JP3609209B2 - Objective lens drive - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an objective lens driving device, and more particularly to an objective lens driving device used for an optical disk drive or the like.
[0002]
[Prior art]
As an objective lens driving device used in a conventional optical disk drive, for example, a biaxial drive actuator provided with a drive mechanism that controls the movement of the objective lens in the focusing direction and the movement of the reflection mirror in the tracking direction. There is. In this two-axis drive type actuator, the reflection mirror disposed below the objective lens is fixed to the pickup housing. Recently, in order to reduce the cost and power consumption of the objective lens driving device, the driving mechanism for moving the pickup in the tracking direction has been changed from a linear motor to a lead screw.
[0003]
As another objective lens driving device, for example, there is an “optical control mechanism of an optical disc player” described in Japanese Patent Laid-Open No. 58-98848. In this optical control mechanism, a reflection mirror that reflects laser light to an objective lens is mounted on a block that moves in the tracking direction, and an elastic member for focusing, an objective lens support member, and an objective lens are mounted on this block. Focusing. When the objective lens is displaced in the tracking direction due to the movement of the block in the tracking direction, the optical axes of the reflection mirror and the objective lens do not shift, so that a decrease in the amount of light incident on the optical system light receiving element can be prevented and stable. Tracking is possible.
[0004]
[Problems to be solved by the invention]
However, in the case of the lead screw driving method among the conventional objective lens driving devices, the follow-up characteristic when the pickup is moved in the tracking direction is deteriorated. Therefore, the movement amount of the objective lens in the tracking direction by the actuator is about 400 μm. A degree is required. When the movement amount in the lens tracking direction is 400 μm, the optical axis of the objective lens and the objective lens incident light (laser light) is shifted by 400 μm as it is, so that the return light incident on the light receiving element enters the light receiving element dividing line. On the other hand, the tracking error signal is offset, or the optical axis of the reflecting mirror and the objective lens is deviated to reduce the amount of return light, thereby degrading the data writing / reading performance of the pickup with respect to the optical disk.
[0005]
In addition, since it is desired to increase the capacity of the next-generation optical disc, the diameter of the light spot on the disc surface is reduced, that is, the NA (numerical aperture) is increased and the wavelength of the laser beam is shortened. The track pitch on the disk surface is being reduced. Therefore, in the above-described lead screw driving type objective lens driving device, tracking offset and light amount reduction due to deviation of the objective lens and the optical axis are important problems for the next generation optical disc, and these problems need to be solved. .
[0006]
Further, in the optical control mechanism of the optical disc player described in JP-A-58-98848, a reflection mirror that reflects laser light to the objective lens is mounted on a block that moves in the tracking direction. Miniaturization in the height direction due to the mounting of an elastic member for focusing, an objective lens support member and an objective lensCause trouble. Furthermore, since the reflecting mirror is mounted on the driving member in the tracking direction, the moving part is heavy.Become.
[0007]
Further, in the case of such an optical control mechanism that drives the objective lens with two axes, as shown in FIG. 19, when the objective lens A moves in the tracking direction in FIG. 19, the laser optical axis B in FIG. The optical axis C of the objective lens is shifted by Δx. As a result, the position of the light spot incident on the light receiving element of the detection system is shifted, an offset is generated in the track error signal, and the control accuracy is lowered. Further, when the objective lens A moves in the tracking direction, the light amount of the laser light incident on the objective lens A is reduced, and the light amount fluctuation occurs during tracking, and each operation of data recording / data reproduction with respect to the optical disc is executed. It becomes a problem above.
[0008]
there,BookThe invention includes an objective lens support mechanism that supports an objective lens that condenses and irradiates light onto an optical disk surface so as to be movable in a tracking direction and a focusing direction, and reflects the incident light from the tracking direction in the focusing direction. A reflection mirror support mechanism that supports the reflection mirror that is incident on the tracking mechanism so as to be movable in the tracking direction. When the objective lens supported by the objective lens support mechanism moves in the tracking direction, the reflection mirror support mechanism By moving the supported reflection mirror in association with the tracking direction, the tracking of the reflection mirror in the tracking direction with respect to the movement of the objective lens in the tracking direction is improved, and the amount of deviation of the optical axis is reduced. It is an object of the present invention to provide an objective lens driving device capable of performing the above.
[0009]
BookAccording to the invention, the objective lens support mechanism and the reflection mirror support mechanism are linked with a predetermined elastic body, thereby moving the reflection mirror in the tracking direction with respect to the movement of the objective lens in the tracking direction with a simple structure and at low cost. It is an object of the present invention to provide an inexpensive objective lens driving device that can improve the followability of the lens and reduce the amount of deviation of the optical axis.
[0010]
BookAccording to the invention, the objective lens support mechanism and the reflection mirror support mechanism are linked by a tubular elastic body, and the center line of the tubular elastic body in the cylinder direction is made to coincide with the tracking direction.(Refer to the description of FIG. 14 described later)An objective lens driving device that can increase the tracking constant elastic constant, lower the focusing direction elastic constant, improve the followability of the reflecting mirror to the objective lens, and reduce the driving current in the focusing direction. It is intended to provide.
