JP2006031781A - Optical pickup and assembling method thereof - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an optical pickup capable of highly precisely and easily adjusting the position of a permanent magnet when attaching the permanent magnet constituting respective magnetic circuits between a focus coil of a movable part and a tracing coil. <P>SOLUTION: The optical pickup 1 is equipped with the movable part 3, supporting wires 4, a supporting table 5, a yoke part 6 and a base 12. The yoke part 6 is mounted on the base by making a supporting point 01 to a fulcrum in the plane view, and by a position adjusting means 13 of which the relative position of the yoke part with respect to the base is adjustable, the positioning of the yoke part on the base is attained. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to an optical pickup that records and reproduces information by condensing light with an objective lens on a recording surface of an optical disc and an assembling method thereof.

The optical pickup is used in an optical disc apparatus such as an optical disc reproducing apparatus and an optical disc recording / reproducing apparatus. An optical pickup is an apparatus that records and reproduces information by condensing light, for example, laser light, onto a recording surface of an optical disc that is a recording medium.
The optical pickup has a movable part, and this movable part is supported by a support base via a plurality of support wires and is movable. The movable part has an objective lens for condensing the laser light, and a focus coil and a tracking coil for adjusting the position of the objective lens with respect to the optical disk.

The movable part of the conventional optical pickup is, for example, arranged by winding a focus coil around the outer peripheral surface of a movable bobbin containing the objective lens so that the winding axis is parallel to the optical axis direction of the objective lens, The winding axis is wound around a plurality of locations on the outer periphery of the movable bobbin so that the winding axis is orthogonal to the optical axis of the objective lens.
In addition, the permanent magnets are arranged on the inside and outside of the movable bobbin by sticking them to the yoke so that the magnetic flux of the permanent magnets is linked to each of the focus coil and the tracking coil.

Usually, the strength of the magnetic force of the permanent magnet varies depending on each position on the permanent magnet and is not uniform. Therefore, when assembling the optical pickup, it is necessary to adjust the arrangement position of the permanent magnet in the tracking direction.
If the arrangement position of the permanent magnet in the tracking direction is not adjusted, the drive center, which is the center of the magnetic force of the permanent magnet, does not match the center of gravity of the movable part, so when the movable part (bobbin) is driven in the focus direction The movable part is inclined to move toward the stronger magnetic force of the permanent magnet.

FIG. 6 is a partial perspective view showing a method for adjusting the position of a permanent magnet in a conventional optical pickup.
In the conventional optical pickup shown in FIG. 6, the permanent magnet 103 attached to the U-shaped yoke 102 is disposed on the upper surface of the yoke portion 101 fixed to the support base so as to face the tracking coil. Then, as indicated by an arrow D, the permanent magnet 103 and the yoke 102 are moved in a linear direction (here, the tracking direction) to adjust the position.

Japanese Patent Application Laid-Open No. 10-320799 discloses an objective lens driving device (optical pickup) in which a permanent magnet is fixed to a yoke portion.
Japanese Patent Laid-Open No. 10-320799

In the conventional optical pickup described above and the objective lens driving device described in Patent Document 1, the position of the permanent magnet is manually adjusted.
However, the range for adjusting the position of the permanent magnet in the linear direction is very small (for example, 1.0 mm to 2.0 mm), and high accuracy is required for position adjustment. It was extremely difficult to do accurately in the work, and skill was required.
Thus, conventionally, the position adjustment of the permanent magnet could only be performed manually, but it was desired to automate the assembly process of the permanent magnet.

Also, the magnetic force between the movable part and the permanent magnet may be adjusted by manually moving the adjustment yoke in the linear direction (tracking direction) and changing the facing area between the permanent magnet and the adjustment yoke. It was.
However, since the adjustment yoke is moved manually, it is difficult to adjust the magnetic force between the movable portion and the permanent magnet with high accuracy, as described above.

