KR20000004873A - Optical pickup device - Google Patents

Abstract

PURPOSE: An optical pickup device is provided to make an optical beam be incidence and be reflected on/from a record medium by adjusting a slope of a beam axis. CONSTITUTION: The optical pickup device comprises: a base plate(210) installed so as to be rotatable against a fixing base(200); a bobbin(230) loaded on the base plate and movably supported by a predetermined wire; an object lens(190) loaded on the bobbin, for focusing an incidence optical beam so that an optical spot is generated on a record medium; a focusing coil(260) installed at the bobbin, for forming a current path for focusing; a first magnet and a first yoke(240) installed at the base plate, for generating an electromagnetic force driving the bobbin by forming a magnetism in a perpendicular direction to a current which flows the focusing coil; a fixing optical system(100) for irradiating an optical beam toward the record medium and collecting an optical light incident through the object lens and reflected from the record medium; a reflection mirror(180) installed at the base plate so as to be disposed between the object lens and the fixing optical system, for changing a progressive path; a support arm(182) having one end fixed to the fixing base and the other end supporting the reflection mirror so as to be rotatable; and a tilt unit(430) for rotating the base plate by use of the support arm as the rotating axis to adjust a slope of the optical axis through the object lens and the reflection mirror.

Description

Optical pickup device

The present invention relates to an optical pickup apparatus for recording information by reading light onto a recording medium and reading information therefrom.

In general, an optical disc recorder / player for recording and reproducing information using an optical disc as a recording medium, such as a disc player, includes an optical pickup device for irradiating light onto an optical disc as a recording medium and reading information from the reflected light. have. In the conventional optical pickup device, as shown in Fig. 1 and 2, the base plate 21 is mounted on the fixed base 20, the objective block is provided on the fixed block 22 provided in the base plate 21 The bobbin 23 on which the 19 is mounted is supported by the wire 28 so that it can flow. The bobbin 23 has a focusing coil 26 for adjusting the focus of an optical spot formed on the optical disc 30 while moving the objective lens 19 in the vertical direction, and a track in which the optical spot is formed on the optical disc 30. A tracking coil 27 is provided to move the objective lens 19 in the horizontal direction so as to accurately follow (not shown). The bobbin 23 is formed by the interaction between the current flowing through the focusing coil 26 and the tracking coil 27 and the magnetic field formed by the magnet 25 and the yoke 24 provided in the base plate 21. ) Is moved by the electromagnetic force. In addition, a reflecting mirror 18 for converting an optical path is provided below the objective lens 19, and irradiates light onto the optical disc 30 via the reflecting mirror 18 and reflects off the optical disc 30. The fixed optical system 10 which receives the processed light is provided. As shown, this fixed optical system 10 includes a light source 11, a beam splitter 13, a collimated lens 14, a detection lens 15, a photodetector 12, and the like. . In addition, the fixed base 20 and the base plate 21 are in contact with a bottom surface formed in a hemispherical shape, and are fastened to each other by a plurality of adjustment screws 41, 42, 43, so that the adjustment screws 41 ( While tightening the 42 and 43, the inclination of the base plate 21 with respect to the fixed base 20 is adjusted. This is because when the axis of the light incident on the optical disk 30 through the objective lens 19 is distorted, that is, when the light is not incident perpendicularly to the optical disk 30 and is arranged to be incident from the optical disk 30, the adjusting screw in the assembling process. (41) (42) It is a structure for correcting the distortion, while adjusting the tightening degree of 43. Reference numeral 50 denotes a controller for controlling the focusing and tracking operations and the like, and reference numeral S denotes a compression spring.

However, not only the assembly as described above, but also the recording / reproducing operation may be inclined to one side due to the vibration of the optical disc 30, and the optical disc 30 may not be horizontal even due to the time-dependent deformation of the optical disc 30 itself. have. However, the conventional optical pickup apparatus described above has a disadvantage in that it cannot cope with such a change. That is, although the distortion of the optical axis C can be corrected at the time of assembling, the optical axis C which is generated during the recording / reproducing operation of the optical disc 30 after the assembly is completed can not be coped with. In this case, sufficient central light intensity cannot be obtained during recording, and information cannot be reproduced cleanly due to deterioration of the reproduction signal during reproduction.