[0011]
BookThe invention includes an objective lens support mechanism and a reflection mirror support mechanism, a magnetized member such as an iron piece attached to one of the objective lens support mechanism and the reflection mirror support mechanism, and the other of the objective lens support mechanism and the reflection mirror support mechanism facing each other with a predetermined interval. The objective lens and the reflecting mirror are moved in the tracking direction in a non-contact manner by being linked with the magnetic member attached to the lens, and the tracking performance of the reflecting mirror to the objective lens is stable with respect to environmental changes such as temperature changes. The objective of this invention is to provide a small objective lens driving device that can further improve the optical axis and further reduce the amount of deviation of the optical axis.
[0012]
BookThe invention includes a first magnet attached to one of the objective lens support mechanism and the reflection mirror support mechanism and having the magnetic pole division line aligned with the focusing direction, the objective lens support mechanism, and the reflection mirror support mechanism. The other side of the first magnet is attached to be opposed to the first magnet at a predetermined interval, and its magnetic pole dividing line is disposed so as to coincide with the focusing direction, and its polarity is opposite to the polarity of the first magnet facing each other. By linking with the second magnet having polarity, in the tracking direction, the followability of the reflecting mirror to the objective lens can be further improved by a strong attractive force, and the driving current in the focusing direction can be reduced. An object of the present invention is to provide an objective lens driving device.
[0013]
BookThe invention further provides a jitter direction adjusting mechanism capable of adjusting the position of the reflecting mirror in a jitter direction orthogonal to both the optical axis of the objective lens and the tracking direction, thereby providing a distance between the magnetic member and the magnetic member, or a relative It is an object of the present invention to provide an objective lens driving device that can stabilize the attractive force by adjusting the interval between the magnets facing and can further improve the followability of the reflecting mirror to the objective lens.
[0014]
[Means for Solving the Problems]
BookAn objective lens driving device according to the present invention includes an objective lens support mechanism that supports an objective lens that condenses and irradiates light onto an optical disk surface so that the objective lens can move in a tracking direction and a focusing direction, and the focusing light that is incident from the tracking direction. A reflection mirror support mechanism for supporting the reflection mirror that is reflected in the direction and incident on the objective lens so as to be movable in the tracking direction, the objective lens support mechanism and the reflection mirror support. The mechanism isIt consists of an elastic body attached over both the support mechanismsLinked by linking means,The objective lens is moved in the tracking direction by driving the objective lens support mechanism by a tracking drive mechanism, and the reflection mirror supported by the reflection mirror support mechanism is moved by the tracking drive mechanism and the linkage means. In association with the movement of the objective lens in the tracking direction, it is displaced in the tracking direction by substantially the same amount as the objective lens, and the displacement reduces the deviation of the optical axis between the objective lens and the reflection mirror.The configuration.
[0015]
According to the above configuration, the objective lens support mechanism that supports the objective lens that condenses and irradiates light onto the optical disk surface so as to be movable in the tracking direction and the focusing direction, and reflects the light incident from the tracking direction in the focusing direction. When the objective lens supported by the objective lens support mechanism moves in the tracking direction, the reflection mirror support mechanism that supports the reflection mirror incident on the objective lens so as to be movable in the tracking direction is linked by the linkage means. Since the reflecting mirror supported by the support mechanism is moved in conjunction with the tracking direction,Simple structure and low costThe followability of the movement of the reflecting mirror in the tracking direction with respect to the movement of the objective lens in the tracking direction can be improved, and the amount of deviation of the optical axis can be reduced.
[0018]
For example,,PreviousThe elastic body may be a tubular elastic body, and may be disposed in a direction in which the center line in the cylindrical direction of the tubular elastic body coincides with the tracking direction.
[0019]
According to the above configuration, since the objective lens support mechanism and the reflection mirror support mechanism are linked by the tubular elastic body, and the center line of the tubular elastic body in the cylinder direction coincides with the tracking direction, the elastic constant in the tracking direction , The elastic constant in the focusing direction can be lowered, the followability of the reflecting mirror to the objective lens can be improved, and the driving current in the focusing direction can be reduced.
[0020]
In addition, for example,PreviousThe linking means includes a magnetism member such as an iron piece attached to one of the objective lens support mechanism and the reflection mirror support mechanism, and the objective lens support mechanism and the reflection mirror opposite to each other with a predetermined interval. And a magnetic member attached to the other side of the support mechanism.
[0021]
According to the above configuration, the objective lens support mechanism and the reflection mirror support mechanism are separated from each other by a magnetized member such as an iron piece attached to one of the objective lens support mechanism and the mirror support member with a predetermined distance therebetween. Since it is linked with a magnetic member attached to the other side of the mechanism, the objective lens and the reflecting mirror can be moved in the tracking direction in a non-contact manner, stable against environmental changes such as temperature changes, and to the objective lens. The followability of the reflecting mirror can be improved. As a result, the amount of deviation of the optical axis can be further reduced.
[0022]
For example,,PreviousThe linking means includes a first magnet attached to one of the objective lens support mechanism and the reflection mirror support mechanism and having its magnetic pole dividing line aligned with the focusing direction, the objective lens support mechanism, The other one of the reflecting mirror support mechanisms is attached to the first magnet so as to be opposed to each other with a predetermined interval, and the magnetic pole dividing line is disposed so as to coincide with the focusing direction, and the polarity is opposed to the first magnet. It may be a second magnet having a polarity opposite to that of the first magnet.