  The present invention has been made to solve such a problem. When a permanent magnet constituting a magnetic circuit is mounted between the focus coil and the tracking coil of the movable part, the position of the permanent magnet is adjusted. An object of the present invention is to provide an optical pickup which can be performed with high accuracy and easily and an assembling method thereof.

In order to achieve the above object, an optical pickup according to the present invention is provided with an objective lens for condensing light on a recording surface of an optical disc, and the position of the objective lens with respect to the optical disc is determined by a focus coil and a tracking coil. An adjustable movable part, a plurality of support wires that movably support the movable part, a support base that supports the support wire, and a permanent magnetic circuit that constitutes each of the focus coil and the tracking coil A yoke portion to which a magnet is attached; and a base to which the yoke portion and the support base are attached. The yoke portion is attached to the base with a support point as a fulcrum in plan view. Position adjustment means that can adjust the relative position of the yoke part with respect to the base enables the yoke part to be positioned on the base To have.
It is preferable that the yoke portion is positioned and held by a fastening member disposed at the support point in a state of being sandwiched between the base and the support base.
The position adjusting means is formed in a circular hole formed in one of the yoke part and the base, and formed in either the yoke part or the base, and is disposed at a position corresponding to the circular hole. In order to assemble the optical pickup, the yoke is supported by rotating the adjustment jig while simultaneously engaging both the circular hole and the long hole in order to assemble the optical pickup. It is preferable that the relative position of the yoke portion with respect to the base can be adjusted by turning the point as a fulcrum.
The adjustment jig is provided at a position eccentric from a center axis of a jig main body having a circular hole engaging portion that can be rotatably engaged with the circular hole, and an end surface of the jig main body. It is preferable to have an eccentric pin that protrudes in a direction parallel to the axis and movably engages with the elongated hole.
In the method of the present invention for assembling the optical pickup, the adjustment jig is rotated while the circular hole engaging portion of the adjustment jig is engaged with the circular hole and the eccentric pin is engaged with the long hole. By doing so, the yoke portion is rotated with the support point as a fulcrum to be positioned on the base.

  Since the optical pickup and its assembling method of the present invention are configured as described above, the position adjustment of the permanent magnet is performed when the permanent magnet constituting the magnetic circuit is mounted between the focus coil and the tracking coil of the movable part. Can be performed with high accuracy and ease.

In the following embodiment, the yoke part to which the permanent magnet is attached is attached to the base with the support point as a fulcrum in plan view, and the yoke part is adjusted by the position adjusting means capable of adjusting the relative position of the yoke part with respect to the base. Can be positioned on the base.
That is, in the present embodiment, a component corresponding to a conventional yoke portion has a double structure of a yoke portion to which a permanent magnet is attached and a base that supports the yoke portion. Then, by adjusting the position of the yoke portion with the position adjusting means, the relative position adjustment of the permanent magnet attached to the yoke portion with respect to the movable portion positioned with respect to the base is easily performed with high accuracy. The purpose is realized.

An embodiment according to the present invention will be described below with reference to FIGS.
1 to 5 are diagrams showing an embodiment of the present invention. FIG. 1 is a plan view of the optical pickup, FIG. 2 is an exploded perspective view of the optical pickup shown in FIG. 1, and FIG. FIG.
FIG. 4A is a partial perspective view showing a method for adjusting the position of the yoke portion, and FIG. 4B is a partial perspective view showing an adjustment jig. FIG. 5 is a partial plan view showing a method of adjusting the position of the yoke portion to which the permanent magnet is attached.

1 to 5, an optical pickup 1 used in an optical disc apparatus (not shown) is movable while being controlled in a radial direction of an optical disc as a recording medium by a moving mechanism (not shown). .
In the optical disk apparatus, the optical disk is rotated by a drive motor, and the optical pickup 1 is moved to a desired position by a moving mechanism. The optical pickup 1 collects light (for example, laser light) on the recording surface of the optical disc with the objective lens 2 to record and reproduce information on the optical disc.
Examples of the optical disk include CD, CD-ROM, CD-R, CD-RW, MD, MO, DVD-ROM, DVD-RAM, DVD-R, and DVD-RW.

