KR100207269B1 - A tracking coil adhering jig of shaft sliding actuator - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a tracking coil adhesion jig of an axial perturbation actuator for quickly and accurately attaching a tracking coil to a lens holder of an axial perturbation actuator.

The jig of the present invention includes a fixing part 50 in which a fixing shaft 52 fitted into the shaft hole 92 formed in the lens holder 90 is fixed to an upper surface of the mounting part 54 formed on the base 58, and Rotating portion 70 in which a plurality of fixing protrusions 74 fitted in the winding groove 96 of the tracking coil 94 are formed on the upper surface of the rotating plate 72 hinged to both sides of the base 58 of the fixing portion 50. It is composed of

The present invention can attach the tracking coil 94 to the correct position of the lens holder 90 by the operation of rotating the rotating plate 72, the operation of adhering the tracking coil 94 to the plurality of lens holder 90 The effect is to speed up the process.

Description

Tracking Coil Adhesive Jig of Axial Perturbation Actuator

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a tracking coil bonding jig of an axial perturbation actuator. In particular, the lens holder of the axial perturbation actuator is fixed to a fixed shaft, and the tracking coil is fixed to a swivel plate to apply an adhesive and rotate the swivel plate to the side of the lens holder. The present invention relates to a tracking coil bonding jig of an axial perturbation actuator for attaching a tracking coil to a lens holder accurately and quickly by attaching the tracking coil.

In general, an optical pickup device is a device installed in a CD player for irradiating laser light to the disc and receiving the light reflected from the disc to reproduce the recording contents of the disc. And an objective lens for focusing the laser light emitted from the hologram element on the disk surface. The objective lens must continuously move in the optical axis direction and the tracking direction while correcting the error value in order to form the focus of the laser on the disc. The actuator is used to move the objective lens in the optical axis and tracking direction.

Among the actuators, the lens holder fixing the objective lens moves in the optical axis and the tracking direction about the rotation axis. The axis perturbation actuator includes an objective lens for a compact disk and a digital video disk. And an actuator having both an objective lens for a CD and an objective lens for a CD and an objective lens for a DVD.

FIG. 1 is an axial perturbation actuator having both a CD objective lens 12 and a DVD objective lens 14, wherein the lens holder 10 is rotated and rotated by a rotating shaft 22 provided on the yoke plate 20. It is installed to be movable up and down, and the objective lens 12 for the CD is fixed to one side of the upper surface of the lens holder 10 and is spaced at a predetermined distance from the objective lens 12 for the DVD at the same distance from the rotating shaft 22. The objective lens 14 is fixed, and a hologram element (not shown) is installed below the yoke plate 20 in the vertical direction of the objective lenses 12 and 14 for CD to irradiate laser light. have.

In addition, the tracking coil 16 is wound and bonded to the side of the lens holder 10 so that the lens holder 10 is finely moved in the tracking direction by the magnetic flux of the magnet 24 fixed to the yoke plate 20. The tracking error of the focus formed on the disk in the DVD objective lenses 12 and 14 is corrected, and a focusing coil is wound around the lens holder 10 to fix the yoke plate 20. The lens holder 10 is finely moved in the optical axis direction by the magnetic flux to correct the focusing error.

On the other hand, two tracking coils 16 are attached to both sides of the lens holder 10, so that the lens when the objective lens 12 fixed to the lens holder 10 is positioned in the optical path of the hologram element. The tracking coils 16 on both sides of the holder 10 are positioned in front of the magnet 24 to drive the lens holder 10 by the magnetic flux of the magnet 24 and are fixed to the lens holder 10. When the objective lens 14 is positioned in the optical path of the hologram element, the other tracking coils 16 on both sides of the lens holder 10 are positioned in front of the magnet 24 so that the magnetic flux of the magnet 24 can be obtained. The lens holder 10 is driven by this.

Accordingly, the driving force of the lens holder 10 should be kept constant only when the tracking coil 16 is bonded to the magnetic flux of the magnet 24 efficiently so that the lens holder is coated with the adhesive on the tracking coil 16. It is difficult to adhere to the correct position of 10 so that the working time for accurately bonding the individual tracking coils 16 is long, and the tracking coils 16 are incorrectly bonded so that the driving force of the lens holder 10 is lowered. have.

SUMMARY OF THE INVENTION The present invention has been made to improve the conventional problems, and an object of the present invention is to accurately and quickly adhere the tracking coil to the correct position of the lens holder of the axial perturbation actuator.

The above object is a fixed shaft fitted to the shaft hole formed in the lens holder of the shaft perturbation actuator fixed to the upper surface of the seating portion formed on the base, and tracking on the upper surface of the rotating plate hinged to both sides of the base of the fixing portion It can be achieved by providing a tracking coil bonding jig of the axial perturbation actuator composed of a plurality of rotating projections formed in the winding groove of the coil.

1 is a perspective view showing a general axial perturbation actuator.

Figure 2 is a perspective view showing a tracking coil bonding jig according to the present invention.

3 is a cross-sectional view showing a state of use of the tracking coil bonding jig according to the present invention.

〈Description of the symbols for the main parts of the drawings〉

50: fixed portion 52: fixed shaft

54: seating part 56: guide

58: base 60: hinge axis

70: rotating part 72: rotating plate

74: fixing projection 76: handle

80: fixed cap

Hereinafter, a preferred embodiment of the tracking coil adhesive jig of the axial perturbation actuator according to the present invention will be described in detail with reference to the accompanying drawings.