The present invention has been made in view of the above problems, and by adjusting the tilt of the optical axis of the incident and reflected light beams through the reflection mirror and the objective lens in response to the tilting of the recording medium, the light beam is always perpendicular to the recording medium. It is an object of the present invention to provide an optical pickup device having a structure improved to be reflected.

1 is a cross-sectional view schematically showing the structure of a conventional optical pickup device;

2 is a plan view of FIG.

3 is a cross-sectional view showing the structure of an optical pickup apparatus according to a first embodiment of the present invention;

4 is a plan view of FIG.

5 is a main part perspective view of FIG. 3;

6 and 7 are views for explaining the tilt operation principle of the optical pickup device shown in FIG.

8 to 10 are views for explaining that the optical pickup device shown in Figure 3 corresponds to the inclination of the optical disk,

11 is a perspective view showing the structure of an optical pickup device according to a second embodiment of the present invention;

12 is a cross-sectional view of FIG. 11,

FIG. 13 is a plan view of FIG. 11;

14 and 15 are views for explaining a focusing operation of the optical pickup device shown in FIG.

16 and 17 are views for explaining that the optical pickup device shown in FIG. 11 corresponds to the inclination of the optical disc;

18 is an exploded perspective view showing an optical pickup device according to a third embodiment of the present invention;

19 is a perspective view of the combination of FIG.

FIG. 20 is a diagram for explaining that an optical pickup apparatus shown in FIG. 18 corresponds to an optical disk inclination. FIG.

<Description of Symbols for Major Parts of Drawings>

100,100a ... Fixed Optics 180,180a ... Reflection Mirrors

181,181a ... Combination rod 182,182a ... Support arm

190,190a ... Objective lens 200,200a ... Fixed base

210,210a ... Baseplate 201a ... Boss

220 ... fixed block 230, 230a ... bobbin

240,240a ... 1st yoke 250,250a ... 1st magnet

260,260a ... Focusing coil 280 ... Wire

300,300a ... optical disk 410,410a ... second yoke

420,420a ... Secondary magnet 430,430a ... Tilt coil

The optical pickup device of the present invention for achieving the above object, a fixed base; A base plate rotatably installed with respect to the fixed base; A bobbin seated on the base plate and movably supported by a predetermined wire; An objective lens mounted on the bobbin and focusing the incident light beam to form a light spot on the recording medium; A focusing coil installed in the bobbin and forming an energization path for current for focusing; A first magnet and a first yoke installed on the base plate to generate an electromagnetic force for driving the bobbin by forming a magnetic field in a direction perpendicular to a current flowing through the focusing coil; A fixed optical system that irradiates a light beam toward the recording medium, and receives the light reflected from the recording medium and incident through the objective lens; A reflection mirror fixed to the base plate so as to be disposed between the objective lens and the fixed optical system, and converting a traveling path of incident light; A support arm having one end fixed to the fixed base and the other end rotatably supporting the reflective mirror, thereby forming a rotational axis of the base plate to which the reflective mirror is fixed; And tilting means for adjusting the inclination of the optical axis passing through the objective lens and the reflecting mirror by rotating the base plate with the support arm as the pivot axis.

In addition, the optical pickup device according to another aspect of the present invention, the fixed base; A base plate rotatably installed with respect to the fixed base; A hollow boss protruding from the base plate; A bobbin liftably coupled to the boss; An objective lens mounted on the bobbin and focusing an incident light beam to form a light spot on a recording medium; A focusing coil installed in the bobbin and forming an energization path for current for focusing; A first magnet and a first yoke installed on the base plate to generate an electromagnetic force for driving the bobbin by forming a magnetic field in a direction perpendicular to a current flowing through the focusing coil; A fixed optical system that irradiates a light beam toward the recording medium, and receives the light reflected from the recording medium and incident through the objective lens; A reflection mirror fixed to the base plate so as to be disposed between the objective lens and the fixed optical system and converting a traveling path of the light beam; A support arm having one end fixed to the fixed base and the other end rotatably supporting the reflective mirror, thereby forming a pivotal axis of the base plate on which the reflective mirror is fixed; And tilting means for adjusting the inclination of the optical axis passing through the objective lens and the reflecting mirror by rotating the base plate with the support arm as the pivot axis.