The optical pickup 1 includes a movable part 3, a support wire 4, a support base 5, a yoke part (a yoke part) 6, a base 12, and the like.
The movable part 3 is provided with a focus coil 7 and a tracking coil 8 and an objective lens 2 for condensing light such as laser light on the recording surface of the optical disk. The position of the objective lens 2 with respect to the optical disk can be adjusted by passing currents through the focus coil 7 and the tracking coil 8 of the movable part 3.
For convenience of explanation, the direction parallel to the optical axis B of the objective lens 2, that is, the focus direction is the X direction, and in particular, the optical disc side and the anti-optical disc side are the upward direction and the downward direction, respectively.
A direction orthogonal to the X direction (radial direction of the optical disk), that is, a tracking direction is defined as a Z direction, and a direction orthogonal to the X direction and the Z direction is defined as a Y direction. In particular, the horizontal direction in FIG. 1 is the horizontal direction (Z direction) of the optical pickup 1.
In this embodiment, a case of the “lens offset type” optical pickup 1 in which the objective lens 2 is arranged eccentrically on one side with respect to the central portion of the movable portion 3 is shown. The present invention can also be applied to a “lens center type” optical pickup in which the objective lens is disposed at substantially the center of the movable portion.

A yoke portion 6 made of a magnetic material is attached to the base 12, and a support base 5 is attached to the yoke portion 6. The support 5 supports a plurality (here, four) of support wires 4, and the four support wires 4 support the movable portion 3 so as to be movable.
Permanent magnets (here, the first permanent magnet 9a and the second permanent magnet 9b) constituting a magnetic circuit between the focus coil 7 and the tracking coil 8 are attached at predetermined positions of the yoke portion 6. .
A current is supplied to the focus coil 7 and the tracking coil 8 provided in the movable portion 3 via the support wire 4. If a current is passed through the focus coil 7, the movable part 3 can be moved in the focus direction (direction parallel to the optical axis B of the objective lens 2 (X direction)). If a current is passed through the tracking coil 8, the movable part 3 can be moved in the tracking direction (radial direction (Z direction) of the optical disk).

The movable portion 3 has a main body portion 20 having a predetermined shape, and the main body portion 20 is integrally formed of an insulating resin material or the like. The objective lens 2, the focus coil 7, the tracking coil 8, and the like are provided at predetermined positions on the main body 20.
The main body 20 includes a lens support 21 to which the objective lens 2 is attached and a coil support 22 that is hollow and formed in a predetermined shape. The objective lens 2 is attached to the lens support portion 21 so that the central axis of the lens support portion 21 coincides with the optical axis B of the objective lens 2.
The coil support portion 22 is formed integrally with the lens support portion 21, and the inner wall portion 23 of the coil support portion 22 is formed in a cylindrical shape in the vertical direction (X direction) so as to be substantially parallel to the optical axis B. . An opening 24 formed by the inner wall portion 23 is located inward of the coil support portion 22.

One focus coil 7 and two tracking coils 8 constitute a coil unit 25, and this coil unit 25 is attached to the coil support portion 22 while being supported by the inner wall portion 23.
The focus coil 7 is supported by the inner wall portion 23 so that its winding axis is parallel to the optical axis B of the objective lens 2 (parallel to the X direction). The two tracking coils 8 are arranged side by side in the Z direction and supported by one or both of the focus coil 7 and the inner wall portion 23 (here, the focus coil 7). Each tracking coil 8 has the direction of its winding axis parallel to the Y direction.

