KR20010017410A - Optical axis aligning apparatus for pickup - Google Patents

Abstract

PURPOSE: A device for arranging an optical shaft is provided to easily control the optical shaft between a fixing optical system and a moving optical system when a pickup is assembled. CONSTITUTION: To horizontally arrange an optical shaft between a fixing optical system(130) and a moving optical system(120), a rotating cam(161) moves a control bar(160) leftward and rightward by eccentrically rotating. A guide shaft(110) to support the moving optical system(120) is moved leftward and rightward. Thereby, the horizontal position of the moving optical system(120) is controlled for the fixing optical system(130). To vertically arrange the optical shaft, a control screw(162) is tightened or loosened to control a balanced position with a spring. The guide shaft(110) is raised within an elastic transformation range of the spring. Thereby, the vertical position of the moving optical system(120) is controlled. A deviation of the optical shaft is fit again with an optical arranging device though the optical shaft is deviated by a processing error or an assembling error.

Description

Optical axis aligning apparatus for pickup

The present invention relates to an optical axis alignment device of a pickup for aligning the optical axis in a separate pickup in which the optical system is separated into a fixed optical system and a moving optical system.

In general, a disc player that records and reproduces information on a disc such as a compact disc (CD) or digital versatile disk (DVD), as shown in FIG. 1, irradiates light onto the disc 10 and reflects light reflected therefrom. A pickup 12 for recording or reproducing information while receiving light is provided. The pickup 12 moves along the guide rail 13 by mounting the entire optical system including the objective lens 12a, the laser diode 12b, the beam splitter 12c, the photodetector 12d, and the like. It was common to be configured to

Recently, however, a pickup for playing both a CD and a DVD in a single disc player is required. To this end, almost all optical components except for the objective lens 12a and the photo detector 12d should be provided two by two. This is because the format of the CD and DVD is not the same, so the optical systems for each CD must be operated separately. However, if the pickup 12 moves with all the parts doubled in this way, the access speed becomes very slow due to the weight increase. Typically, the access speed is measured by the time taken for the pickup 12 to move 11 mm, which is preferably about 30 msec for high speed access. As the weight increases as described above, the time becomes very slow, such as 80 to 90 msec. .

Therefore, to solve this problem, a separate pickup as shown in FIG. 2 has been proposed. That is, the movable optical system 21 equipped with the objective lens 21a is moved along the guide rail 23 in the radial direction of the disk 20, and light is transmitted to the disk 20 through the objective lens 21. The laser diode 22a for irradiation, the beam splitter 22b, the photodetector 22c, and the like are provided in the fixed optical system 22 fixed to the base 24. Therefore, since only the moving optical system equipped with the minimum optical parts moves, the weight of the moving object is lightened, thereby improving access speed. However, when the pickup is separated into the moving optical system 21 and the fixed optical system 22, the axis of light irradiated from the laser diode 22a toward the objective lens 21a may be distorted. That is, when the optical system is integrated as in the prior art, the optical axis therein is already fixed so as to be accurately irradiated toward the objective lens 21a at the time of assembly of the pickup. Since it is assembled separately, there is a risk that the optical axis is distorted during the assembly process. As such, when the optical axis is distorted, it is impossible to form an optical spot at the correct point of the disk 20, which results in deterioration of data recording and reproducing performance. Therefore, there is a demand for a structure that can easily adjust the optical axis between the fixed optical system 22 and the moving optical system 21 during assembly in the separate pickup.

SUMMARY OF THE INVENTION The present invention has been made in view of the above point, and an object thereof is to provide an optical axis aligning device of a pickup, which makes it possible to easily adjust an optical axis between a fixed optical system and a moving optical system during assembly of the pickup.

1 shows a general structure of a disc player in which the pickup is integrated;

2 is a view showing a general structure of a disc player in which the pickup is configured detachably;

3 is a view showing an internal structure of a disc player having a pickup optical axis alignment device according to the present invention;

4 is a view showing a coupling relationship between the first and second bases shown in FIG. 3;

5 is a view showing the structure of the adjustment bar shown in FIG.

6a to 6c are views for explaining the operation of the adjustment bar shown in FIG.

7 is a view showing a structure for supporting the guide shaft end shown in FIG.

<Description of reference numerals for the main parts of the drawings>

100 ... 1st base 200 ... 2nd base

110 ... Guide shaft 120 ... Moving optics

130 ... Fixed Optics 141 ... Center oak

142 Side yoke 143 Coil

144 magnet 151 screw

152..Spring 153 ... Cam member

160 ... Adjustment bar 161 ... Rotating Cam

162 ... Adjustment screw 163 ... Spring

170 Dish Head Screws

The present invention for achieving the above object, the optical axis is mounted between the moving optical system is mounted along the guide shaft mounted on the base and the fixed optical system fixed to the base to irradiate the light through the objective lens to the disk An optical axis alignment device for pickup, comprising: first adjusting means for moving the guide shaft in a horizontal direction to adjust a lateral relative position of a moving optical system with respect to the fixed optical system; And second adjusting means for moving the guide shaft in a vertical direction to adjust a longitudinal relative position of the moving optical system with respect to the fixed optical system.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

First, Figure 3 shows the internal structure of a disc player employing the optical axis adjusting device according to the present invention. Referring to the drawings, the disc player is provided with a first base 100 on which the moving optical system 120 and the fixed optical system 130 are mounted, and a second base 200 on which the turntable 101 is provided. The first and second bases 100 and 200 are elastically coupled to each other using a plurality of screws 151, springs 152, and cam members 153 as shown in FIGS. 3 and 4. The optical axis adjusting device of the present invention to be described below adjusts the optical axis while moving one end of the guide shaft 110 of the mobile optical system 120 up, down, left, and right, and all of its components are on the first base 100. Since it is provided, this first base 100 will be described below as a base.

