KR20000003525A - Damping construction for sliding axis type actuator - Google Patents

Abstract

PURPOSE: Conventional sliding axis type actuator has little damping power toward tracking direction, so lens holder can't be equilibrate the system quickly. This problem is manifest when external impact is applied to this system. CONSTITUTION: Damping structure for sliding axis type actuator is presented to improve the performance of actuator by replaying the records of disk. It is composed of lens holder for sliding axis type actuator for picking up light, yoke, pickup base, and circular groove under pickup base is poured by damping gel. This actuators damping force is magnified, so it enhances the performance of sliding axis type actuator for picking up light.

Description

Damping Structure of Sliding Shaft Optical Pickup Actuator

The present invention relates to a damping structure of a sliding shaft optical pickup actuator, and more particularly, to a damping structure of a sliding shaft optical pickup actuator having a separate damping structure using a damping gel in order to reinforce the tracking damping force, which is a weak point of the sliding shaft actuator. It is about.

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

On the other hand, the rotating shaft 38 is coated with Teflon to reduce the friction coefficient, thereby reducing the loss of rotational force of the lens holder 10 and to be able to rotate or rotate up and down about the rotating shaft 38, the lens holder 10 On the side of the) is fixed two winding coils 20 and one magnetic body 16 in four divided positions at an angle of 90 °, and the winding coil 20 and the inner surface of the yoke 30 By fixing the magnet 34 magnetized up and down and the magnet 36 magnetized left and right at positions corresponding to the magnetic body 16, the winding coil 20 generates an electromagnetic force by the magnetic flux of the magnets 34 and 36. The lens holder 10 was driven.

In the objective lens 12, the magnets 36 divided by the polarity are arranged at 180 ° intervals so that the electromagnetic force is generated in the left and right directions in the winding coil 20 under the magnetic flux of the magnet 36. When a tracking error occurred in the focal point of the formed laser light, the lens holder 10 was rotated in the tracking direction to correct the error. In addition, the magnets 34 whose polarity is divided up and down are also disposed at 180 ° intervals so that the electromagnetic force is generated in the winding coil 20 under the magnetic flux of the magnet 34 in the vertical direction, thereby forming the objective lens 12. When a focus error occurs at the focus of one laser light, the lens holder 10 is moved in the optical axis direction to correct the error.

In addition, the four magnetic bodies 16 are fixed to the rear lens holder 10 of the winding coil 20 to lift the lens holder 10 to a predetermined height by a force attracted to the magnetic flux of the magnets 34 and 36 to raise the lens holder ( 10) was to act as a suspension to have the restoring force up, down, left and right.

Such an actuator is provided with one hologram element in a pickup base moving below the disk, and through the laser passing hole 13 in which the laser light irradiated horizontally from the hologram element is formed in the lens holder 10, the objective lens ( The full mirror changing the light path was fixed so as to be irradiated perpendicularly to 12). Therefore, the disk was regenerated by rotating the lens holder 10 about the rotation axis 38 to position the objective lens 12 fixed to the lens holder 10 in the optical path of the hologram element.

On the other hand, the actuator as described above is mounted on the pickup base to be transportably installed in the disc player, its assembly structure will be described with reference to FIG.

Protruding jaw 82 is formed in the pickup base 80 to guide the circumference of the bottom of the yoke 30, and the verticality of the rotating shaft 38 is corrected while the yoke 30 is seated on the pickup base 80. In order to be able to do so, a tapered circular inclined surface 84 is formed around the through hole 88 through which the laser light passes, and a spherical surface in contact with the inclined surface 84 is formed. The adjustment plate 72 formed in the bottom was fixed to the bottom of the yoke 30. Therefore, the spherical surface of the adjustment plate 72 was made to slide on the inclined surface 84 of the pickup base 80 so that the rotation shaft 38 of the yoke 30 was vertical.

In addition, in order to support the yoke 30 to the pick-up base 80, a catching piece 32 is formed on one side of the yoke 30, and a catching jaw 92 is formed on the pick-up base 80 corresponding to the compression spring. Both ends of the 70 were fixed to the locking piece 32 and the locking step 92, respectively. Then, two through holes 88 are formed in the pickup base 80 on the other side of the inclined surface 84 to form a triangle with the locking jaw 92, and the yoke 30 corresponding to the through holes 88 is formed. By forming a screw hole (not shown) in the bottom surface and passing the two adjusting screws 90 through the through holes 88 and fastening to the respective screw holes, the yoke 30 of the yoke 30 depends on the tightening degree of the adjusting screw 90. Tilt can be adjusted.