The base 12 to which the yoke portion 6 and the support base 5 are attached is fixed to a fixed side such as a case or a base member of the optical disk device, and is formed in a predetermined shape (here, rectangular).
The yoke portion 6 is attached to the base 12 with the support point O1 as a fulcrum in plan view. That is, in the present embodiment, a component corresponding to a conventional yoke portion (for example, the yoke portion 101 in FIG. 6) is divided into a yoke portion 6 to which permanent magnets 9a and 9b are attached, and a base that supports the yoke portion 6. A double structure comprising the base 12 is employed.
The yoke portion 6 can be positioned on the base 12 by position adjusting means 13 that can adjust the relative position of the yoke 6 with respect to the base 12. Therefore, when attaching the permanent magnets 9a and 9b constituting the magnetic circuit between the focus coil 7 and the tracking coil 8 of the movable part 3, respectively, the relative position adjustment of the permanent magnets 9a and 9b with respect to the movable part 3 is increased. It can be performed accurately and easily.

Specifically, the yoke portion 6 can rotate on the base 2 with the support point O1 as a fulcrum in plan view before positioning and fixing. For this reason, at least the upper surface of the base 12 and the lower surface of the yoke portion 6 are in sliding contact with each other, and thus have a flat plate shape. In this embodiment, the base 12 and the yoke portion 6 are formed of a plate material and have a rectangular shape in plan view.
The yoke portion 6 is positioned and held in a state of being sandwiched between the base 12 and the support base 5 by a screw member 33 as a fastening member disposed at the support point O1. That is, the yoke portion 6 is disposed on the upper surface of the base 12, and the support base 5 is disposed on the upper surface of the yoke portion 6.

Holes 34 and 35 are formed through the support base 5 and the yoke portion 6, respectively, and a screw hole 36 is formed in the base 12. The screw member 33 is loosely fitted into the holes 34 and 35 and is screwed into the screw hole 36.
Therefore, if the screw member 33 is inserted into the holes 34 and 35 from above the support base 5 and screwed into the screw holes 36, the yoke portion 6 is positioned and held while being sandwiched between the base 12 and the support base 5. Is done.
Thus, since the base 12 is provided separately from the yoke portion 6 to which the permanent magnets 9a and 9b are attached, the yoke portion 6 can be rotated with respect to the base 12 using the support point O1 as a fulcrum. The movable part 3 is positioned relative to the base 12.
Therefore, the relative position adjustment of the permanent magnets 9a and 9b with respect to the movable part 3 is made possible by the yoke part 6 moving continuously.

The yoke part 6 is formed in a substantially rectangular plate shape in plan view, is integrally formed with the body part 14 (or is fixed separately), and protrudes from the body part 14 in a substantially right angle direction. It consists of two substantially rectangular yokes 10 and 11 arranged in parallel to each other. The two yokes 10 and 11 are disposed through the opening 24 of the coil support portion 22 so as to sandwich the focus coil 7 and the tracking coil 8.
The first permanent magnet 9a and the second permanent magnet 9b are attached to the yoke portion 6, and are arranged at predetermined positions corresponding to one focus coil 7 and a total of two tracking coils 8 in the movable portion 3. Yes.
The first permanent magnet 9 a is fixed to the yoke 10 (and / or the direct main body portion 14) with an adhesive or the like, and is disposed to face the two tracking coils 8.

The second permanent magnet 9b is fixed to the yoke 11 (and / or the main body portion 14) with an adhesive or the like. The second permanent magnet 9 b passes through the inside of the focus coil 7 in the X direction, and is disposed to face the two tracking coils 8.
A magnetic circuit is formed between the focus coil 7, the yoke 11 and the second permanent magnet 9b disposed inside the focus coil 7, and the yoke 10 and the first permanent magnet 9a disposed outside the focus coil 7. It is configured. The focus coil 7 is arranged so that the magnetic fluxes of the permanent magnets 9a and 9b are linked.
The two tracking coils 8 are wound so that the respective winding axis directions are perpendicular to the winding axis direction of the focus coil 7. The two tracking coils 8 are arranged in a magnetic field formed by the first permanent magnet 9a and the second permanent magnet 9b to form a magnetic circuit. The two tracking coils 8 are arranged so that the magnetic fluxes of the permanent magnets 9a and 9b are linked.