As described above, the base 100 is provided with a pair of guide shafts 110 along the radial direction of the disk, and a moving optical system 120 is installed to move on the guide shaft 110. Reference numerals 141 and 142 denote center yokes and side yokes, respectively, reference numeral 144 is a magnet and reference numeral 143 is a coil, and the moving optical system 120 is moved by the electromagnetic force generated by them. In addition, the fixed optical system 130 including the laser diodes 131 and 132 and the photo detector 133 is fixedly installed at one side of the base 100 so that the objective lens 121 of the moving optical system 120 moves as described above. ) Is irradiated with light.

On the other hand, the base 100 is provided with a control bar (160) is slidably installed in a direction perpendicular to the longitudinal direction of the guide shaft (110). As shown in FIG. 5, the adjustment bar 160 is held by putting one end of the guide shaft 110 in the accommodation groove 160c, and when the sliding bar 160 is slid, the one end is moved in the horizontal direction. Reference numeral 165 is a boss formed in the base 100 to be inserted into the long hole 160b formed in the adjustment bar 160, and slidably supports the adjustment bar 160 within the length range of the long hole 160b. Play a role. Reference numeral 164 denotes a screw that is fastened to the boss 165 so that the adjustment bar 160 does not escape upward. A rotation cam 161 is rotatably coupled to the base 100 through a through hole 160a formed at the center of the adjustment bar 160. As shown in FIGS. 6A to 6C, the rotation cam 161 is slightly offset from the center of the body, that is, eccentrically positioned. When the rotation cam 160 is rotated, the rotation cam 160 rotates eccentrically. The adjustment bar 160 is moved to the left and right by pushing the edge of the through hole 160a.

Next, referring to FIG. 5 again, the upper and lower surfaces of one end of the guide shaft 110 may include an adjustment screw 162 supported by the adjustment bar 160 and a spring 163 that is an elastic member supported by the base 100. Stuck in between. The spring 163 provides an elastic force in the direction of lifting the guide shaft 110, the adjustment screw 162 is pressed down the guide shaft 110 in the direction opposite to the elastic force, that is, the spring 163. Accordingly, when the adjusting screw 162 is tightened or released, the guide shaft 110 moves up and down within the elastic deformation range of the spring 163.

Meanwhile, the other end of the guide shaft 110 is disposed between the countersunk head 170 and the side wall of the base 100 in a state where it is placed on the support jaw 103 provided in the base 100 as shown in FIGS. 3 and 7. Supported by being caught in At this time, if the countersunk screw 170 is slightly loosened, the other end of the guide shaft 110 may move to some extent, and the adjustment amount of the guide shaft 110 may be extremely minute, so that the upper and lower left and right sides of the guide shaft 110 may be moved. The end can perform the role of the rotation axis without difficulty.

In the above configuration, when the optical axis between the fixed optical system 130 and the moving optical system 120 is to be aligned left and right, that is, in the horizontal direction, the rotating cam 161 is rotated. Accordingly, as the rotary cam 160 rotates eccentrically, as shown in FIGS. 6A to 6C, the adjustment bar 160 is moved left and right. Then, one end of the guide shaft 110 supporting the moving optical system 120 is moved left and right, so that the horizontal position of the moving optical system 120 with respect to the fixed optical system 130 is adjusted.

In addition, when the optical axis between the fixed optical system 130 and the moving optical system 120 is to be aligned up and down, that is, in the vertical direction, a position that is in equilibrium with the spring 163 while tightening or loosening the adjusting screw 162. Adjust it. Accordingly, one end of the guide shaft 110 is raised and lowered within the elastic deformation range of the spring 163, thereby adjusting the vertical position of the moving optical system 120 with respect to the fixed optical system 130.

Therefore, even if the optical axis is distorted by the processing error or assembly error, the optical axis alignment between the fixed optical system 130 and the moving optical system 120 can be realigned with the optical axis alignment device as described above.

As described above, according to the optical axis aligning device of the pickup according to the present invention, since the optical axis between the fixed optical system and the moving optical system can be aligned even after the assembly is completed, it is possible to correct the distortion of the optical axis due to processing or assembly errors, and This increases the reliability of the recording / playback function of the disc.

It is to be understood that the invention is not limited to that described above and illustrated in the drawings, and that more modifications and variations are possible within the scope of the following claims.

Claims (3)

A pickup optical axis alignment device for aligning an optical axis between a fixed optical system mounted on an object lens and moving along a guide shaft installed in a base and a fixed optical system fixed to the base to irradiate light to the disk through the objective lens, First adjusting means for moving the guide shaft in a horizontal direction to adjust a transverse relative position of the moving optical system with respect to the fixed optical system; And second adjusting means for moving the guide shaft in a vertical direction to adjust the longitudinal relative position of the moving optical system with respect to the fixed optical system. The method of claim 1, The first adjustment means, An adjustment bar which is installed to be movable on the base by holding one end of the guide shaft and has a through hole formed at one side thereof; Rotation is rotatably coupled to the base through the through hole, the center of rotation is eccentrically located in the center of the body to rotate the body inserted in the through hole to move the adjustment bar while pushing the edge of the through hole during rotation Cam; including, And rotating the rotary cam to adjust the horizontal relative position of the moving optical system supported by the guide shaft by moving the adjustment bar. The method according to claim 1 or 2, The second adjustment means, An elastic member installed on the base to elastically support one end of the guide shaft; Including; adjusting screw for pressing one end of the guide shaft toward the elastic member, When the adjusting screw is tightened or loosened, the guide shaft is moved up and down within the elastic deformation range of the elastic member so that the vertical relative position of the moving optical system is adjusted.