[0023]
According to the above configuration, the objective lens support mechanism and the reflection mirror support mechanism are attached to one of them, the first magnet disposed with its magnetic pole dividing line aligned with the focusing direction, the objective lens support mechanism, and the reflection The other side of the mirror support mechanism is attached to the first magnet so as to be opposed to each other at a predetermined interval, and the magnetic pole dividing line is arranged so as to coincide with the focusing direction, and the polarity of the first magnet is opposed to each other. In the tracking direction, the tracking performance of the reflecting mirror with respect to the objective lens can be further improved by a strong attractive force, and the driving current in the focusing direction is also linked. Can be reduced.
[0024]
In addition, for example,PreviousThe objective lens driving device may further include a jitter direction adjusting mechanism capable of adjusting the position of the reflection mirror in a jitter direction orthogonal to both the optical axis of the objective lens and the tracking direction.
[0025]
According to the above configuration, the apparatus further includes the jitter direction adjusting mechanism that can adjust the position of the reflecting mirror in the jitter direction orthogonal to both the optical axis of the objective lens and the tracking direction. Alternatively, it is possible to adjust the interval between the magnets facing each other, stabilize these attractive forces, and further improve the followability of the reflecting mirror with respect to the objective lens.
[0026]
DETAILED DESCRIPTION OF THE INVENTION
DESCRIPTION OF EXEMPLARY EMBODIMENTS Hereinafter, preferred embodiments of the invention will be described in detail with reference to the accompanying drawings. The embodiments described below are preferred embodiments of the present invention, and thus various technically preferable limitations are given. However, the scope of the present invention is particularly limited in the following description. As long as there is no description which limits, it is not restricted to these aspects.
(First embodiment)
1 to 3 are exploded perspective views of a pickup block in the objective lens driving device to which the first embodiment of the objective lens driving device of the present invention is applied.
[0027]
In FIG. 1, a pickup block 1 has a focus plate spring 3 composed of two pieces that support an objective lens 2 and are displaced in the focusing direction in the figure. The two focus plate springs 3 are fixed. The spacer 4 is sandwiched in the hole 3a portion opened for use, and is fixed to the tracking holding member 6 by a fixing pin 5 passed through the hole 3a.
[0028]
Further, the two focus leaf springs 3 are displaced in a focusing direction indicated by a double-headed arrow in FIG. 1 by a force in a vertical direction (focusing direction) in FIG.
[0029]
The tracking holding member 6 has one end of a hinge leaf spring 7 fixed to the center of the front surface in FIG. 1 and the hinge fixed to the other end of the hinge leaf spring 7 via the hinge leaf spring 7. The leaf spring holding member 8 is connected. The tracking holding member 6 and the focus leaf spring 3 are displaced in the tracking direction indicated by the double-headed arrow in FIG. 1 when a force in the left-right direction (tracking direction) in FIG.
[0030]
That is, the objective lens 2 is displaced in the focusing direction indicated by the double arrow in FIG. 1 by the focus leaf spring 3, and is displaced in the tracking direction indicated by the double arrow in FIG.
[0031]
The reflecting mirror 9 is held by two parallel leaf springs 10 so as to be displaceable in the tracking direction shown in the figure, and a shaft 11 is provided on the front side face in FIG. A cylindrical elastic member (elastic body) 13 fixed by a fixing member 12 is provided on the facing surface of the tracking holding member 6 facing the shaft 11, and the shaft 11 is, as shown in FIG. By being inserted into the cylindrical elastic member 13, the reflection mirror 9 and the tracking holding member 6 are linked and held.
[0032]
Further, the two parallel leaf springs 10 for displacing the reflecting mirror 9 include a parallel leaf spring fixing member 14 on the side where the reflecting mirror 9 is not fixed and a parallel leaf spring holding member 15 to which the reflecting mirror 9 is fixed. A parallel interval is set and held, and the side on which the reflecting mirror 9 is not fixed is fixed to a pickup case (not shown) with a screw 14 a by a parallel leaf spring fixing member 14.
[0033]
That is, the focus plate spring 3, the spacer 4, the tracking holding member 6, the hinge plate spring 7, and the hinge plate spring holding member 8 support the objective lens 2 so as to be movable in the tracking direction and the focusing direction. The parallel leaf spring 10, the parallel leaf spring fixing member 14, and the parallel leaf spring holding member 15 function as a reflection mirror support mechanism 1b that supports the reflection mirror 9 to be movable in the tracking direction as a whole. The shaft 11, the fixing member 12, and the cylindrical elastic member 13 link the objective lens support mechanism 1a and the reflection mirror support mechanism 1b as a whole, and the objective lens 2 supported by the objective lens support mechanism 1a is in the tracking direction. When it moves to, it functions as linkage means for moving the reflection mirror 9 supported by the reflection mirror support mechanism 1b in linkage with the tracking direction.
[0034]
Therefore, when the objective lens 2 is displaced in the tracking direction shown in FIG. 1 by the hinge plate spring 7, the tracking holding member 6 is also rotated in the tracking direction and fixed to the tracking holding member 6. The reflection mirror 9 linked by the member 13 is also displaced by substantially the same amount in the same tracking direction.