In addition, the optical pickup device according to another aspect of the present invention, the fixed base; A rotation block rotatably installed on the fixed base; A holder integrally coupled with the pivot block; A bobbin movably supported by the holder by a predetermined wire; A base plate fixed to the fixed base to be positioned between the pivot block and the bobbin; An objective lens mounted on the bobbin and focusing an incident light beam to form a light spot on a recording medium; A focusing coil and a tracking coil installed in the bobbin to form an energization path for current for focusing and tracking; A first magnet and a first magnet installed in the base plate so as to face the focusing coil and the tracking coil and generating an electromagnetic force for driving the bobbin by forming a magnetic field in a direction perpendicular to a current flowing through the focusing coil and the tracking coil. Outer yoke; A fixed optical system that irradiates a light beam toward the recording medium, and receives the light reflected from the recording medium and incident through the objective lens; A reflection mirror installed at the rotation block so as to be disposed between the objective lens and the fixed optical system and converting a traveling path of incident light; And tilting means for adjusting the inclination of the optical axis through the objective lens and the reflecting mirror by rotating the pivoting block.

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

3 to 10 show an optical pickup apparatus according to a first embodiment of the present invention, which illustrates a type in which a bobbin is supported by a wire.

First, referring to FIGS. 3 to 5, the base plate 210 is disposed on the fixed base 200, and the bobbin 230 is formed on the base plate 210 by a wire 280 connected to the fixing block 220. It is fluidly supported. The bobbin 230 is equipped with an objective lens 190 for focusing the incident light beam to form a light spot on a recording medium such as an optical disc 300, and focusing coil 260 to form a current carrying path for focusing operation. Each of these is installed. In addition, the base plate 210 forms a magnetic field in a direction perpendicular to the current flowing through the focusing coil 260 to generate the first magnet 250 and the first yoke, which generate electromagnetic force for driving the bobbin 230. 240 is installed. In addition, there is provided a fixed optical system 100 for irradiating a light beam and receiving and processing light reflected from the optical disk 300. The fixed optical system 100 includes a light source 110, a beam splitter 130, a collimated lens 140, a detection lens 150, a photodetector 120, and the like. A reflection mirror 180 is provided between the objective lens 190 and the fixed optical system 100 to convert a traveling path of incident light. The reflection mirror 180 is fixedly installed on a pair of arms 211 extending from the base plate 210 so as to move integrally with the base plate 210. In addition, a predetermined coupling rod 181 is provided on an arm of the pair of arms 211 surrounding the rear surface of the reflection mirror 180, and the coupling rod 181 is a support arm fixed to the fixed base 200. 182 is rotatably coupled. Therefore, the support arm 182 functions to support the entire base plate 210 including the reflective mirror 180 with respect to the fixed base 200, and at the same time rotatably support the reflective mirror 181. Since the base plate 210 also serves as a pivot.

In addition, tilting means for adjusting the inclination of the optical axis C through the objective lens 190 and the reflection mirror 180 by rotating the base plate 210 is provided. The tilt means is installed on the outer surface of the first yoke 240 to form a current passing path of the current, and the tilting coil 430 is installed in the fixed base 200 flows in the tilt coil 430 It comprises a second magnet 420 and the second yoke 410 for generating an electromagnetic force for rotating the base plate 210 by forming a magnetic field in a direction perpendicular to the current. Here, the tilt coil 430 is symmetrically arranged in pairs on one side and the other side with respect to the bobbin 230 and is installed to face the second magnet 420, respectively, and the second magnet 420 and Assuming that they are stacked, as shown in Figs. 6 and 7, only the inner vertical portion is arranged to overlap. In this state, when a current flows through each pair of tilt coils 430 in the direction shown in FIG. 6, the influence of the current in the horizontal direction cancels each other in the coil and the current I flowing in the vertical direction and the The electromagnetic force is generated in the direction of arrow F by the interaction with the magnetic field B by the second magnet 420, so that the base plate 210 is formed around the support arm 182 coupled to the coupling rod 181. Turn clockwise. On the contrary, when a current flows in the tilt coil 430 in the direction shown in FIG. 7, an electromagnetic force is generated in the direction of arrow F by the interaction with the magnetic field B by the second magnet 420, and thus the base plate 210. Rotates counterclockwise. Therefore, the direction of rotation of the base plate 210 can be controlled by controlling the direction of the current flowing through the tilt coil 430. Reference numeral 500 in the drawing denotes a controller that controls the current control of the tilt coil 430 and the focusing coil 260.