  An upper yoke 15 is attached to the top of the yokes 10 and 11. The upper yoke 15 is fixed across the upper ends of the yokes 10 and 11 so as to cover one side of the permanent magnets 9a and 9b, the two tracking coils 8 and the focus coil 7, thereby forming a closed magnetic circuit therebetween. is doing. In FIG. 1, the illustration of the upper yoke 15 is omitted for clarity of the structure.

A total of four support wires 4 are provided at both ends of the movable portion 3, two each in parallel with the Y direction. One end of the support wire 4 (the end far from the support base 5) is fixed to the movable part 3 side, and the other end is fixed to the support base 5 side.
The movable portion 3 is attached in a manner floating in the space between the support base 5 and the yoke portion 6 via the four support wires 4. Accordingly, the movable part 3 can freely change the state of the movable part 3 (position, posture, etc. of the movable part 3) by performing operations such as movement and swinging.
The movable part 3 supplies the current to one or both of the focus coil 7 and the tracking coil 8 from the basic position when no current is supplied to the focus coil 7 and the tracking coil 8, thereby moving the movable part 3 in the vertical direction (X direction). Or shift (move) in the left-right direction (Z direction).
Here, the “basic position of the movable part 3” means a stationary position when no current is supplied to the focus coil 7 and the tracking coil 8 and when the movable part 3 is in a stationary state.

A printed wiring board to which the support wire 4 is connected is fixed to the support base 5 with an adhesive or the like. In the printed wiring board, a plurality of (here, four) holes for engaging the support wires 4 are formed at predetermined positions.
A plurality of (here, four) through holes for penetrating the support wire 4 are formed in the support base 5 at predetermined positions. The other end portion of the support wire 4 or the vicinity thereof is electrically connected to the printed wiring board through the hole of the printed wiring board and is fixed to the support base 5 side. One end portion of the support wire 4 or the vicinity thereof is electrically connected to the focus coil 7 or the tracking coil 8 and is fixed to the movable portion 3 side.
The focus coil 7 and the two tracking coils 8 are electrically connected to a control unit (not shown) by a support wire 4 and a printed wiring board to which the support wire 4 is electrically connected.

The position adjusting means 13 includes a circular hole 30 formed in one of the yoke part 6 and the base 12 (here, the yoke part 6) and one of the yoke part 6 and the base 12 (here, the base part). The long hole 31 is formed in the base 12) and disposed at a position corresponding to the circular hole 30.
Then, in order to assemble the optical pickup 1, the adjustment jig 32 is rotated (rotated) in the forward direction or the reverse direction while being simultaneously engaged with both the circular hole 30 and the long hole 31. The portion 6 is rotated (rotated) in the forward or reverse direction with the support point O1 as a fulcrum, so that the relative position of the yoke portion 6 with respect to the base 12 can be adjusted.

The long hole 31 is formed to be long in the direction (Y direction) orthogonal to the direction in which the yoke portion 6 is moved, that is, the tracking direction (Z direction) in plan view. Thereby, if the adjustment jig 32 is rotated, the eccentric pin 40 of the adjustment jig 32 moves in the long hole 31, so that the yoke portion 6 can move in the tracking direction (Z direction). .
Thus, the yoke portion 6 changes its position relative to the base 12, and this change is a substantially linear change. For example, FIG. 5A shows a case where the yoke portion 6 has moved to the right angle (that is, counterclockwise) by the maximum angle θ with the support point O1 as a fulcrum. FIG. 5B shows a case where the yoke portion 6 has moved the maximum angle θ in the left direction (that is, clockwise direction) with respect to the base 12. Therefore, in this example, the adjustment movable range is the angle 2θ, and the yoke portion 6 can be positioned at an arbitrary position within the adjustment movable range.
By rotating the adjustment jig 32 in a state in which both the circular hole 30 and the long hole 31 are simultaneously engaged with each other, the yoke portion 6 is rotated with the support point O1 as a fulcrum. The relative position adjustment in the tracking direction (Z direction) of the permanent magnets 9a and 9b with respect to the movable part 3 which is continuously moved with respect to the base 12 is performed with high accuracy. Can do.
Thereby, adjustment of the magnetic force between the movable part 3 and permanent magnet 9a, 9b can be performed with high precision and easily.

