KR100291751B1 - A damping structure in shaft type optical pick-up actuator - Google Patents

Abstract

The present invention is to generate a sufficient damping force in the optical pick-up actuator, which is uniform regardless of the degree of machining or the manufacturing state of each component, respectively, for the focusing direction and the tracking direction.

The present invention for this purpose, the one end is fixed to the lens holder 40 through the yoke 10, the central region is guided by the yoke 10, the longitudinal direction at the other end of the rotary shaft 30 A piston 31 comprising a vertical plate 34 vertically connected between a pair of horizontal plates 32 and a pair of horizontal plates 32 fixed vertically, spaced at a predetermined interval relative to the piston 31, and a piston 31. In the damping structure of the axial optical pickup actuator including a damping case 60 fixed to one side of the yoke 10 and having a horizontal plate 32 and a vertical plate 34 of the lens holder 40. By generating a structural damping force that prevents rotation in the horizontal direction and flow in the optical axis direction, it is uniform and uniform for the focusing direction and the tracking direction irrespective of the processing degree or manufacturing state of each part related to the damping of the lens holder 40. Each has the effect of generating sufficient damping force.

Description

A damping structure in shaft type optical pick-up actuator

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a damping structure of an axial optical pickup actuator. In particular, the present invention relates to a damping structure of a lens holder. It relates to a damping structure of an axial optical pickup actuator that is uniform regardless of the state and generates sufficient damping force for the focusing direction and the tracking direction, respectively.

First, an example of an axial method as an optical pickup actuator for reproducing the recording of an optical recording medium is shown in FIG.

The actuator forms a circular hole 143 in the center of the lens holder 140 to fix the objective lens 142, to form a shaft hole 150 on one side, and to form an arc-shaped long hole 148 on the other side The tracking coil 146 is wound and the focusing coil 144 is wound around the side.

In addition, the yoke 110 fixes the central axis 114 inserted into the shaft hole 150 of the lens holder 140, and is positioned outside the tracking coil 146 and the focusing coil 144 to fix the magnet 120. The bending piece 112 is formed.

FIG. 2 illustrates a state in which the magnetic body 152 is fixed to the lens holder 140 at the point where the tracking coil 146 and the focusing coil 144 intersect in order to float the lens holder 140 in the actuator. The magnetic body 152 is attracted to the magnetic force of the magnet 120 to float the lens holder 140, thereby removing the friction that the lens holder 140 in contact with the yoke 110.

Meanwhile, the PCC 154 to which the tracking coil 146 and the focusing coil 144 are connected to the upper surface of the lens holder 140 is fixed to allow the flexible PC to be connected to the power supply unit (not shown). .

Hereinafter, the operation of the optical pickup actuator having the above configuration will be described.

The laser beam of the optical system is irradiated perpendicularly to the objective lens 142 through the circular hole 143 of the lens holder 140, and the laser beam passing through the objective lens 142 is focused on the disc to reproduce the recording.

When a tracking error occurs at the focal point of the laser beam formed by the objective lens 142 during disc playback, the power supply unit supplies power to the tracking coil 146 under the magnetic flux of the magnet 120 through the PC 154. By generating an electromagnetic force in the horizontal direction, the lens holder 140 is rotated about the central axis 114 to correct the tracking error.

In addition, when a focusing error occurs at the focus of the laser beam, power is applied to the focusing coil 144 to generate an electromagnetic force in the vertical direction, thereby moving the lens holder 140 in the optical axis direction to correct the focusing error of the laser beam.

On the other hand, in the conventional optical pickup actuator having the structure as described above, the force for damping unnecessary vibration generated during the driving of the lens holder 140, the inner peripheral surface of the shaft hole 150 formed in the optical axis direction in the lens holder 140 And the frictional force generated between the outer circumferential surface of the central axis 114 fixed to the yoke 110.

For this reason, the frictional force due to the contact between the shaft hole 150 and the central shaft 114 is generated according to the difference in the degree of processing and the manufacturing state of each shaft hole 150 and the central shaft 114. Accordingly, the conventional optical pickup actuator has a problem in that damping force is unevenly generated depending on the processing degree and manufacturing state of each product related to the damping of the lens holder 140.

In addition, in the conventional optical pickup actuator, since the shaft hole 150 is formed in the optical axis direction, the friction force between the central axis 114 and the shaft hole 150 with respect to the flow in the optical axis direction of the lens holder 140 becomes large, The friction force between the central axis 114 and the shaft hole 150 with respect to the flow in the tracking direction of the lens holder 140 becomes small. Therefore, the conventional optical pickup actuator has a problem that the damping force in the tracking direction is insufficient.

The present invention has been made to solve the above-mentioned conventional problems, and an object of the present invention is uniform, regardless of the processing degree or manufacturing state of each component for damping the lens holder, respectively, for the focusing direction and the tracking direction, respectively It is to provide a damping structure of an axial optical pickup actuator that generates a sufficient damping force.