Therefore, when installing the actuator yoke 30 to the pickup base 80, the adjustment plate 72 is fixed to the bottom of the yoke 30, and one compression spring 70 and two adjustment screws 90 are used. The yoke 30 is supported on the pickup base 80, and then the two adjustments are made while checking the horizontality of the objective lenses 12 and 14 fixed to the lens holder 10 coupled to the rotating shaft 38 of the yoke 30. By rotating the screw 90 to adjust the inclination of the rotation shaft 38, the objective lens 12 is leveled and then bonded to fix the yoke 30 to the pickup base 80.

On the other hand, the actuator as described above yoke 30 in order to prevent the foreign matter such as the first contact the lens holder 10 from the outside during use, and to prevent the lens holder 10 is separated from the rotation shaft 38 to the upper side. On the upper side of the cover is covered with a cylindrical cover 60 is closed.

The upper surface of the cover 60 forms a lens opening groove 62 through which the objective lens 12 protrudes, and a cutout portion 64 through which the locking piece 32 protrudes. In addition, a plurality of grooves 66 are formed on the side of the cover 60, and projections 33 inserted into the grooves 66 are formed on the side of the yoke 30 to mount the cover 60 to the yoke 30. When the projection 33 of the yoke 30 is elastically inserted into the groove 66 of the cover 60 to prevent the cover 60 from being separated.

On the other hand, in the conventional sliding axis optical pickup actuator as described above, the magnet 34, without providing a separate structure to reduce the negative resonance continuously generated in the lens holder 10 by the impact applied to the actuator from the outside 36) reduced the negative resonance by the force of attracting the magnetic body 16 and the friction force of the lens holder 10 in contact with the rotation axis 38.

By the way, since the rotating shaft 38 coupled to the lens holder 10 is in a vertical direction, the lens holder 10 in contact with the rotating shaft 38 may obtain sufficient frictional force when contacted in the vertical direction. When the lens holder 10 is in contact with the rotating shaft 38 in the direction of rotation, the distance of the moment arm is so close that the friction force is small, the damping force is insufficient.

Therefore, in the conventional sliding axis type optical pickup actuator as described above, the damping force in the tracking direction is weak, so that the sub-resonance in which the lens holder 10 rotates minutely cannot be stabilized quickly, and thus the optical pickup actuator is shocked from the outside. When this is applied, there is a problem that the signal of the disc being played is unstable.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned conventional problems, and includes a damping gel and a damping shaft in a sliding shaft type optical pickup actuator to reinforce the damping force, thereby improving the damping force in the tracking direction, thereby recording the disc. It is to improve the performance of the actuator by regenerating stably.

1 is an exploded perspective view showing a conventional sliding axis type optical pickup actuator.

Figure 2 is a perspective view showing a coupling state of the conventional sliding axis optical pickup actuator.

Figure 3 is an exploded perspective view showing a sliding axis optical pickup actuator according to the present invention.

Figure 4 is a side cross-sectional view of the sliding shaft actuator according to the present invention.

5 is a plan sectional view of a sliding shaft actuator according to the present invention.

<Explanation of symbols for main parts of drawing>

110: lens holder 114: damping shaft

120: winding coil 130: yoke

138: axis of rotation 139,190: long groove

160: cover 180: pickup base

191: damping gel

The present invention provides a lens holder for fixing an objective lens, a winding coil, and a magnetic body to a disc-shaped body, a yoke for fixing a rotating shaft and a magnet coupled to the lens holder, a cover coupled to the yoke to protect the lens holder from an upper side, and In the sliding axis type optical pickup actuator consisting of a pickup base on which the yoke is seated, an arc-shaped long groove is formed on the bottom surface of the yoke and an upper surface of the pickup base, and a damping gel is injected into the long groove of the pickup base. And a damping structure of the sliding shaft type optical pickup actuator, wherein the damping shaft inserted into the long groove is fixed to one side of the holder.

Therefore, the damping shaft fixed to the lens holder is damped in contact with the damping gel in the long groove formed in the pickup base. In particular, the tracking direction damping force of the lens holder is improved, so that the recording of the disc is stably reproduced, thereby improving the performance of the actuator.

Hereinafter, the present invention will be described in detail by describing a preferred embodiment of the sliding shaft type optical pickup actuator having the dangping structure as described above.

3 and 4, the optical pickup actuator to which the damping structure of the present invention is applied has a lens holder 110 in which an objective lens 112, a winding coil 120, and a magnetic body 116 are fixed to a disk-shaped body. And a yoke 130 fixing the rotation shaft 138 coupled to the lens holder 110 and the magnets 134 and 136, and a cover 160 coupled to the yoke 130 to protect the lens holder 110 from an upper side. And the pickup base 180 on which the yoke 130 is seated.