The adjustment jig 32 includes a jig body 38 having a circular hole engaging portion 37 (parallel oblique line portion in FIG. 4A) that can be rotatably engaged with the circular hole 30, and a long hole 31 that is movable. And an eccentric pin 40 (parallel oblique line portion in FIG. 4A) that can be engaged with the pin.
The eccentric pin 40 is provided at a position deviated from the central axis CL of the end surface 39 of the jig body 38, is formed to project in a direction parallel to the central axis CL, and is movably engaged with the long hole 31. The eccentric pin 40 is movable in the longitudinal direction within the long hole 31 while being engaged with the long hole 31.

Therefore, when the optical pickup 1 is assembled, the adjustment jig 32 is moved as shown by an arrow E, and the circular hole engaging portion 37 is moved to the circular hole of the yoke portion 6 (parallel oblique line portion in FIG. 4A). 30, and the eccentric pin 40 is movably engaged with the long hole 31 (parallel oblique line portion in FIG. 4A) of the base 12.
In this state, if the adjustment jig 32 is rotated as indicated by the arrow F, the eccentric pin 40 moves in the elongated hole 31. As a result, the yoke portion 6 is rotated with the support point O1 as a fulcrum as indicated by an arrow G to adjust the relative position with respect to the base 12, and the yoke portion 6 is positioned on the base 12.

As a modification, a long hole 31 is formed in the yoke portion 6, a circular hole 30 is formed in the base 12, and the adjustment jig 32 is formed between the circular hole 30 and the long hole 31 from the lower surface side of the base 12. You may make it engage with both simultaneously.
In this way, when the adjustment jig 32 is used, the support wire 4 and the movable portion 3 are not present in the vicinity, so that the operation of the adjustment jig 32 is facilitated. For example, it is convenient for automation of the assembly process. It is.

The optical pickup 1 has an optical system (not shown). This optical system includes a light source such as a semiconductor laser that generates laser light, a photodetector, a reflection mirror, a lens, and a diffraction grating. The objective lens 2 is also included in this optical system.
The photodetector receives the laser beam reflected from the recording surface of the optical disc, detects a reproduction signal, and detects a focus error signal, a tracking error signal, and the like, thereby detecting the position of the objective lens 2 in the X direction and the Z direction. Is controlling.

Next, the operation of the optical pickup 1 will be described.
First, in the optical disc apparatus, the optical pickup 1 is moved to a desired position by the moving mechanism while the optical disc is being rotationally driven by the drive motor. Then, the laser beam generated in the optical system is condensed on the recording surface by the objective lens 2, and information is recorded on and reproduced from the optical disc.
When controlling the state of the optical pickup 1 (position, posture, etc. of the movable part 3), the position of the focus direction (height direction) of the objective lens with respect to the recording surface of the optical disc detected by the photodetector and the tracking direction The detection result relating to the position or the like is converted into an electric signal by the conversion unit and output to the control unit as an electric signal. The control unit controls the current flowing through the focus coil 7 and the current flowing through the tracking coil 8 based on the electric signal output from the conversion unit.

When the objective lens 2 is moved in the focus direction (X direction), the control unit supplies a control current corresponding to the direction and amount of movement to the focus coil 7 via the support wire 4. Then, the electromagnetic force generated by the focus coil 7 moves (shifts) the movable portion 3 in the focus direction (X direction) with respect to the optical disc, and adjusts the position of the objective lens 2.
Similarly, if the current supplied to the two tracking coils 8 via the support wire 4 is controlled, the movable part 3 moves (shifts) in the tracking direction (Z direction) of the optical disk by the electromagnetic force generated by the tracking coil 8. Then, the position of the objective lens 2 is adjusted.
In this way, the position of the movable unit 3 is controlled so as to move in the focus direction and the tracking direction, respectively.