[0035]
Further, since the reflecting mirror 9 is linked to the tracking holding member 6 by the cylindrical elastic member 13 and the shaft 11, the hinge plate spring 7 is bent and the focus plate spring 3 and the tracking holding member 6 are displaced in the tracking direction. Then, the parallel leaf spring 10 is also bent in the tracking direction, and the reflection mirror 9 is displaced in the tracking direction.
[0036]
Next, the operation of the present embodiment will be described. The pickup block 1 fixes the hinge leaf spring 7 to the tracking holding member 6 and is provided with a cylindrical elastic member 13 linked to the shaft 11 provided on the side surface of the reflection mirror 9, so that the objective lens 2 and the reflection mirror 9 are provided. Are displaced by the same amount in the tracking direction, and the shift of the optical axis between the objective lens 2 and the reflection mirror 9 can be reduced.
[0037]
That is, when the focusing force is applied to the focus plate spring 3 in the focusing direction by a focus drive mechanism (not shown), the pickup block 1 is bent when the focus plate spring 3 is pulled upward or downward, and the focus plate spring 3 is bent. The objective lens 2 is displaced in the focusing direction.
[0038]
Further, when a tracking force is applied in the tracking direction to the focus leaf spring 3 and the tracking holding member 6 by a tracking drive mechanism (not shown), the focus leaf spring 3 and the tracking holding member 6 are pulled rightward or leftward in FIG. As a result, the hinge plate spring 7 is bent and the hinge plate spring 7 is bent, whereby the objective lens 2 is displaced in the tracking direction.
[0039]
When the objective lens 2 is displaced in the tracking direction, the reflecting mirror 9 linked to the tracking holding member 6 by the fixing member 12, the cylindrical elastic member 13 and the shaft 11 receives the force in the tracking direction, and the parallel leaf spring 10 is moved. The reflecting mirror 9 is displaced in the tracking direction like the objective lens 2 by bending in the tracking direction.
[0040]
As described above, when the objective lens 2 is displaced in the tracking direction, the reflection mirror 9 is also displaced in the tracking direction in conjunction with the objective lens 2, so that the optical axis shift between the objective lens 2 and the reflection mirror 9 can be reduced.
[0041]
Therefore, it is possible to reduce the occurrence of an offset with respect to the tracking error signal and the reduction in the amount of return light as in the conventional case, improve the utilization efficiency of the laser light, and extend the life of the laser diode. Further, the data writing / reading performance with respect to the optical disk of the pickup can be stabilized.
[0042]
Furthermore, since the reflecting mirror 9 is linked to the tracking holding member 6 by a cylindrical elastic member 13 which is an elastic body, the reflecting mirror 9 can be made stationary with respect to vibration in a high frequency band. Further, an optical control mechanism for an optical disc player described in Japanese Patent Laid-Open No. 58-98848 is disclosed.Then, in order from the top, the objective lens 5, the reflection mirror 10, and the second elastic plate 16 are arranged in the height (vertical) direction, whereas in the first embodiment, the elastic member 13 is the objective lens. 2 and the reflecting mirror 9 are arranged in the horizontal direction,Miniaturization can be achieved.
[0043]
Therefore, the reliability of the optical disk player can be improved by mounting the pickup block 1 of the first embodiment on the optical disk player.
[0044]
In the first embodiment, the elastic body that links the reflecting mirror 9 to the tracking holding member 6 is the cylindrical elastic member 13, but as the elastic body, as shown in FIG. Alternatively, a linear member 15 such as a bar spring may be used.
[0045]
In FIG. 1, the case where the objective lens 2 is displaced in the tracking direction by the rotation type hinge plate spring 7 has been described. However, the structure of the shaft sliding rotation tracking system and four wires are described. The same effect can be obtained even when the objective lens driving mechanism is employed.
(Second Embodiment)
In the pickup block 1 of the first embodiment, the reflecting mirror 9 is attached to the shaft 11 and the cylindrical elastic member 13 with respect to the tracking holding member 6 to which the hinge leaf spring 7 that displaces the objective lens 2 in the tracking direction is fixed. When the objective lens 2 is displaced in the tracking direction by the hinge leaf spring 7, the reflection mirror 9 linked to the tracking holding member 6 is similarly displaced in the tracking direction. The optical axis shift of the reflection mirror 9 was reduced. However, in this case, since the cylindrical elastic member 13 which is an elastic member is used for the portion where the tracking holding member 6 and the reflection mirror 9 are linked, the hardness of the elastic member changes due to the influence of the ambient temperature, and the cylindrical elastic member 13 There is a possibility that the reflection mirror 9 will not be displaced in the tracking direction, similarly to the displacement of the objective lens 2 in the tracking direction.
[0046]
In the second embodiment, the objective lens and the reflecting mirror are not linked directly, but the objective lens and the reflecting mirror are linked in a non-contact manner, and the objective lens is moved in accordance with the amount of displacement in the tracking direction. Stabilizes the amount of displacement of the reflecting mirror in the tracking direction.