In the above configuration, when the optical disk 300 to be recorded / reproduced as shown in FIG. 8 is horizontal, no current flows in the tilt coil 430, and thus the base plate 210 is not rotated, but is in a horizontal state. Keep it. In this state, a focusing operation by the focusing coil 260, the first magnet 250, and the first yoke 240 is performed.

When the optical disc 300 is inclined to the right side as shown in FIG. 9, current flows from the controller 500 to the tilt coil 430 as shown in FIG. 6, and the objective lens 190 and the reflection mirror ( The base plate 210 is rotated clockwise so that the optical axis C through the 180 is incident perpendicularly to the optical disc 300. That is, by rotating the base plate 210 inclined as much as the optical disc 300 is inclined, the optical axis C is adjusted so as to be perpendicular to the optical disc 300.

Similarly, when the optical disc 300 is inclined to the left side as shown in FIG. 10, the base plate 210 is rotated counterclockwise by flowing a current through the tilt coil 430 as shown in FIG. 7.

As described above, the base plate 210 is rotated in response to the tilt of the optical disc 300 to dynamically compensate for the distortion of the optical axis C passing through the objective lens 190 and the reflection mirror 180.

On the other hand, in the optical pickup apparatus of the present invention, it is possible to perform the tracking operation by using the above-described tilting means. That is, the optical axis C is microscopically moved while the base plate 210 is rotated by the electromagnetic force of the tilt coil 430 and the second magnet 420 for tracking. Therefore, the optical axis C is adjusted macroscopically in accordance with the tilting of the optical disc 300 through the above tilting operation, and then the optical axis is tracked of the optical disc 300 while microscopically rotating the base plate 210 at the position. It is to perform tracking operation to follow. In the normal tilt operation, the rotation angle of the optical axis C proceeds in the range of about ± 1 °, and in tracking, the rotation angle proceeds in the minute range of about ± 0.25 °. Therefore, the tracking operation can be performed even without a separate tracking coil and magnet.

Next, FIGS. 11 to 17 illustrate an optical pickup apparatus according to a second embodiment of the present invention, in which a bobbin is not supported by a wire as in the previous embodiment, but is inserted into a predetermined boss to be slidably moved in the axial direction. It is an example of the axial movement type.

First, referring to FIGS. 11 to 13, a predetermined base plate 210a is rotatably installed with respect to the fixed base 200a. The pivot support structure will be described later. The bobbin 230a equipped with the objective lens 190a is coupled to the hollow boss 201a formed on the base plate 210a. The bobbin 230a can be independently lifted in the state coupled to the boss 201a, but is restrained in the horizontal direction. Therefore, when the bobbin 230a moves in the horizontal direction, the entire base plate 210a must move together. In addition, the bobbin 230a is provided with a focusing coil 260a constituting an energization path of a current for focusing operation, and the base plate 210a forms a magnetic field in a direction perpendicular to the current flowing through the focusing coil 260a. As a result, a first magnet 250a and a first yoke 240a for generating an electromagnetic force for driving the bobbin 230a are provided. Reference numeral 261a denotes an iron piece for focusing the magnetic flux. In addition, the first magnet 250a and the focusing coil 260a are disposed to face each other, and are arranged to overlap each other when overlapped with each other as shown in FIGS. 14 and 15. In the first magnet 250a, two magnets having opposite polarities are arranged up and down, thereby forming magnetic fields in opposite directions. In this state, when a current flows through the focusing coil 260a as shown in FIG. 14, the electromagnetic force according to the left hand rule of Fleming acts in the upward direction. Therefore, at this time, the bobbin 230a is raised by the electromagnetic force. On the contrary, when a current flows through the focusing coil 260a as shown in FIG. 15, the electromagnetic force acts in the downward direction and the bobbin 230a descends.