The lens holder 110 fixes the objective lens 112 by penetrating the laser passage hole 113 up and down in the outer circumference of the body, and fixes the plurality of winding coils 120 and the magnetic body 116 on the outer circumferential surface. . In addition, the yoke 130 fixes the rotation shaft 138 coupled to the shaft hole 118 formed in the lens holder 110 at the center thereof, and fixes the magnets 134 and 136 to correspond to the winding coil 120 and the magnetic body 116. Fix it.

The rotating shaft 138 is coated with Teflon to reduce the friction coefficient, thereby reducing the loss of rotational force of the lens holder 110, and to rotate or rotate up and down about the rotating shaft 138, the of the lens holder 110 On the side, two winding coils 120 and one magnetic body 116 are fixed at four divided positions at an angle of 90 °, and the winding coils 120 and the magnetic body (on the inner side of the yoke 130). The magnet 134 magnetized up and down and the magnet 136 magnetized to the left and right at positions corresponding to 116 are respectively fixed so that the winding coil 120 generates an electromagnetic force by the magnetic flux of the magnets 134 and 136 so that the lens holder 110 is fixed. ) Is driven.

In the objective lens 112, the magnets 136 having the polarity divided in the left and right directions are arranged at 180 ° intervals so that the electromagnetic force is generated in the left and right directions in the winding coil 120 applied by the magnetic flux of the magnet 136. When a tracking error occurs in the focus of the formed laser light, the lens holder 110 is rotated in the tracking direction to correct the error. In addition, the magnet 134 having the polarity divided up and down is also arranged at intervals of 180 ° so that an electromagnetic force is generated in the winding coil 120 applied by the magnetic flux of the magnet 134 in the vertical direction, thereby forming the objective lens 112. When a focus error occurs at the focus of one laser light, the lens holder 110 is moved in the optical axis direction to correct the error.

In addition, the four magnetic bodies 116 are fixed to the rear lens holder 110 of the winding coil 120 to lift the lens holder 110 to a predetermined height by a force attracted to the magnetic flux of the magnets 134 and 136 so that the lens holder 110 is fixed. It is to act as a suspension to have the resilience of up, down, left and right.

Such an actuator is provided with one hologram element in a pickup base moving below the disk, and through the laser passing hole 113 formed by the laser light irradiated horizontally from the hologram element on the lens holder 110, the objective lens ( Fix the full mirror changing the light path so that it is irradiated perpendicularly to 112). Therefore, the disk is regenerated by rotating the lens holder 110 about the rotation axis 138 to position the objective lens 112 fixed to the lens holder 110 in the optical path of the hologram element.

In addition, the cover 160 prevents foreign matter such as dust from contacting the lens holder 110 from the outside during use, and the yoke 130 to prevent the lens holder 110 from escaping upward from the rotation shaft 138. Put on the upper side of).

The upper surface of the cover 160 forms a lens opening groove 162 through which the objective lens 112 protrudes, and a plurality of grooves 166 are formed on the side surface of the cover 160 and inserted into the groove 166. When the protrusion 133 is formed on the side surface of the yoke 130 to mount the cover 160 to the yoke 130, the protrusion 133 of the yoke 130 elastically moves to the groove 166 of the cover 160. Is inserted to prevent the departure of the cover 160.

In addition, the pickup base 1180 is for installing the actuator such as to transfer to the disc player, the pickup base 180 is formed with a projection jaw 182 for guiding the bottom circumference of the yoke 130, In order to be able to correct the verticality of the rotating shaft 138 in a state where the 130 is seated on the pickup base 180, the through-hole 188 through which the laser light passes through the projection jaw 182 is centered. The tapered circular inclined surface 184 was formed, and the adjustment plate 172 which formed the spherical surface which contacted this inclined surface 184 in the bottom was fixed to the bottom of the yoke 130. As shown in FIG. Therefore, the spherical surface of the adjustment plate 172 is made to slide on the inclined surface 184 of the pickup base 180 so that the rotation axis 138 of the yoke 130 is vertical.

In addition, in order to support the yoke 130 to the pick-up base 180, a hook piece 132 is formed on one side of the yoke 130, and a hooking jaw 192 is formed on the pick-up base 180 corresponding to the compression spring. Both ends of the 170 are fixed to the locking piece 132 and the locking step 192, respectively. In addition, two through holes 188 are formed in the pickup base 180 on the other side of the inclined surface 184 to form a triangle with the locking jaw 192, and the yoke 130 corresponding to the through holes 188 is formed. A screw hole (not shown) is formed on the bottom surface, and two adjusting screws are passed through the through holes 188 and fastened to the respective screw holes, so that the inclination of the yoke 130 can be adjusted according to the tightening degree of the adjusting screw. It was.