[0047]
FIG. 4 is a diagram showing a configuration of a pickup block according to the second embodiment to which the objective lens driving device of the present invention is applied. In the description of the present embodiment, the same components as those of the pickup block 1 shown in FIG. 1 of the first embodiment are denoted by the same reference numerals, and detailed description thereof is omitted.
[0048]
FIG. 4 is an exploded perspective view of the pickup block 20 according to the second embodiment. In FIG. 4, the pickup block 20 has an objective lens 21 supported by a bobbin 22, and the bobbin 22 is connected to and supported by a support member 24 by four wire springs 23. An iron piece (magnetized member) 25 is attached to the side surface of the bobbin 22 on the reflection mirror 9 side, and the iron piece 25 is attached to the surface of the parallel leaf spring holding member 15 to which the reflection mirror 9 is attached. A magnet (magnetic member) 26 is attached at a position opposite to.
[0049]
The bobbin 22 that supports the objective lens 21 is supported by four wire springs 23 and a support member 24 connected by the wire springs 23 so as to be displaceable in the tracking direction and the focusing direction in FIG. .
[0050]
Therefore, the objective lens 21 is displaced in the focusing direction and the tracking direction shown in FIG. 4 when the wire spring 23 bends in the vertical and horizontal directions in FIG. 4, and the bobbin 22, the wire spring 23 and the support member 24 are It functions as the objective lens support mechanism 20a.
[0051]
As in the first embodiment, the reflecting mirror 9 is held by two parallel leaf springs 10 so as to be displaceable in the tracking direction shown in FIG. 4 and the side surface opposite to the parallel leaf springs 10. A magnet 26 is fixed to the magnet. The magnet 26 is fixed at a position facing the iron piece 25 provided on the bobbin 22. The parallel leaf spring 10, the parallel leaf spring fixing member 14, and the parallel leaf spring holding member 15 function as a reflection mirror support mechanism 20b.
[0052]
Therefore, when the objective lens 21 is displaced in the tracking direction in FIG. 4 by the wire spring 23, the iron piece 25 provided on the bobbin 22 and the magnet fixed to the side surface of the reflecting mirror 9 facing the iron piece 25. The reflecting mirror 9 is also pulled in the tracking direction by the attractive force of the magnetic field lines generated between the reflecting mirror 26 and the magnetic recording line 26. At this time, the parallel leaf spring 10 is deflected in the tracking direction, and the reflection mirror 9 is moved in the tracking direction in the same manner as the objective lens 21.
[0053]
Next, the operation of the present embodiment will be described. In the pickup block 20, in order to displace the objective lens 21 in the tracking direction, a bobbin 22 that supports the objective lens 21 is supported by a support member 24 connected by four wire springs 23, thereby tracking direction in FIG. 4. And an iron piece 25 is provided at a position facing the side surface of the reflecting mirror 9 of the bobbin 22, and a magnet 26 is fixed to the side surface of the reflecting mirror 9 facing the iron piece 25. When the bobbin 22 is displaced in the tracking direction, the objective lens 21 and the reflecting mirror 9 are displaced in the tracking direction by the same amount by the magnetic attractive force of the iron piece 25 and the magnet 26. The deviation of the optical axis from the reflecting mirror 9 can be reduced.
[0054]
That is, when a force in the focusing direction is applied to the pickup block 20 by a focus drive mechanism (not shown), the wire spring 23 holding the bobbin 22 bends upward or downward, and the objective lens 21 moves upward or downward in FIG. Displaced in the downward focusing direction.
[0055]
Further, when a force in the tracking direction is applied by a tracking drive mechanism (not shown), the bobbin 22 is pulled rightward or leftward in FIG. 4 and the wire spring 23 is bent, so that the objective lens 21 is moved in the tracking direction in FIG. Is displaced.
[0056]
When the objective lens 21 is displaced in the tracking direction, the parallel leaf spring holding member 15 and the parallel leaf spring are caused by the magnetic force between the iron piece 25 provided on the bobbin 22 and the magnet 26 fixed to the reflection mirror 9. The parallel leaf spring 10 held by the fixing member 14 bends in the tracking direction, and the reflection mirror 9 is displaced in the tracking direction like the objective lens 2.
[0057]
In this way, when the objective lens 21 is displaced in the tracking direction, the iron piece 25 provided on the bobbin 22 and the magnet 26 provided on the reflection mirror 9 are not contacted, and the reflection mirror 9 is also interlocked in the tracking direction. Therefore, the optical axis shift between the objective lens 21 and the reflection mirror 9 can be reduced. For this reason, it is possible to reduce the occurrence of an offset with respect to the tracking error signal as described above and the reduction in the amount of return light, improve the utilization efficiency of the laser light, and extend the life of the laser diode. Further, the data writing / reading performance with respect to the optical disk of the pickup can be stabilized.
[0058]
Further, in the pickup unit 20 of the second embodiment, similarly to the pickup unit 1 of the first embodiment,Since the linking means (25, 26) between the objective lens support mechanism and the reflection mirror support mechanism is not arranged in the height direction with respect to the reflection mirror and the objective lens,Miniaturization can be achieved.
[0059]
Therefore, the reliability of the optical disk player can be improved by mounting the pickup block 20 of the second embodiment on the optical disk player.
