KR20020087185A - Extruded lens type optical pickup actuator - Google Patents

Abstract

PURPOSE: A lens-protrusion type optical pickup actuator is provided to prevent the transmission of vibration from a head part to a tail part of a lens holder by coupling a vibration absorbing element in the central portion to which the deformation force generated in the tail part. CONSTITUTION: A lens-protrusion type optical pickup actuator includes a lens holder(112) having a protruded head part(112a) for securing an objective lens(111), and tail parts(112b) integrated with the head part and each having a rear part in the shape of opened leg, and vibration absorbing elements coupled between the head and tail parts for reducing the vibration transmitted from the tail parts to the head part of the lens holder by absorbing the strain energy in the vibration mode.

Description

Lens protrusion type optical pickup actuator {EXTRUDED LENS TYPE OPTICAL PICKUP ACTUATOR}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a lens projecting optical pickup actuator, and more particularly to a lens projecting optical pickup actuator which improves the performance of an actuator by opening the rear end of the optical pickup actuator and reducing unwanted high order resonances.

In general, an objective lens driving device for driving an optical spot to follow the center of a signal track of an optical disk with respect to the surface vibration and eccentricity of the optical disk due to the condensed light beam from the objective lens is driven together with the optical pickup.

Such an objective lens driving apparatus is called an optical pickup actuator, and the objective lenses perform translational movements in the focusing and tracking directions perpendicular to each other, and allow the movement to be performed without unnecessary vibration such as rotation or torsion in order to reduce an error of the optical signal.

In addition, optical pickup actuators should be made as thin and light as possible to meet the special requirements of portable personal computers such as laptops, such as space limitations and portability. Since the spacing is a major factor that determines the overall height of the drive or optical pickup actuator, a concept structure is required to reduce this, and an actuator (lens protruding) shape in which an objective lens protrudes forward is required to satisfy this requirement. Do.

This conventional lens protrusion type optical pickup actuator structure will be described with reference to FIG. 1.

Referring to FIG. 1, the lens holder 12 includes an objective lens 11 for condensing a light beam from a laser diode light source on an information recording surface of an optical disc, a head portion 12a on which the objective lens 11 is seated and protruded; A tail portion 12d is formed integrally with the head portion 12a and is provided with a tail portion 12d for installing a magnetic circuit in the bobbin portion 12c processed therein.

FIG. 2 is a configuration diagram in which a magnetic circuit is provided in the lens holder structure of FIG. 1. Referring to FIG. 2, a magnetic circuit installed in bobbins 12c of the lens holder 36 is fixed to a pickup base. (13) and the yoke 14 positioned on the rear surface of the magnet 13 to prevent magnetic flux leaking out of the rear surface of the magnet 13, and the inner diameter surface of the lens holder 12 opposite to the magnet 13; The wound tracking coil 15 and the focusing coil 16 wound around the inner diameter surface of the lens holder 12 at right angles to the tracking coil 15 are provided.

Further, a wire spring 17 is provided on the left and right sides of the lens holder 12 to supply current to the tracking coil 15 and the focusing coil 16 and to support the lens holder 12.

A conventional lens protrusion optical pickup actuator as described above will be described with reference to the accompanying drawings.

1 and 2, the lens holder 12 can be largely divided into a head portion 12a and a tail portion 12b, and the head portion 12a normally protrudes and protrudes to avoid an optical path from a light source. The objective lens 11 is attached to the site.

Through the objective lens 11, the lens holder (for the focus direction driving to focus the light beam is perpendicularly irradiated to the disk surface and the track direction driving to focus according to the track signal recorded on the disk) 12 is a structure in which the magnet 13 and the yoke 14 which form a magnetic circuit are supported by the pick-up base and inserted into the inner diameter of the bobbin part 12c of the center.

The tracking coil 15 is wound around the bobbin portion 12c of the lens holder 12, and the focusing coil 16 is wound around the inner side of the bobbin portion of the lens holder 12 at a right angle to the tracking coil 15. .

In the wire spring 17, the lens holder 12 has fixed points at both left and right sides, and the up and down and left and right movements of the optical pickup actuator according to the tracking operation and the focusing operation are driven in two axes based on the end portion of the wire spring 17. It is done if possible.

In addition, the lens holder 12 having the objective lens 11 attached to the head 12a may include a magnet 13, a yoke 14, a tracking coil 15, and a focusing coil 16 for focusing and tracking. The objective lens 11 is driven up, down, left and right.

The driving force of the optical pickup actuator forms a tracking coil 15 and a focusing coil 16 in a magnetic space formed by the magnet 13 and the yoke 14 to control power in the focus direction and the track direction. 16), it is operated by Lorentz force according to Fleming's left hand law according to its power supply. The yoke 14 is made of a magnetic body of a steel system and is located on the rear surface of the magnet 13.