1 is a perspective view of a general optical pickup actuator.

2 is a cross-sectional view of the optical pickup actuator shown in FIG.

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

4 is a side cross-sectional view of the engaged state of the optical pickup actuator shown in FIG.

<Explanation of symbols for main parts of drawing>

10: York 12: bending piece

14: shaft support boss 16: shaft

20: magnet 30: axis of rotation

31: piston 32: horizontal plate

33: first air passage hole 34: vertical plate

35: second air passage hole 40: lens holder

42: objective lens 43: circular ball

44: focusing coil 46: tracking coil

48: through groove 50: axial inlet hole

51: boss ball 52: magnetic material

54: PC 60: Damping Case

The present invention for achieving the above object, the lens holder for fixing the objective lens on the upper surface and the focusing coil and the tracking coil on the side; An axial optical pickup actuator having a yoke fixed to a magnet facing the focusing coil and the tracking coil, the axial optical pickup actuator comprising: a rotating shaft having one end fixed to the lens holder through the yoke and a central region guided by the yoke; A piston comprising a pair of horizontal plates vertically connected between the pair of horizontal plates and the pair of horizontal plates vertically fixed to the other end of the rotating shaft at predetermined intervals with respect to the longitudinal direction; And a damping case accommodating the piston therein and fixed to one surface of the yoke.

The optical pickup actuator has a damping force under the resistance of air in the vertical plate and the horizontal plate as the lens holder flows integrally with the rotating shaft, and the vertical and horizontal plates of the piston installed on the rotating shaft flow in the air in the damping case. Generate.

Such damping is a structural damping that prevents unnecessary rotation in the horizontal direction of the lens holder and unnecessary flow in the optical axis direction, and the damping force is uniform regardless of the processing degree or manufacturing state of each part related to the damping of the lens holder. Sufficient damping force is generated for the focusing direction and the tracking direction, respectively.

Hereinafter, preferred embodiments of the present invention having the above-described configuration will be described to facilitate implementation of the present invention.

First, an optical pickup actuator of an axial method according to an embodiment of the present invention is illustrated in FIGS. 3 and 4.

As shown in the drawing, the present embodiment includes a lens holder 40 having an objective lens 42 fixed to an upper surface and a focusing coil 44 and a tracking coil 46 fixed to a side surface, a focusing coil 44 and It is applied to an axial optical pickup actuator having a yoke 10 fixed with a magnet 20 facing the tracking coil 46.

In this case, one end is fixed to the lens holder 40 and the rotating shaft 30 is guided to the center area by the yoke 10, and the horizontal plate 32 is fixed to the other end of the rotating shaft 30 and has a horizontal plane. A piston 31 is formed of a vertical plate 34 having a vertical plane, and a damping case 60 accommodated therein and fixed to the yoke 10.

The horizontal plate 32 and the vertical plate 34 are formed with a first air through hole 33 and a second air through hole 35, respectively.

In addition, the yoke 10 has a shaft support boss 14 having a shaft hole 16 into which the rotating shaft 30 is inserted to be protruded upwardly. The shaft support boss 14 is formed below the lens holder 40. A boss hole 51 is inserted to be flowable. In the center of the boss hole 51 is formed an axial pressurizing hole 50 through which the upper end of the rotary shaft 30 is press-fitted.

On the other hand, the objective lens 42 is fixed to the upper end of the circular hole 43 formed in the optical axis direction in the lens holder 40, the yoke 10 forms a bending piece 12 to which the magnet 20 is fixed.

In addition, the magnetic body 52 attracted to the magnetic force of the magnet 20 is fixed to the side of the lens holder 40, and the PCC 54 to which the tracking coil 46 and the focusing coil 44 are connected to the upper surface of the lens holder 40. ) To be connected to a flexible PC (not shown) connected to a power supply (not shown).

Hereinafter, the operation of the optical pickup actuator having the above configuration will be described.

First, when the rotary shaft 30 is coupled to the lens holder 40, the upper end of the rotary shaft 30 having the piston 31 fixed to the lower end passes through the shaft hole 16 from the lower side of the yoke 10 to the lens holder 40. And press-fit into the axial press-in hole (50). In addition, the damping case 60 is fixed to the bottom surface of the yoke 10 in a state where the piston 31 is inserted into the damping case 60, and the periphery of the upper end of the damping case 60 is sealed to prevent leakage of air therein. .

On the other hand, the laser beam of the optical system is irradiated perpendicularly to the objective lens 42 through the circular hole 43 of the lens holder 40, and the laser beam passing through the objective lens 42 is focused on the disc to reproduce the recording. do.

An operation of correcting a focusing error and a tracking error generated in the focus of the laser beam passing through the objective lens 42 in the recording / reproducing operation of the disc will be described with reference to FIG.