(Third embodiment)
In the pickup block 20 of the second embodiment, since the objective lens 21 and the reflection mirror 9 are displaced in conjunction with the tracking direction, the iron piece 25 is provided on the surface of the bobbin 22 that supports the objective lens 21 that faces the reflection mirror 9. And a magnet 26 is provided on the side surface of the parallel leaf spring holding member 15 that supports the reflecting mirror 9 that faces the iron piece 25, and the attractive force generated by the lines of magnetic force generated between the iron piece 25 and the magnet 26 is used. However, in this case, since the iron piece 25 and the magnet 26 are simply arranged so as to face each other regardless of their magnetic polarities, the attractive force generated by the lines of magnetic force generated between the iron piece 25 and the magnet 26 takes the polarity into consideration. This is inferior to the case where the bobbin 22 supporting the objective lens 21 moves, and a slight delay occurs in the timing when the reflecting mirror 9 moves.
[0060]
Thus, in the third embodiment, a magnet is provided on the bobbin so that the magnetic pole dividing lines of S and N poles are in the focusing direction, and the magnetic pole of the magnet provided on the side of the reflecting mirror facing the magnet. The S and N poles are arranged so as to be attracted to the magnet provided on the bobbin, thereby improving the followability of the reflecting mirror with respect to the movement of the objective lens in the tracking direction.
[0061]
5 to 7 are diagrams showing the configuration of a pickup block to which the third embodiment of the objective lens driving device of the present invention is applied. In the description of the present embodiment, the same components as those of the pickup block 20 of the second embodiment are denoted by the same reference numerals, and detailed description thereof is omitted.
[0062]
5 and 6 show a pickup block 30 according to the third embodiment. In FIGS. 5 and 6, the pickup block 30 supports the reflection mirror 9 that holds the reflection mirror 9 so as to be displaceable in the tracking direction. A pair of fixing members 32 and a fixing member 33 are fixed to a base 31 that fixes the mechanism 30b.
[0063]
One end of two parallel plate springs 34 is attached to the fixing member 32, and the parallel plate spring holding the reflecting mirror 9 is fixed to the other end of the two parallel plate springs 34. The member 35 is fixed. A magnet 36 is attached to the parallel plate spring holding member 35 on the surface opposite to the surface on which the reflecting mirror 9 is fixed. As shown in FIG. 7, the magnet 36 is provided at a position facing the magnet 37 provided on the bobbin 22, and the magnetic pole dividing line is installed in a direction that coincides with the focusing direction in FIG. 7. The magnetic poles divided by the magnetic pole dividing line are N poles on the right side and S poles on the left side as shown in FIG.
[0064]
In FIG. 7, the magnet 37 provided on the bobbin 22 is also installed so that the magnetic pole dividing line is in the focusing direction, and the magnetic poles divided by the magnetic pole dividing line are as shown in FIG. S pole on the right and N pole on the left.
[0065]
Therefore, the magnetic poles of the magnet 36 and the magnet 37 facing each other are both arranged in a direction in which the magnetic pole dividing line coincides with the focusing direction, and the magnetic poles are arranged so that the N pole and the S pole face each other. The magnet 36 and the magnet 37 are attracted to each other by a magnetic force.
[0066]
In FIG. 6, the objective lens 21 is supported by the bobbin 22 similarly to the one shown in FIG. 4 of the second embodiment, and is supported on the support member 24 by the bobbin 22 and the four wire springs 23. It is connected. The support member 24 is fixed to the base 31 so that the bobbin 22 connected to the support member 24 by the wire spring 23 is disposed in front of the parallel leaf spring holding member 35 to which the reflection mirror 9 is fixed. The bobbin 22, the wire spring 23, and the support member 24 function as an objective lens support mechanism 30a as a whole.
[0067]
When the force in the tracking direction is applied to the bobbin 22 by a tracking drive mechanism (not shown), the pickup block 30 is pulled in the tracking direction. At this time, the four wire springs 23 are bent, and the objective lens 2 is shown in FIG. 6 is displaced in the tracking direction.
[0068]
Further, when a force in the focusing direction is applied to the bobbin 22 by a focus drive mechanism (not shown), the pickup block 30 moves the bobbin 22 upward or downward, the wire spring 23 bends, and the objective lens 21 is moved as shown in FIG. Displaced in the focusing direction.
[0069]
Therefore, the objective lens 21 is displaced in the focusing direction and the tracking direction shown in FIG. 6 when the wire spring 23 bends in the vertical direction and the horizontal direction in FIG.
[0070]
When the bobbin 22 is displaced in the tracking direction, the reflection mirror 9 is attracted to each other by the magnetic force between the magnet 37 provided on the bobbin 22 and the magnet 36 provided on the side surface of the reflection mirror 9. In response to the displacement in the tracking direction, the parallel leaf spring 10 bends and is similarly displaced in the tracking direction.
[0071]
Therefore, when the objective lens 21 is displaced in the tracking direction in FIG. 6 by the wire spring 23, the magnet 37 provided on the bobbin 22 and the magnet 36 fixed to the side surface of the opposing reflecting mirror 9. The reflecting mirror 9 is also pulled in the tracking direction by the attractive force of the magnetic force lines generated therebetween. At this time, the parallel leaf spring 34 is bent in the tracking direction, and the reflection mirror 9 is moved in the tracking direction in the same manner as the objective lens 21.