First, the configuration of this embodiment will be described with reference to FIG. 3.

The fixing part 50 has a seating part 54 on which the lens holder 90 is horizontally mounted, and is formed on an upper surface of the base 58, and both sides of the seating part 54 support the sides of the lens holder 90. The guide 56 is formed to prevent the flow, and the fixed shaft 52 is fitted to the shaft hole 92 of the lens holder 90 in the center of the upper surface of the seating portion 54. In addition, the fixing cap 80 is screwed to the upper end of the fixing shaft 52 in order to prevent the lens holder 90 fitted to the fixing shaft 52 from escaping upward. In addition, rotating grooves 62 are formed at both sides of the base 58, and hinge shafts 60 are installed to cross the rotating grooves 62.

And the rotating part 70 is formed on the upper surface of both rotating plate 72 is formed with two fixing projections 74 fitted in the winding groove 96 formed in the center of the tracking coil 94, each rotating plate 72 Hinge holder 78 is formed on one side of the () is fitted into the rotary groove 62 formed in the base 58 of the fixing portion 50 is rotatably coupled by the hinge shaft 60, and the rotating plate 72 The other side of the handle 76 is formed to conveniently rotate the rotating plate (72).

On the other hand, if the portion to which the tracking coil 94 of the lens holder 90 is bonded has a curvature, the upper surface of the rotating plate 72 corresponding to the curvature of the lens holder 90 has a curvature.

The operation of the tracking coil bonding jig having the above configuration will be described with reference to FIG. 3.

Bonding the tracking coil 94 to both sides of the lens holder 90, first, so that the fixed shaft 52 of the fixing portion 50 is fitted into the shaft hole 92 of the lens holder 90, the lens holder 90 ) Is seated on the upper surface of the seating portion (54). At this time, the guides 56 formed on both sides of the seating part 54 support both sides of the lens holder 90 to prevent the lens holder 90 from rotating about the fixed shaft 52.

Subsequently, by screwing the fixing cap 80 to the upper end of the fixing shaft 52 protruding above the shaft hole 92 of the lens holder 90 to press the upper side of the lens holder 90, the lens holder 90 is upper side. The lens holder 90 is fixed to the upper surface of the mounting portion 54 by preventing the lens holder 90 from being separated.

Next, the winding groove 96 of the tracking coil 94 is formed in the fixing protrusion 74 formed on the upper surface of the rotating plate 72 of the rotating unit 70 rotatably installed on the base 58 of the fixing unit 50. The tracking coil 94 is fixed so as not to flow from side to side on the upper surface of the rotating plate 72, and an adhesive is applied to the upper surface of the tracking coil 94.

In this state, by holding and lifting the handle 76 formed on both sides of the rotating plate 72, the rotating plate 72 rotates about the hinge axis 60 to fix the tracking coil 94 to the rotating plate 72. The side surface of the lens holder 90 fixed to the fixed shaft 52 of the fixing part 50 comes into contact. Therefore, since the adhesive is applied to the upper surface of the tracking coil 94, the tracking coil 94 is adhered to the side of the lens holder 90. When the rotating plate 72 is rotated in the opposite position, the rotating plate 72 is fixed. The protrusion 74 is removed from the winding groove 96 of the tracking coil 94 and the tracking coil 94 remains attached to the lens holder 90. The periphery of the tracking coil 94 is then cured with hardening means to fix the tracking coil 94 to the lens holder 90.

Since the tracking coil 94 is bonded at the correct position of the side of the lens holder 90 in the above, it is possible to quickly attach the tracking coil 94 to the lens holder 90 of another product repeatedly.

As described in the above embodiment, in the present invention, the tracking coil 94 is fixed to the rotating plate 72 while the lens holder 90 is fixed to the fixed shaft 52 and the adhesive is applied to the rotating plate ( 72 is a jig for rotating the tracking coil 94 on both sides of the lens holder 90 by rotating the rotating plate 72. The tracking coil 94 is attached to the correct position of the lens holder 90 by rotating the rotating plate 72. Since the tracking coil 94 can be quickly adhered to the other lens holder 90, the assembly workability of the actuator can be improved.

Claims (4)

In the jig for adhering the tracking coil 94 to the lens holder 90 of the axial perturbation actuator, A fixing part 50 fixed to an upper surface of the seating part 54 formed on the base 58 with a fixing shaft 52 fitted into the shaft hole 92 formed in the lens holder 90, and the fixing part 50. It consists of a rotating part 70 formed with a plurality of fixing protrusions 74 that are fitted to the winding groove 96 of the tracking coil 94 on the upper surface of the rotating plate 72 hinged to both sides of the base 58 A tracking coil bonding jig for axial perturbation actuators. According to claim 1, wherein the fixed shaft 52 of the fixing portion 50 of the axial perturbation actuator, characterized in that the fixing cap 80 is screwed to prevent the lens holder 90 is separated from the upper side Tracking coil adhesive jig. The tracking coil adhesive jig of claim 1, wherein guides 56 are formed on both sides of the seating part 54 of the fixing part 50 to support side surfaces of the lens holder 90. The tracking coil adhesive jig of claim 1, wherein a handle (76) is formed at one end of the rotating plate (72) of the rotating part (70).