On the other hand, there is provided a fixed optical system 100a for irradiating a light beam toward the optical disk 300a and receiving and processing the light reflected from the optical disk 300a. The fixed optical system 100a includes a light source 110a and a beam splitter. 130a, a collimated lens 140a, a detection lens 150a, a photodetector 120a, and the like. A reflection mirror 180a is provided between the objective lens 190a and the fixed optical system 100a to convert a traveling path of incident light. The reflecting mirror 180a is fixed to a pair of arms 211a extending from the base plate 210a so as to move integrally with the base plate 210a. In addition, a predetermined coupling rod 181a is provided on an arm surrounding the rear surface of the reflective mirror 180a of the pair of arms 211a, and the coupling rod 181a is a support arm fixed to the fixed base 200a. Rotatably coupled to 182a). Therefore, the support arm 182a functions to support the entire base plate 210a including the reflective mirror 180a with respect to the fixed base 200a, and at the same time rotatably support the reflective mirror 181a. Since the base plate 210a also serves as a pivot.

A tilting means for adjusting the inclination of the optical axis C through the objective lens 190a and the reflecting mirror 180a is provided by rotating the base plate 210a. The tilt means includes a tilt coil 430a installed on the side surface of the bobbin 230a and a base installed in the fixed base 200a to form a magnetic field in a direction perpendicular to a current flowing through the tilt coil 430a. The second magnet 420a and the second yoke 410a which generate electromagnetic force for rotating the plate 210a are configured to be included. Here, the tilt coil 430a is symmetrically arranged in pairs on one side and the other side with respect to the bobbin 230a to be installed to face the second magnet 420a, respectively, and the second magnet 420a and Assuming that they are stacked, as shown in Figs. 16 and 17, only the inner vertical portion is arranged to overlap. Reference numeral 500a in the drawing denotes a controller that controls current control of the tilt coil 430a and the focusing coil 260a.

In the above configuration, when the optical disc 300a is horizontal, no current flows through the tilt coil 430a, and thus the base plate 210a is also maintained in a horizontal state. In this state, the focusing operation by the focusing coil 260a, the first magnet 250a, and the first yoke 240a is performed.

However, when the optical disk 300a is inclined to the right as shown in FIG. 16, current flows through the tilt coil 430a as shown in the controller 500a. At this time, the influence of the current in the horizontal direction cancels each other in the coil 430a, and the arrow is caused by the interaction between the current I flowing in the vertical direction and the magnetic field B by the second magnet 420a. The electromagnetic force is generated in the F direction, and the base plate 210a is rotated clockwise about the support arm 182a coupled to the coupling rod 181a. That is, by rotating the base plate 210a inclined as much as the optical disc 300a is inclined, the optical axis C is adjusted so as to be perpendicular to the optical disc 300a.

On the contrary, when the optical disc 300a is inclined to the left side as shown in FIG. 17, current flows to the tilt coil 430a in the illustrated direction. Accordingly, the electromagnetic force is generated in the direction of the arrow F by the interaction with the magnetic field B by the second magnet 420a so that the base plate 210a returns to the counterclockwise direction. Therefore, by adjusting the direction of the current flowing through the tilt coil (430a) to control the rotation direction of the base plate 210a to dynamically compensate for the distortion of the optical axis (C) through the objective lens 190a and the reflecting mirror (180a) It can be.

On the other hand, the optical pickup device of the present embodiment can also perform a tracking operation by using the above-described tilting means. That is, the optical axis C is microscopically moved while the base plate 210a is rotated by the electromagnetic force of the tilt coil 430a and the second magnet 420a for tracking. Therefore, the optical axis C is adjusted macroscopically in accordance with the tilting of the optical disc 300a through the above tilting operation, and then the optical axis is tracked of the optical disc 300a by microscopically rotating the base plate 210a at the position. It is to perform tracking operation to follow. Therefore, even in this embodiment, the tracking operation can be performed without a separate tracking coil and magnet.

18 to 20 illustrate an optical pickup apparatus according to a third embodiment of the present invention, which illustrates a type in which a tracking coil and a tilt coil are separately provided.