When a tracking error occurs at the focal point of the laser beam formed by the objective lens 42 during reproduction of the disc, the power supply unit applies power to the tracking coil 46 via the PC 54. Therefore, a horizontal electromagnetic force is generated in the tracking coil 46 to correct the tracking error by rotating the lens holder 40 about the central axis 30.

When a focusing error occurs at the focal point of the laser beam, the power supply unit applies power to the focusing coil 44 through the PC 54. Therefore, a vertical electromagnetic force is generated in the focusing coil 44 to correct the focusing error of the laser beam by moving the lens holder 40 in the optical axis direction about the central axis 30.

In the operation of the lens holder 40, the magnetic body 52 magnetically floats the lens holder 40 by a force attracted to the magnet 20, thereby eliminating the friction that the lens holder 40 contacts the yoke 10. .

On the other hand, an unnecessary flow occurs in the lens holder 40 while the lens holder 40 is driven as described above, and the flow is transmitted to the rotation shaft 30 coupled to the lens holder 40. Accordingly, the horizontal plate 32 and the vertical plate 34 of the piston 31 installed on the rotary shaft 30 flow in the damping case 60.

Since the horizontal plate 32 is subjected to the resistance of the air to reduce the rotational force of the rotating shaft 30, the horizontal flow of the lens holder 40 is damped. Here, the air acts as a resistance to the flow of the horizontal plate 32 and moves up and down through the first air through hole (33).

In addition, the vertical plate 34 is subjected to the resistance of air to reduce the vertical flow of the rotary shaft 30, thereby damping the flow in the optical axis direction of the lens holder 40. Here too, air acts as a resistance to the flow of the vertical plate 34 and moves to the left and right through the second air through hole (35).

The damping force is a damping structure that prevents the rotation of the lens holder 40 in the horizontal direction and the flow in the optical axis direction. The optical pickup actuator of the present embodiment includes a damping case 60, a first air passing hole 33, and a first damping case. The damping force is determined according to the relative dimensions of the two air through holes 35, and the damping force is uniform regardless of the processing degree or manufacturing state of each part.

Here, the upper end of the rotating shaft 30 is press-fitted into the axial press-in hole 50 of the lens holder 40 to flow integrally with the lens holder 40, the central portion of the rotating shaft 30 is the shaft hole formed in the yoke 10 It is coupled to the guide 16 so as to be flowable, and the up and down and rotational directions are possible. In addition, the axial support boss 14 formed in the yoke 10 is also inserted into the boss hole 51 of the lens holder 40 so as not to interfere with the flow of the lens holder 40.

As described in the above embodiment, the present invention has a rotation shaft 30, one end of which is fixed to the lens holder 40 through the yoke 10 and the center region is guided by the yoke 10, and the rotation shaft 30 Piston 31 consisting of a vertical plate 34 for vertically connecting between a pair of horizontal plate 32 and a pair of horizontal plate 32 is fixed vertically spaced at a predetermined interval in the longitudinal direction at the other end of the And a damping structure of the axial optical pickup actuator including a damping case 60 which accommodates the piston 31 therein and is fixed to one surface of the yoke 10, wherein the horizontal plate 32 and the vertical plate 34 are lenses. By generating a structural damping force that prevents the horizontal rotation of the holder 40 and the flow in the optical axis direction, a uniform and focusing direction is achieved regardless of the processing degree or manufacturing state of each component related to the damping of the lens holder 40. And sufficient damping force for the tracking direction, respectively. It works.

Claims (3)

A lens holder 40 which fixes the objective lens 42 to the upper surface and fixes the focusing coil 44 and the tracking coil 46 to the side; In the axial optical pickup actuator having a yoke 10 fixed to the focusing coil 44 and the magnet 20 facing the tracking coil 46, A rotation shaft 30 having one end penetrated through the yoke 10 and fixed to the lens holder 40 and a central region guided by the yoke 10; On the other end of the rotary shaft 30 to the vertical plate 34 vertically connected between the pair of horizontal plate 32 and the pair of horizontal plate 32 is fixed vertically spaced at a predetermined interval in the longitudinal direction Piston 31; And Damping structure of the axial optical pickup actuator, characterized in that it comprises a damping case (60) accommodated therein and fixed to one surface of the yoke (10). According to claim 1, The horizontal plate 32 is formed with a plurality of first air through holes 33, The vertical plate (34) is a damping structure of the axial optical pickup actuator, characterized in that a plurality of second air through hole 35 is formed. According to claim 1, The yoke 10 has a shaft support boss 14 having a shaft hole 16, the rotational shaft 30 is inserted into the flowable protruding upwards, In the lens holder 40, the boss hole 51 into which the shaft support boss 14 is inserted into the lens holder 40 and the shaft press-in hole 50 in which an upper end of the rotation shaft 30 is press-fitted into the center of the boss hole 51. Damping structure of the axial optical pickup actuator, characterized in that formed.