When the permanent magnets 9a and 9b are assembled in the yoke portion 6 in the optical pickup assembly process, the first permanent magnet 9a is fixed to the yoke 10 (and / or the main body portion 14) with an adhesive or the like, and the second The permanent magnet 9b is fixed to the yoke 11 (and / or the main body 14) with an adhesive or the like. Further, the movable portion 3 is supported on the support base 5 via the support wire 4.
Then, the yoke portion 6 and the support base 5 are sequentially superposed on the base 12, the hole 35 of the yoke portion 6 and the hole 34 of the support base 5 are aligned with the screw hole 36 of the base 12, and the screw member 33 is opened. 34 and 35 and is loosely screwed into the screw hole 36.

Next, the base 12 and the support 5 are positioned and held with an assembly jig or the like. Thereby, relative positioning with respect to the base 12 of the movable part 3 supported by the support stand 5 is made.
Next, as shown by an arrow E, the adjustment jig 32 is simultaneously engaged with both the circular hole 30 and the long hole 31 from the upper surface side of the main body part 14 of the yoke part 6. That is, the circular hole engaging portion 37 of the adjustment jig 32 is engaged with the circular hole 30 of the yoke portion 6, and the eccentric pin 40 of the adjustment jig 32 is engaged with the long hole 31 of the base 12.
Then, as shown by the arrow F, the adjustment jig 32 is rotated in the forward direction or the reverse direction. As a result, the circular hole engaging portion 37 rotates in the circular hole 30 and the eccentric pin 40 moves in the long hole 31, so that the yoke portion 6 is positive with the support point O 1 as a fulcrum as indicated by an arrow G. It is positioned in the base 12 by rotating in the direction or the reverse direction.

Thus, since the relative position of the yoke part 6 with respect to the base 12 is adjusted, the relative position of the permanent magnets 9a and 9b with respect to the movable part 3 is adjusted via the base 12, the support base 5 and the yoke part 6. Can be easily performed with high accuracy.
Usually, the position of the center of gravity of the movable part 3 is a driving point, and if the magnetic center of the permanent magnets 9a and 9b (the driving center that becomes the center of the magnetic force of the permanent magnet) coincides with this driving point, the movable part 3 Without tilting toward the strong magnetic force of the permanent magnet in the tracking direction (Z direction), it is possible to translate in the focus direction (X direction) while maintaining the correct posture.
Therefore, in this embodiment, by adjusting the relative positions of the permanent magnets 9a and 9b with respect to the movable part 3, the driving point of the movable part 3 and the magnetic centers of the permanent magnets 9a and 9b are made to coincide with each other with high accuracy. Can do.
Thus, normally, the magnetic force centers of the permanent magnets 9a and 9b are usually matched with the driving point of the movable part 3. However, the magnetic centers of the permanent magnets 9a and 9b are intentionally decentered with respect to the drive point of the movable part 3 in order to cope with the processing accuracy and characteristic differences of the components of the movable part 3 or the surface deflection of the optical disk. Sometimes you want to. Even in such a case, the permanent magnets 9a and 9b can be easily positioned at desired positions eccentric from the drive point of the movable portion 3.

After the position of the yoke portion 6 is adjusted, the screw member 33 is screwed firmly into the screw hole 36, and the yoke portion 6 is fastened and fixed while being sandwiched between the base 12 and the support base 5. In addition, it is preferable to further fix the yoke portion 6 to both the base 12 and the support base 5 with an adhesive or the like because there is no risk of displacement. In this case, a pin or the like may be used instead of the screw member 33.
The upper yoke 15 is fixed to the upper end surfaces of the yokes 10 and 11 with an adhesive or the like before or after the position adjustment of the permanent magnets 9a and 9b.

