat 210 is formed at a step with the lens holder upper surface along the outer periphery of the objective lens 201, the lens seat 210 is a lens adhesive spaced at a predetermined angle, for example, 90 degrees apart A plurality of guide parts 211 protrude. That is, the 90-degree intervals are four guide parts, and may vary according to the number of guide parts.

The lens adhesive guide portion 211 protrudes in a shape in which two surfaces face each other and are open in one direction, that is, the objective lens direction. For example, it may be formed in one of shapes such as “U”, “C”, “E”, “V”, and the like, and may be formed in a hemispherical shape or a structure bent one or more times.

In addition, the lens adhesive guide portion 211 may be formed in the inner surface of the concave-convex shape, the inside of the adhesive groove 212 is formed due to the structure facing the two surfaces. As another example, the lens adhesive guide portion 211 may form a portion of the upper surface together.

In addition, the lens adhesive guide 211 may form an adhesion reinforcing protrusion 213 protruding in the direction of the objective lens therein. Here, one or more adhesion reinforcing protrusions 213 may be formed and are formed lower than the height of the lens adhesive guide portion 211. In addition, the adhesion reinforcing protrusion 213 may protrude from the lens seating portion 210 or may be formed in an uneven shape.

After mounting the objective lens 201 in the lens seating portion 210, the lens adhesive (not shown) is applied to the lens adhesive guide portion 211. In this case, the lens adhesive includes a UV adhesive or a bond and the like, and the lens adhesive does not leak out of the lens adhesive groove 212 due to the structure in the lens adhesive guide 210. At this time, the lens adhesive is bisected in the groove 212 by the adhesion reinforcing protrusion 213 and connected to each other, the rigidity of the adhesive becomes stronger.

By applying the lens adhesive between the lens adhesive guide portion 211 and the outer surface of the objective lens, the objective lens 201 is mounted to the lens holder 202 in a structure that is more rigid than before. The lens adhesive guide portion 211 may be installed at least two or more and compatible with the existing lens guide boss.

In this way, by attaching the objective lens 201 to the center of the lens holder 202 through the adhesive in the lens adhesive guide portion 211, the rigidity of the adhesive is reinforced, which is vulnerable when the actual lens holder 202 is operated. The structure can be improved, and the phenomenon that the gain margin is reduced due to the higher-order resonance peak due to the elastic mode of the lens holder 202 itself can be improved.

So far, the present invention has been described with reference to the preferred embodiments, and those skilled in the art to which the present invention pertains to the detailed description of the present invention and other forms of embodiments within the essential technical scope of the present invention. Could be implemented. Here, the essential technical scope of the present invention is shown in the claims, and all differences within the equivalent range will be construed as being included in the present invention.

According to the objective lens mounting structure of the lens holder according to the present invention as described above, by strengthening the adhesive structure of the objective lens attached to the lens holder in a drive system for reproducing and recording a high density disk at high speed, The size of the resonant pickle can be effectively reduced, and the known effect can effectively reduce the effect, enabling a stable control system in a high speed drive system.

Claims (3)

In the optical pickup actuator having a lens holder which is mounted on the center of the objective lens and is movable, The lens holder includes a plurality of lens adhesive guides formed along a circumferential surface on which the objective lens is mounted and formed in appropriate positions, the two surfaces facing each other so as to confine the lens adhesive applied therein. The objective lens mounting structure of the lens holder. The method of claim 1, An lens mounting structure of the lens holder, characterized in that the inside of the lens adhesive guide portion protrudes an adhesion reinforcing projection for dividing the groove to which the lens adhesive is applied. The method of claim 1, The lens adhesive guide unit is an objective lens mounting structure of the lens holder, characterized in that formed in one of "C" shape, "V" shape or "U" shape.

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