The optical pick-up actuator driven by the magnetic force in the up-down (focusing) direction and the left-right (tracking) direction generated in such a magnetic circuit has an up-down movement, a left-right movement with the axis of the tip of the wire spring 17 fixed to the fixed portion as an axis. To perform the focusing operation and the tracking operation.

In the conventional lens holder 12 as described above, the frequency characteristics of the actuator are determined by the stiffness of the wire spring 17 and the mass of the lens holder part on both sides thereof. However, since the lens holder itself is a mechanical structure, it has a unique vibration frequency, and when the actuator is excited at the vibration frequency, the lens holder resonates due to the inherent vibration mode of the lens holder 12.

Looking at the vibration mode in the conventional lens holder, the lens holder structure is a mode in which the entire lens holder is deformed to vibrate in the form of twisting or bending (Bending). The vibration mode of the lens holder causes the objective lens to also vibrate, which directly affects the beam, making it difficult to control the actuator that must follow the disk.

The inherent vibration mode of the lens holder 12 is a characteristic determined by the shape of the lens holder 12. The vibration mode of the lens holder itself causes the objective lens 11 to vibrate together, resulting in distortion of the beam. This will adversely affect the control characteristics that follow.

Due to the conventional lens holder structure, unwanted high-order resonance occurs, and such high-order resonance is shown in the graphs of frequency, phase, and gain (dB) in FIG. 3 (a) (b). Since high-order resonance occurs near 17 khz (about 15 to 20 khz), there is a problem in that the overall frequency characteristic decreases and the control characteristics of the actuator become difficult.

The present invention has been made to solve the above problems, and the bobbin portion of the lens holder has an open structure and the vibration transmitted to the head to the appropriate element between the head portion to which the lens holder is seated and the tail portion for supporting the operation thereof. It is an object of the present invention to provide a lens projecting optical pickup actuator which can reduce the higher order resonance of the lens holder and improve the performance of the actuator by coating and inserting a vibration absorbing member for reducing the pressure.

1 is a plan view showing the structure of a conventional lens projection optical pickup actuator.

2 is a conceptual diagram showing a magnetic circuit configuration of a conventional lens protrusion optical pickup actuator.

Figure 3 (a) (b) is a graph showing the frequency characteristics by the structure of a conventional lens protrusion optical pickup actuator.

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

5 is a conceptual diagram illustrating an example of vibration of the rear end portion of the lens holder of FIG. 4 according to the present invention;

6 is a view showing the configuration of a magnetic circuit in the structure of the lens protrusion optical pickup actuator according to the embodiment of the present invention.

Figure 7 (a) (b) is a graph showing the frequency characteristics by the structure of the lens protrusion optical pickup actuator according to an embodiment of the present invention.

8 is a plan view showing a structure of a lens protrusion optical pickup actuator according to another embodiment of the present invention.

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

11,111 objective lens 12,112,212 lens holder

13,113 ... Magnet 14,114 ... York

15,115 ... tracking coil 16,116 ... focusing coil

12a, 112a ... head 12b, 112b ... tail

112c, 122c ... damper groove 120,130 ... damper

Lens projection type optical pickup actuator according to the present invention for achieving the above object,

In the lens projection optical pickup actuator,

A lens holder including a protruding head portion for mounting the objective lens and a tail portion integrated with the head portion and having a rear end portion thereof open;

It characterized in that it comprises a vibration absorbing member coupled between the head and the tail to reduce the vibration transmitted to the head from the tail of the lens holder.

Preferably, the vibration absorbing member is a damper.

Preferably, the lens holder is characterized in that the damper is applied by processing the damper insertion grooves in each of the outer surface that is integrally connected to each of the tail portion.

Preferably, the lens holder is characterized in that the processing of the damper insertion grooves and applying the damper to each of the inner surface of the element in which each tail is integrally connected to the head.

Preferably, the lens holder is characterized in that it comprises a magnetic circuit for the operation of the lens holder in the inner diameter and the inner periphery of the tail portion.

Hereinafter, with reference to the accompanying drawings as follows.

4 is a plan view illustrating a structure of a lens protrusion optical pickup actuator according to an exemplary embodiment of the present invention, FIG. 5 is a conceptual diagram illustrating an example of vibration of the tail of the lens holder of FIG. 4, and FIG. 6 is a lens according to an exemplary embodiment of the present invention. 7 is a diagram illustrating a magnetic circuit configuration of the protruding optical pickup actuator, and FIGS. 7A and 7B are graphs showing frequency characteristics of the lens protruding optical pickup actuator according to the embodiment of the present invention.

4 and 6, the protruding head portion 112a on which the objective lens 111 is seated, and the tail portion 112b having a leg shape formed integrally with the head portion 112a and the rear end thereof are opened. The lens holder 112, the damper 120 for reducing the vibration of the self on the left, right outer surface or the inner surface of the lens holder 112, and the damper coupling groove (112c) is applied to the damper 120 applied coating It includes a configuration.