[0072]
Next, the operation of the present embodiment will be described. When a force in the focusing direction is applied to the bobbin 22 by a focus drive mechanism (not shown), the pickup block 30 moves the bobbin 22 upward or downward in FIG. 6 and the wire spring 23 bends, so that the objective lens 21 is displaced in the focusing direction of FIG.
[0073]
In addition, in the pickup block 30, when a force in the tracking direction is applied to the bobbin 22 by a tracking drive mechanism (not shown), the bobbin 22 is pulled in the tracking direction, and at this time, the four wire springs 23 bend, thereby the objective lens 2 Is displaced in the tracking direction of FIG.
[0074]
When the objective lens 21 is displaced in the tracking direction, the parallel leaf spring holding member 35 and the reflecting mirror 9 are caused by the magnetic force between the magnet 37 provided on the bobbin 22 and the magnet 36 fixed to the reflecting mirror 9 side. The parallel leaf spring 34 held by the fixing member 32 also bends in the tracking direction, and the reflection mirror 9 is displaced in the tracking direction like the objective lens 21.
[0075]
In this way, when the objective lens 21 is displaced in the tracking direction, non-contact is caused by a stronger attractive force generated between the magnet 37 provided on the bobbin 22 and the magnet 36 provided on the reflecting mirror 9 side. Thus, the reflection mirror 9 is interlocked and the reflection mirror 9 is similarly displaced in the tracking direction, and the optical axis shift between the objective lens 21 and the reflection mirror 9 can be reduced.
[0076]
Therefore, it is possible to reduce the occurrence of an offset with respect to the tracking error signal as described above and the reduction in the amount of return light, improve the utilization efficiency of the laser light, and extend the life of the laser diode. Further, the data writing / reading performance with respect to the optical disk of the pickup can be stabilized.
[0077]
Furthermore, in the pickup unit 30 of the third embodiment, as with the pickup unit 1 of the first embodiment,Since the linking means (25, 26) between the objective lens support mechanism and the reflection mirror support mechanism is not arranged in the height direction with respect to the reflection mirror and the objective lens,Miniaturization can be achieved.
[0078]
Therefore, the reliability of the optical disk player can be improved by mounting the pickup block 30 of the third embodiment on the optical disk player.
(Fourth embodiment)
In this embodiment, a hinge is used to displace the objective lens in the focusing direction and the tracking direction.
[0079]
8 and 9 are diagrams showing a configuration of a pickup block according to a fourth embodiment to which the objective lens driving device of the present invention is applied. In the description of the present embodiment, the same components as those in the pickup block 30 of the third embodiment are denoted by the same reference numerals, and detailed description thereof is omitted.
[0080]
8 and 9 are diagrams showing a pickup block 40 according to the fourth embodiment. 8 and 9, the pickup block 40 supports the objective lens 21 with a bobbin 41, and the bobbin 41 is integrally formed with a rotating hinge portion 42 that rotates the bobbin 41 in the tracking direction. A tracking hinge member 43 that displaces the objective lens 21 supported by the bobbin 41 in the tracking direction is fixed to the base 44, and the rotating hinge portion 42 and the tracking hinge member 43 are connected by a parallel link member 45. . Further, a focus hinge portion 45 a is formed at a connection portion between the parallel link member 45 and the rotation hinge member 42. Therefore, the bobbin 41, the rotation hinge part 42, the tracking hinge member 43, the parallel link member 45, and the focus hinge part 45a function as an objective lens support mechanism 40a as a whole.
[0081]
The reflection mirror 9 is supported by a reflection mirror holder 46, and reflection mirror tracking leaf springs 47 are provided at both left and right ends of the reflection mirror holder 46, thereby displacing the reflection mirror 9 in the tracking direction. The reflection mirror tracking leaf spring 47 is attached to a fixing member 48, and the fixing member 48 is fixed to the base 44. Therefore, the reflection mirror holder 46, the reflection mirror tracking leaf spring 47, and the fixing member 48 function as a reflection mirror support mechanism 40b as a whole.
[0082]
A bobbin side magnet 49 is provided on the side surface of the bobbin 41 facing the reflection mirror holder 46, and a reflection mirror side magnet 50 is provided on the surface of the reflection mirror holder 46 facing the bobbin side magnet 49. Further, the base 44 is provided with an inner yoke 51 and an outer yoke 52, and a magnet 53 is attached to a surface of the outer yoke 52 facing the inner yoke 51. A focusing coil 54 and a tracking coil 55 are attached to the left and right side surfaces of the bobbin 41.
[0083]
Between the inner yoke 51 provided on the base 44 and the outer yoke 52, a part of the winding of the focusing coil 54 provided on the side surface of the bobbin 41 is disposed. A tracking coil 55 is disposed to face the magnet 53 attached to the yoke 52.
[0084]
The tracking hinge member 43 includes a movable member 43a to which the parallel link member 45 is connected, a fixed portion 43b fixed to the base 44, and a tracking formed at a connecting portion between the movable member 43a and the fixed member 43b. Hinge part 43c. In addition, the fixing member 43 b is formed with a hole that fits into the pin 56 provided on the base 44.