First, referring to FIGS. 18 and 19, the base plate 700 is fastened by a screw S on the fixed base 500 on which the fixed optical system 900 is installed. The fixed optical system 900 includes the same components as the first and second embodiments described above. The base plate 700 has a first magnet 730 and a first inner and outer yoke 710 (which generates an electromagnetic force for driving the bobbin 800 by interacting with the focusing coil 820 and the tracking coil 830) ( 720 is provided. The first magnet 730 and the first inner and outer yoke 710 and 720 are always maintained in a fixed state because the base plate 700 is fastened to the fixed base 500 by a screw S. . On the other hand, the fixed base 500 is provided with a rotatable block 600 mounted with a reflection mirror 610 to be rotatable. That is, the rotation protrusions 601 and 602 provided on the front and rear surfaces of the rotation block 600 are inserted into the coupling holes 501 and 502 formed in the fixed base 500 to be rotatably supported. In the pivoting projection 601 provided on the front surface thereof, a hole 601a penetrates to the reflection mirror 610, so that the light emitted from the fixed optical system 900 passes through the hole 601a. ) Is reached. In addition, a pair of tilt coils 621 and 622, a second magnet 630, and a second inner and outer yoke 650 and 640 are provided at both sides of the pivot block 600 as tilting means, respectively. . They generate an electromagnetic force for rotating the pivot block 600 about the pivot X shown in FIG. 19, and a pair of tilt coils 621 are assumed to overlap each other as shown in FIG. The center portion of the 622 overlaps with the second magnet 630. Reference numerals 623 and 624 denote iron pieces provided in the centers of the tilt coils 621 and 622 so that the second magnet 630 and the attraction force act, and when the current does not flow in the tilt coils 621 and 622, the second magnets. By balancing the vertical force of 600 and the magnetic force serves to maintain the equilibrium position of the rotation block (600). Accordingly, the iron pieces 623 and 624 are symmetrically installed up and down with respect to the magnetic force of the second magnet 630. In addition, a holder 850 supporting the bobbin 800 with the wire 840 is coupled to the rotation block 600. That is, the coupling protrusion 851 formed on the lower surface of the holder 850 is fitted into the coupling groove 603 formed on the upper surface of the rotation block 600 to be fixed to each other integrally. Therefore, when the rotating block 600 is rotated, the holder 850 and the bobbin 800 supported thereon are rotated together. On the other hand, the bobbin 800 is provided with an objective lens 810, a focusing coil 820 and a tracking coil 830. As the focusing coil 820 and the tracking coil 830 are coupled to the rotating block 600, the first magnet 730 provided in the base plate 700 is illustrated in FIG. 19. ) And the first inner and outer yoke 710 (720). Therefore, the bobbin 800 is connected to the wires due to the current flowing through the focusing coil 820 and the tracking coil 830 and the magnetic force lines of the first magnet 730 and the first and the outer yoke 710 and 720. It moves in a state supported by the 840, thereby performing the focusing and tracking operation of the objective lens 810.

In the above configuration, the tilting block 600 is rotated by the tilting means in order to match the perpendicularity between the optical axis through the objective lens 810 and the optical disk (not shown). That is, when the current I flows through the tilt coils 621 and 622 provided at one side of the rotation block 600, as shown in FIG. 20, the magnetic field lines B by the second magnet 630 and Due to the interaction of the electromagnetic force (F) in the upward direction is generated. At this time, when the electromagnetic force is generated in the downward direction by flowing a current in the opposite direction to the tilt coil, the rotating block 600 returns to the center of the rotating shaft (X). Of course, when the current flows in the tilt coil of the one side and the other side as opposed to the above example, the rotation block 600 is returned to the opposite direction.

As described above, in the present exemplary embodiment, the optical axis through the objective lens 810 and the reflection mirror 610 is distorted by rotating the rotation block 600 which moves integrally with the holder 850 of the bobbin 800 in response to the tilt of the optical disk. Can be compensated dynamically.

In addition, in the configuration of the third embodiment, the first plate 730 and the first inner and outer yoke 710, 720 for the tracking and focusing operation is fastened to the base plate ( Since it is fixed to the 700, the weight of the first magnet 730 and the first inner and outer yoke 710 (720) has no effect on the rotation operation for the tilt adjustment. That is, since the pivoting operation during the tilting operation is the pivoting block 600 and the bobbin 800 and the holder 850 integrally coupled thereto, the weight of the driven body to be rotated than the first and second embodiments described above. Is relatively small. Therefore, the mass moment of inertia for tilt driving is reduced to improve driving sensitivity, and tilt adjustment can be performed even at a low driving current.

As described above, the optical pickup apparatus according to the present invention adjusts the inclination of the optical axis of the incident and reflected light beams through the reflection mirror and the objective lens in response to the tilting of the recording medium, so that the optical beam is always perpendicular to the recording medium. Can be reflected. In addition, the optical pickup device of the present invention can further reduce the weight of the driven body to be moved for the optical axis tilt adjustment, it is possible to further improve the driving sensitivity.