When the position of the permanent magnet is adjusted, it is conventionally moved manually in the linear direction, but in the present embodiment, the position is adjusted by rotating the adjusting jig 32. Therefore, the position adjustment work of the permanent magnets 9a and 9b can be performed in a short time and with high accuracy. Since the position adjustment of the permanent magnets 9a and 9b becomes highly accurate, the characteristics of the shift operation of the movable part 3 are improved.
For example, if the adjustment jig 32 is automatically rotated, the yoke portion 6 is rotated with the support point O1 as a fulcrum and moves continuously with respect to the base 12. That is, the process of adjusting the relative position of the permanent magnets 9a and 9b in the tracking direction (Z direction) with respect to the movable part 3 can be automated.
As a modification of the present embodiment, the support point O1 may be arranged at the current position adjusting means 13 and the position adjusting means 13 may be provided at the current support point O1.

As mentioned above, although the Example of this invention was described, this invention is not limited to the above-mentioned Example, A various deformation | transformation, addition, etc. are possible in the range of the summary of this invention.
In the drawings, the same reference numerals denote the same or corresponding parts.

  The present invention is applied to an optical pickup that is attached to an optical disk apparatus that records and reproduces information by condensing a laser beam or the like with an objective lens on a recording surface such as a DVD or CD, and an assembling method thereof.

1 to 5 are views showing an embodiment of the present invention, and FIG. 1 is a plan view of an optical pickup. FIG. 2 is an exploded perspective view of the optical pickup shown in FIG. It is a fragmentary sectional view of an optical pick-up. 4A is a partial perspective view showing a method for adjusting the position of the yoke portion, and FIG. 4B is a partial perspective view showing an adjustment jig. It is a fragmentary top view which shows the position adjustment method of the yoke part to which a permanent magnet is attached. It is a fragmentary perspective view which shows the position adjustment method of the permanent magnet in the conventional optical pick-up.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Optical pick-up 2 Objective lens 3 Movable part 4 Support wire 5 Support stand 6 Yoke part 7 Focus coil 8 Tracking coil 9a 1st permanent magnet (permanent magnet)
9b Second permanent magnet (permanent magnet)
12 base 13 position adjustment means 30 circular hole 31 long hole 32 adjustment jig 33 screw member (fastening member)
37 Circular hole engaging part 38 Jig body 39 End face 40 Eccentric pin CL Center axis O1 Support point

Claims (5)

An objective lens for condensing light on the recording surface of the optical disc, and a movable part capable of adjusting the position of the objective lens with respect to the optical disc by a focus coil and a tracking coil;
A plurality of support wires that movably support the movable part;
A support base for supporting the support wire;
A yoke part to which a permanent magnet constituting a magnetic circuit is attached between the focus coil and the tracking coil;
A base on which the yoke part and the support base are mounted;
The yoke part is attached to the base with a supporting point as a fulcrum in plan view, and the yoke part is placed on the base by position adjusting means capable of adjusting the relative position of the yoke part with respect to the base. An optical pickup characterized in that positioning is possible.   2. The optical pickup according to claim 1, wherein the yoke portion is positioned and held in a state of being sandwiched between the base and the support by a fastening member disposed at the support point. . The position adjusting means is formed in a circular hole formed in one of the yoke part and the base, and formed in either the yoke part or the base, and is disposed at a position corresponding to the circular hole. A long hole,
In order to assemble the optical pickup, the yoke is rotated about the support point as a pivot by rotating the adjustment jig while simultaneously engaging both the circular hole and the long hole. The optical pickup according to claim 1, wherein a relative position of the yoke portion with respect to the base is adjustable. The adjustment jig is
A jig body having a circular hole engaging portion that can be rotatably engaged with the circular hole;
It is provided at an eccentric position from the central axis of the end face of the jig body, and has an eccentric pin that is formed to project in a direction parallel to the central axis and movably engage with the elongated hole. The optical pickup according to claim 3. A method of assembling the optical pickup according to claim 3,
By rotating the adjustment jig while engaging the circular hole engaging portion of the adjustment jig with the circular hole and engaging the eccentric pin with the long hole, the yoke portion is moved to the support point. The optical pickup assembly method is characterized in that the optical pickup is positioned on the base by being rotated as a fulcrum.

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