Therefore, when installing the yoke 130 of the actuator to the pickup base 180, the adjustment plate 172 is fixed to the bottom of the yoke 130, using one compression spring 170 and two adjustment screws 190 The yoke 130 is supported on the pick-up base 180, and then the horizontal adjustment of the objective lens 112 fixed to the lens holder 110 coupled to the rotation shaft 138 of the yoke 130 is performed. By rotating the 190 and adjusting the inclination of the rotation shaft 138, the objective lens 112 is horizontal, and then bonded to fix the yoke 130 to the pickup base 180.

In order to improve the damping force in the tracking direction of the lens holder 110, arc-shaped long grooves 139 and 190 are formed on the bottom surface of the yoke 130 and the top surface of the pickup base 180, respectively. The damping gel 191 is injected into the long groove 190 of the 180, and the damping shaft 114 inserted into the long grooves 139 and 190 is fixed to one side of the bottom surface of the lens holder 110. The damping gel 191 uses a good viscosity gel to damp the damping shaft 114 in contact with the damping gel 191.

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

The laser light irradiated horizontally from the hologram element installed in the pickup base is vertically reflected by the full mirror and irradiated perpendicularly to the objective lens 112 through the laser passage hole 113 of the lens holder 110. As a result, the laser light that has passed through the objective lens 112 is focused on the disk to reproduce the recording.

When a tracking error occurs at the focal point of the laser light formed by the objective lens 112 during reproduction of the disc, power is applied to the winding coil 120 applied by the magnetic flux of the magnet 136 whose polarity is divided left and right in the left and right direction. By generating an electromagnetic force, the lens holder 110 is rotated in the tracking direction to correct the tracking error. In addition, when a focusing error occurs at the focus of the laser light, power is applied to the winding coil 120 of the magnetic flux of the magnet 134 having the polarity divided up and down so that an electromagnetic force is generated in the vertical direction. Direction to correct the focus error of the laser light.

As described above, when a shock is applied to the actuator from the outside during recording of the disc, negative resonance in which the lens holder 112 continuously vibrates occurs. As shown in FIG. The damping shaft 114 fixed to the lens holder 110 is partially reduced by friction generated in the contacting rotating shaft 138, and the damping shaft 114 fixed to the lens holder 110 is formed in the pickup base 180 through the long hole 139 of the yoke 130. Most of the disappearance by vibrating in the damping gel 191 in the sheet groove 190. In particular, the vibration of the lens holder 110 in the tracking direction which cannot be reduced in the rotation axis 138 is rapidly reduced by the viscosity of the damping gel 191.

Therefore, the lens holder 110 and the objective lens 112 fixed to the lens holder 110 are stabilized quickly, so that the recording of the disc can be satisfactorily reproduced.

As described in the above embodiments, the present invention forms arc-shaped long grooves 139 and 190 on the bottom surface of the yoke 130 and the top surface of the pickup base 180 of the sliding shaft type optical pickup actuator, respectively. The damping gel 191 is injected into the long groove 190 of the 180, and the damping shaft 114 inserted into the long grooves 139 and 190 is fixed to one side of the bottom surface of the lens holder 110, and to the lens holder 110. The fixed damping shaft 114 is damped in contact with the damping gel 191 in the long groove 190 formed in the pickup base 180, so that the damping force is improved, particularly in the tracking direction, thereby stably reproducing the recording of the disc. Has the effect of improving performance.

Claims (1)

A lens holder 110 fixing the objective lens 112, the winding coil 120, and the magnetic body 116 to the disc-shaped body, and a yoke fixed to the rotation shaft 138 and the magnets 134 and 136 coupled to the lens holder 110. Sliding shaft optical pickup actuator consisting of a 130, a cover 160 coupled to the yoke 130 to protect the lens holder 110 from the upper side, and the pickup base 180 on which the yoke 130 is seated To Arc-shaped long grooves 139 and 190 are formed on the bottom surface of the yoke 130 and the upper surface of the pickup base 180, and the damping gel 191 is injected into the long groove 190 of the pickup base 180. A damping structure of a sliding shaft type optical pickup actuator, characterized in that the damping shaft 114 is fixed to one side of the bottom surface of the lens holder 110 to be inserted into the long grooves (139, 190).