KR100390807B1 - Optical Pickup Actuator with Magnetic Axis - Google Patents

Abstract

The present invention is to improve the assembly productivity by reducing the number of parts required for driving the lens holder by magnetizing the axis that is the rotation center of the lens holder to drive the coil fixed to the lens holder.

The present invention for this purpose is a magnetic shaft having a vertical magnetized portion 144 that is fixed to the yoke 140 and inserted into the shaft hole 114 and magnetized in the vertical direction and a horizontal magnetized portion 146 magnetized in the circumferential direction. 142 and a first focusing coil wound around the first horizontal groove 116 and the second horizontal groove 118 respectively formed in the lens holder 110 at positions corresponding to the polarities of the vertical magnetized portions 144. A winding including an outer circumference of the vertical groove 120 and the lens holder 110 formed in the lens holder 110 at a position corresponding to the horizontal magnetizing portion 146 and the second focusing coil 132. An optical pickup actuator comprising a first tracking coil 134 and a second tracking coil 136, wherein a magnetic axis 142 becomes a center of rotation of the lens holder 110 and simultaneously drives the lens holder 110. Acting as a magnet for driving the coils 130 to the second tracking coil 136, driving of the lens holder 110 This reduces the number of parts required to improve assembly productivity.

Description

Optical Pickup Actuator with Magnetic Axis

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical pickup actuator having a magnetic axis. In particular, a magnet for reducing the number of parts required for driving a lens holder by driving a coil fixed to the lens holder by magnetizing a shaft that is the rotation center of the lens holder is rotated. An optical pickup actuator having an axis.

As shown in FIG. 1, a general shaft type optical pickup actuator is formed so as to penetrate a laser passage hole 13 up and down in the outer circumference of the disc-shaped body to fix the objective lens 12, and a plurality of winding coils ( 20 and the lens holder 10 to which the magnetic body 16 is fixed; The yoke 30 fixes the rotation shaft 38 coupled to the shaft hole 18 formed in the lens holder 10 at the center thereof, and fixes the magnets 34 and 36 to correspond to the winding coil 20 and the magnetic body 16. It consists of.

The rotary shaft 38 has a Teflon coating to reduce the friction coefficient, thereby reducing the loss of the rotational force of the lens holder 10 and allowing the rotary shaft 38 to rotate or slide up and down about the rotary shaft 38. In addition, the negative resonance in the optical axis direction and the tracking direction generated in the lens holder 10 is damped by the friction generated between the shaft hole 18 and the rotation shaft 38.

In addition, two winding coils 20 and one magnetic body 16 are fixed to the side of the lens holder 10 at four divided positions of 90 °, and the winding coil 20 is disposed on the inner side of the yoke 30. And the magnets 34 magnetized up and down and the magnets 36 magnetized left and right at positions corresponding to the magnetic body 16, respectively.

The magnets 36 divided by the polarity in the left and right directions are disposed at 180 ° intervals to generate electromagnetic force in the left and right directions in the winding coil 20 under the magnetic flux of the magnet 36, thereby forming the objective lens 12. When a tracking error occurred in the focus of the laser beam, the lens holder 10 was rotated in the tracking direction to correct the tracking error.

In addition, the magnet 34 divided up and down is also disposed at 180 ° to generate an electromagnetic force in the vertical direction in the winding coil 20 under the magnetic flux of the magnet 34, thereby forming the laser beam formed in the objective lens 12. When a focusing error occurs at the focus of the lens holder 10 is moved in the optical axis direction to correct the focusing error.

In addition, the four magnetic bodies 16 fixed to the rear lens holder 10 of the winding coil 20 are attracted to the magnetic flux of the magnets 34 and 36, thereby serving as a suspension that floats the lens holder 10 to a certain height. It was.

Meanwhile, in the conventional optical pickup actuator, since the winding coil 20 has a quadrangular shape, the winding coil 20 receiving magnetic flux of the magnet 34 magnetized up and down uses only the horizontal portion of the quadrangle in the focusing direction. Generate an electromagnetic force. In addition, since the horizontal portion is present in two places in one winding coil 20, the current direction is reversed, and only one portion is used to prevent the electromagnetic force from canceling.