In detail, the tail portion 112b of the lens holder 112 is formed with an internal groove 112d having a “c” shape, and therein, a mark net 113 and a yoke 114 for tracking the lens holder and tracking the inside of the lens holder 112. And the focusing coils 115 and 116 are installed.

FIG. 8 illustrates a structure in which a damper 130 for reducing self vibration is coupled to a damper coupling groove 122c on the left and right inner surfaces of the lens holder 112.

The lens protrusion optical pickup actuator according to the present invention as described above will be described with reference to the accompanying drawings.

4 to 6, the lens holder 112 is largely divided into a head portion 112a and a tail portion 112b, and an objective lens 111 is seated on the head portion 112a, and the head portion ( On the left and right sides of 112a, the tail 112b is integrally molded into a leg shape.

The damper coupling groove 112c has a predetermined depth in the molded outer surface of the head portion 112a and the tail portion 112b of the lens holder 112 in the longitudinal direction, and the damper coupling groove 112c. Each damper 120 is applied and inserted.

The tail portion 112b of the lens holder 112 has an internal groove 112d processed into a "c" shape, and thus a magnetic circuit necessary for the operation of the lens holder 112 is provided in the "c" groove 112d. Install.

Here, due to the vibration mode according to the operation of the lens holder 112, the vibration form at the tail portion 112b flows up, down, left, right, or a combination thereof based on the head 112a as shown in FIG. 5. At this time, the damper 120 absorbs the vibration transmitted from the tail portion 112b of the lens holder 112 to the head portion 112a and attenuates and blocks the vibration.

That is, since the vibration energy (strain energy) in the vibration mode of the lens holder 112 is concentrated on the damper coupling groove 112c portion, by applying the damper 120 to the damper coupling groove 112c portion, The vibration transmitted by the objective lens 111 from the tail 112b to the seated head 112a is attenuated and blocked, so that the vibration effect of the objective lens 111 is not affected by the lens holder 112.

As shown in FIG. 6, the magnetic circuit for the operation of the lens holder 112 includes a focusing coil for operation in the focusing direction and the tracking direction around the inner groove 112d of the lens holder 112. 116, the tracking coil 115 is provided, and the yoke 114 and the magnet 114 fixed to the yoke 114 are installed in the pickup base.

Then, the lens holder 112 is moved in the focusing direction and the tracking direction by a magnetic field generated between the focusing coil 115 or the tracking coil 116 and the magnet 114 by the current applied to the coils 115 and 116. give.

When the lens holder 112 is operated, a local vibration mode is generated at the tail 112b, and the damper 120 attenuates (absorbs) the vibration energy generated from the vibration mode and transfers the vibration to the head 112a. Block it from becoming As a result, the vibration generated by the tail 112b is prevented from being transmitted to the objective lens 111 by the vibration of the lens holder 112, thereby preventing the vibration effect of the lens holder 112 from reaching the objective lens. .

FIG. 8 illustrates another embodiment of the present invention, wherein the damper coupling groove 122c is processed into an inner surface between the head 112a and the tail portion 12b of the lens holder 112, and the damper coupling groove 122c. By allowing the damper 130 to be applied to the coating, the damper 130 absorbs vibration energy from the damper 130 and blocks the damper 130 from being transmitted to the objective lens.

As such, by opening the rear end of the lens holder 112 and providing dampers 120 and 130 for vibration attenuation of the rear end of the lens holder 112 to the element where the vibration energy is concentrated, the objective lens 111 is subjected to vibration by the lens holder 112. There is little impact. This results in a higher order resonant frequency of more than twice that of an actuator having a conventional lens holder structure. That is, in the tracking mode, the secondary resonant frequency is 17 kHz as shown in FIG. 3 (a) (b), whereas the present invention provides a higher order resonant frequency as shown in (a) (b) of FIG. Can be improved to 41kHz (about 35 ~ 41khz).

According to the lens projecting optical pickup actuator according to the present invention as described above, by opening the rear end of the lens holder and by coupling the vibration absorbing member to the central portion where the deformation force generated in the open tail portion is concentrated, the lens holder By preventing the vibration caused by opening of the rear end of the lens holder to be transmitted to the seated portion, and having a higher resonant frequency more than twice as compared to the conventional optical pickup actuator, stable optical pickup control is possible.

Claims (3)

In the lens projection optical pickup actuator, A lens holder including a protruding head portion for mounting an objective lens and a leg-shaped tail portion integrated with the head portion and whose rear end portion is opened; And a vibration absorbing member coupled between the head and the tail to reduce the vibration transmitted from the tail of the lens holder to the head. The method of claim 1, And a vibration damping member is applied to the outer surface between the head and the tail to apply and insert the vibration absorbing member. The method of claim 1, And a damper coupling groove is applied to the inner surface between the head and the tail to apply and insert a vibration absorbing member.