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 (7)

With a fixed base; A base plate rotatably installed with respect to the fixed base; A bobbin seated on the base plate and movably supported by a predetermined wire; An objective lens mounted on the bobbin and focusing the incident light beam to form a light spot on the recording medium; A focusing coil installed in the bobbin and forming an energization path for current for focusing; A first magnet and a first yoke installed on the base plate to generate an electromagnetic force for driving the bobbin by forming a magnetic field in a direction perpendicular to a current flowing through the focusing coil; A fixed optical system that irradiates a light beam toward the recording medium, and receives the light reflected from the recording medium and incident through the objective lens; A reflection mirror fixed to the base plate so as to be disposed between the objective lens and the fixed optical system, and converting a traveling path of incident light; A support arm having one end fixed to the fixed base and the other end rotatably supporting the reflective mirror, thereby forming a rotational axis of the base plate to which the reflective mirror is fixed; And tilting means for adjusting the inclination of the optical axis passing through the objective lens and the reflecting mirror by rotating the base plate with the support arm as a pivot axis. The method of claim 1, The tilt means, A tilt coil installed in the first yoke to form an energization path for current; An optical pickup apparatus installed on the fixed base and including a second magnet and a second yoke to generate an electromagnetic force for rotating the base plate by forming a magnetic field in a direction perpendicular to a current flowing through the tilt coil. . With a fixed base; A base plate rotatably installed with respect to the fixed base; A hollow boss protruding from the base plate; A bobbin liftably coupled to the boss; An objective lens mounted on the bobbin and focusing an incident light beam to form a light spot on a recording medium; A focusing coil installed in the bobbin and forming an energization path for current for focusing; A first magnet and a first yoke installed on the base plate to generate an electromagnetic force for driving the bobbin by forming a magnetic field in a direction perpendicular to a current flowing through the focusing coil; A fixed optical system that irradiates a light beam toward the recording medium, and receives the light reflected from the recording medium and incident through the objective lens; A reflection mirror fixed to the base plate so as to be disposed between the objective lens and the fixed optical system and converting a traveling path of the light beam; A support arm having one end fixed to the fixed base and the other end rotatably supporting the reflective mirror, thereby forming a pivotal axis of the base plate on which the reflective mirror is fixed; And tilting means for adjusting the inclination of the optical axis passing through the objective lens and the reflecting mirror by rotating the base plate with the support arm as a pivot axis. The method of claim 3, The tilt means, A tilt coil installed in the bobbin to form an energization path for electric current; And a second magnet and a second yoke installed in the fixed base to form a magnetic field in a direction perpendicular to the current flowing through the tilt coil to generate an electromagnetic force for rotating the base plate coupled to the bobbin. Optical pickup device. With a fixed base; A rotation block rotatably installed on the fixed base; A holder integrally coupled with the pivot block; A bobbin movably supported by the holder by a predetermined wire; A base plate fixed to the fixed base to be positioned between the pivot block and the bobbin; An objective lens mounted on the bobbin and focusing an incident light beam to form a light spot on a recording medium; A focusing coil and a tracking coil installed in the bobbin to form an energization path for current for focusing and tracking; A first magnet and a first magnet installed in the base plate so as to face the focusing coil and the tracking coil and generating an electromagnetic force for driving the bobbin by forming a magnetic field in a direction perpendicular to a current flowing through the focusing coil and the tracking coil. Outer yoke; A fixed optical system that irradiates a light beam toward the recording medium, and receives the light reflected from the recording medium and incident through the objective lens; A reflection mirror installed at the rotation block so as to be disposed between the objective lens and the fixed optical system and converting a traveling path of incident light; And tilting means for adjusting the inclination of the optical axis through the objective lens and the reflecting mirror by rotating the pivoting block. The method of claim 5, The tilt means, A tilt coil installed at both sides of the rotation block to form a current carrying path; And a second magnet and a second inner and outer yoke which are installed to face the tilt coil and generate an electromagnetic force for rotating the rotating block by forming a magnetic field in a direction perpendicular to the current flowing through the tilt coil. Optical pickup device. The method of claim 6, Optical pickup, characterized in that a plurality of iron pieces are installed symmetrically on both sides of the rotating block by the magnetic force between the second magnet and the second inner, outer yoke to maintain the equilibrium position of the rotating block. Device.