The winding coil 20 receiving magnetic flux of the magnet 36 magnetized to the left and right generates an electromagnetic force in the tracking direction by using a vertical portion of the quadrangle. Here, since the vertical portions are present in two places in one winding coil 20, only one portion is used to prevent the electromagnetic force from canceling due to the opposite direction of the current.

Therefore, the driving force is weak due to the low magnetic flux utilization efficiency, so that sufficient driving force is generated by using eight winding coils 20 and four magnets 34 and 36 to compensate for this. For this reason, the conventional optical pickup actuator has a problem that the assembly productivity is low because the number of parts is excessive and the assembly process is complicated accordingly.

The present invention has been made to improve the conventional problems, an object of the present invention is to magnetize the axis that is the rotation center of the lens holder to drive the coil fixed to the lens holder, thereby reducing the number of parts required for driving the lens holder It is for improving assembly productivity.

1 is an exploded perspective view of a general axial optical pickup actuator.

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

3 is a plan view of a coupling state of the optical pickup actuator shown in FIG.

<Explanation of symbols for main parts of drawing>

110: lens holder 112: objective lens

114: shaft work 116: first horizontal groove

118: second horizontal groove 120: vertical groove

130: first focusing coil 132: second focusing coil

134: first tracking coil 136: second tracking coil

140: York 142: magnetic shaft

144: vertical magnetized portion 146: horizontal magnetized portion

The present invention for achieving the above object, in the optical pickup actuator having a lens holder fixed to the objective lens and the axis hole in the optical axis direction, and a yoke coupled to the lens holder; A magnetic shaft fixed to the yoke and having a vertical magnetized part inserted into the shaft hole and magnetized in a vertical direction and a horizontal magnetized part circumferentially magnetized; First and second horizontal grooves formed in the lens holder at positions corresponding to polarities of the vertical magnetized parts; A first focusing coil and a second focusing coil wound around the first horizontal groove and the second horizontal groove, respectively; A vertical groove formed in the lens holder at a position corresponding to the horizontal magnetized portion; And a first tracking coil and a second tracking coil wound including the vertical groove and the outer circumference of the lens holder at a position corresponding to each polarity of the horizontal magnetized part.

The optical pick-up actuator has a magnetic flux from the north pole of the vertical magnetized part magnetized on the magnetic shaft, passes through the first focusing coil, passes the second focusing coil, and then enters the south pole of the vertical magnetized part. As the emitted magnetic flux passes through the first tracking coil and passes through the second focusing coil and enters the S pole of the horizontal magnetized portion, the lens holder is driven in the focusing direction and the tracking direction.

As described above, the present invention serves as a magnet for driving the first focusing coil or the second tracking coil that drives the lens holder while the magnetic shaft serves as the center of rotation of the lens holder, thereby reducing the number of parts required for driving the lens holder. To improve assembly productivity.

Hereinafter, preferred embodiments of the present invention will be described to facilitate implementation of the present invention.

First, an exploded perspective view of the axis type optical pickup actuator according to the present embodiment is shown in FIG. 2. As shown in this figure, the present embodiment fixes the objective lens 112 and the lens holder 110, the shaft hole 114 in the optical axis direction, and the yoke 140 coupled to the lens holder 110. It is applied to the optical pickup actuator having.

Here, it has a vertical magnetized portion 144 magnetized in the vertical direction and a horizontal magnetized portion 146 magnetized in the circumferential direction, and fixes the magnetic shaft 142 rotatably inserted into the shaft hole 114 to the yoke 140. .

Further, the first horizontal grooves 116 and the second horizontal grooves 118 are formed in the lens holder 110 at positions corresponding to the polarities of the vertical magnetizing portions 144 at two positions of 180 degrees, respectively. The first focusing coil 130 and the second focusing coil 132 are wound around the first horizontal groove 116 and the second horizontal groove 118, respectively. The first focusing coil 130 and the second focusing coil 132 are wound in opposite directions, so that the same direction of magnetic flux passing through the first focusing coil 130 and the second focusing coil 132 is reversed. To generate an electromagnetic force.

Further, vertical grooves 120 are formed in the lens holder 110 at positions corresponding to the horizontal magnetizing portions 146 at positions of 180 °, respectively, and vertical grooves at positions corresponding to the polarities of the horizontal magnetizing portions 146 are respectively formed. The first tracking coil 134 and the second tracking coil 136 are wound, including the outer circumference of the 120 and the lens holder 110. The first tracking coil 134 and the second tracking coil 136 are also wound in opposite directions so that the same direction of the magnetic flux passing through the first tracking coil 134 and the second tracking coil 136 becomes the same. To generate an electromagnetic force.

The magnetic shaft 142 may magnetize the vertical magnetizing portion 144 and the horizontal magnetizing portion 146 to the integral rod as in the present embodiment, respectively, and the vertical magnetizing portion 144 and the horizontal magnetizing portion 146 Each of the divided parts may be manufactured separately and then combined with each other to form a single axis.

Hereinafter, the operation of the optical pickup actuator as described above.

For a description of this action, reference is made to FIG. 3, which shows a plane in the coupled state of the optical pickup actuator. In the optical pickup actuator of the present embodiment, the laser beam focused on the objective lens 112 through an optical system not shown is focused on the recording pit of the disk to reproduce the recording.

If a tracking error or focusing error occurs in the focus of the laser beam during the recording and reproduction, a signal processing unit applies a signal for correcting the tracking error and focusing error to the first focusing coil 130 to the second tracking coil 136. .

Apart from this signal, the magnetic flux from the north pole of the vertical magnetizing portion 144 magnetized to the magnetic shaft 142 passes through the first focusing coil 130 and passes through the second focusing coil 132, and then again the vertical magnetizing part ( Enter the S pole of 144). Therefore, when current is applied to the first focusing coil 130 and the second focusing coil 132, an electromagnetic force is generated in the optical axis direction to drive the lens holder 110 in the optical axis direction.

The magnetic flux from the N pole of the horizontal magnetizing portion 146 passes through the first tracking coil 134 and passes through the second tracking coil 136 to enter the S pole of the horizontal magnetizing portion 146. Therefore, when a current is applied to the first tracking coil 134 and the second tracking coil 136, an electromagnetic force is generated in the tracking direction to rotate the lens holder 110 in the tracking direction about the magnetic axis 142.

Therefore, the lens holder 110 is driven in the focusing direction and the tracking direction about the magnetic axis 142 to correct the focusing error and the tracking error generated in the focus of the laser beam.

Here, the negative resonance generated in the lens holder 110 is reduced by the friction of the shaft hole 114 in contact with the magnetic shaft 142.

As described in the above embodiment, the present invention is fixed to the yoke 140, the vertical magnetized portion 144 inserted into the shaft hole 114 and magnetized in the vertical direction and the horizontal magnetized portion 146 magnetized in the circumferential direction First windings respectively formed in the first horizontal grooves 116 and the second horizontal grooves 118 formed in the lens holder 110 at positions corresponding to the polarities of the respective magnetic shafts 142 and the vertical magnetized portion 144. Including the outer periphery of the vertical groove 120 and the lens holder 110 formed in the lens holder 110 at a position corresponding to the first focusing coil 130 and the second focusing coil 132, the horizontal magnetizing portion 146 An optical pickup actuator including a wound first tracking coil 134 and a second tracking coil 136, wherein the magnetic shaft 142 becomes a center of rotation of the lens holder 110 and simultaneously drives the lens holder 110. By acting as a magnet for driving the first focusing coil 130 to the second tracking coil 136, the lens hole It has the effect of reducing the number of parts needed for driving improve assembly productivity of 110.

Claims (1)

An optical pickup actuator having a lens holder (110) having an objective lens (112) fixed thereto and an axis hole (114) formed in an optical axis direction, and a yoke (140) coupled to the lens holder (110); A magnetic shaft 142 fixed to the yoke 140 and having a vertical magnetized portion 144 inserted into the shaft hole 114 and magnetized in a vertical direction and a horizontal magnetized portion 146 magnetized in the circumferential direction; A first horizontal groove 116 and a second horizontal groove 118 formed in the lens holder 110 at positions corresponding to polarities of the vertical magnetized portions 144; A first focusing coil 130 and a second focusing coil 132 wound around the first horizontal groove 116 and the second horizontal groove 118, respectively; A vertical groove 120 formed in the lens holder 110 at a position corresponding to the horizontal magnetizing portion 146; And The first tracking coil 134 and the second tracking coil 136 wound around the vertical groove 120 and the lens holder 110 at positions corresponding to the polarities of the horizontal magnetizing parts 146, respectively. Optical pickup actuator having a magnetic axis comprising a ;.