[0085]
Next, the operation of the present embodiment will be described. In the pickup block 40, a rotating hinge portion 42 is formed integrally with a bobbin 41 that supports the objective lens 21, and a space between the rotating hinge portion 42 and a tracking hinge member 43 that displaces the objective lens 21 in the tracking direction. By connecting the parallel link member 45 and forming a focus hinge portion 45a at the connection portion between the parallel link member 45 and the rotating hinge member 42, the objective lens 21 supported by the bobbin 41 is moved in the tracking direction in the figure. It is supported so that it can be displaced in the focusing direction.
[0086]
In addition, a bobbin side magnet 49 is provided at a position facing the side surface of the reflection mirror 9 of the bobbin 41, and a reflection mirror side magnet 50 is provided on the side surface of the reflection mirror holder 46 facing the bobbin side magnet 49. Is displaced in the tracking direction, an attractive force is generated between the bobbin side magnet 49 and the reflection mirror side magnet 50, and the reflection mirror 9 is also displaced in the tracking direction in the same manner as the objective lens 21.
[0087]
That is, in the pickup block 40, the current is passed through the focusing coil 54 and the tracking coil 55 attached to the left and right side surfaces of the bobbin 41, thereby forming the outer yoke 52, the inner yoke 51 and the magnet 53 provided on the base 44. When the electromagnetic force acts between the magnetic circuit and the focus hinge portion 45a formed at the connecting portion between the rotating hinge portion 42 of the bobbin 41 and the parallel link member 45, the focusing hinge portion 45a is displaced in the focusing direction in FIG. The objective lens 21 supported by the bobbin 41 is displaced in the focusing direction, or the tracking hinge 43 is displaced in the tracking direction, and the objective lens 21 supported by the bobbin 41 is displaced in the tracking direction.
[0088]
When the objective lens 21 is displaced in the tracking direction, the reflection force attached to the reflection mirror holder 46 is caused by the magnetic force between the bobbin side magnet 49 provided on the bobbin 41 and the magnet 50 attached to the reflection mirror holder 46. The mirror tracking leaf spring 47 also bends in the tracking direction, and the reflection mirror 9 is displaced in the tracking direction like the objective lens 21.
[0089]
In this way, when the objective lens 21 is displaced in the tracking direction, it is more powerful that is generated between the bobbin side magnet 49 provided on the bobbin 41 and the reflection mirror side magnet 50 provided on the reflection mirror holder 46. The reflecting mirror 9 is interlocked in a non-contact manner by the suction force, and the reflecting mirror 9 is similarly displaced in the tracking direction, so that the optical axis shift between the objective lens 21 and the reflecting mirror 9 can be reduced.
[0090]
Therefore, it is possible to reduce the occurrence of an offset with respect to the tracking error signal as described above and the reduction in the amount of return light, improve the utilization efficiency of the laser light, and extend the life of the laser diode. Further, the data writing / reading performance with respect to the optical disk of the pickup can be stabilized.
[0091]
Therefore, the reliability of the optical disk player can be improved by mounting the pickup block 40 of the fourth embodiment on the optical disk player.
(Fifth embodiment)
FIG. 10 is a diagram showing a configuration of a pickup block of the fifth embodiment to which the objective lens driving device of the present invention is applied. In the description of the present embodiment, the same components as those of the pickup block 20 shown in FIG. 4 of the second embodiment are denoted by the same reference numerals, and detailed description thereof is omitted.
[0092]
FIG. 10 is a perspective view of a pickup block 60 according to the fifth embodiment. In FIG. 10, in the pickup block 60, the objective lens 21 is supported by an elliptical support member 61, and a shaft 62 is inserted through a substantially central portion of the support member 61. A focus coil 63 inserted through the shaft 62 is fixed to the lower surface of the support member 61, and a tracking coil 64 is attached to the peripheral surface of the focus coil 63. The support member 61 and the shaft 62 function as an objective lens support mechanism 60a as a whole.
[0093]
The support member 61 and the focus coil 63 are supported by the inserted shaft 62 so as to be rotatable about the shaft 62 in the tracking direction in FIG. 10 and slidable in the focusing direction in FIG. Has been. A magnet 65 is attached to a position facing the side surface of the lower reflection mirror 9 on the lower side of the support member 61. A magnet 66 is attached to the side surface of the parallel leaf spring holding member 15 that supports the reflecting mirror 9 facing the magnet 65.
[0094]
A magnetic circuit (not shown) is provided in the vicinity facing the peripheral surfaces of the focus coil 63 and the tracking coil 64. When a current flows through the focus coil 63 and the tracking coil 64, an electromagnetic force is generated between the magnetic coil and the magnetic circuit. As a result, the support member 61 fixed to the focus coil 63 is rotated about the shaft 62, and the objective lens 21 is rotated in the tracking direction in the figure, or is slid in the direction of the shaft 62 to be objective. The lens 21 is moved in the focusing direction in FIG.
[0095]
The parallel leaf spring 10, the parallel leaf spring fixing member 14, and the parallel leaf spring holding member 15 function as a reflection mirror support mechanism 1b as a whole.
[0096]
Next, the operation of the present embodiment will be described. In the pickup block 60, a focus coil 63 and a tracking coil 64 are fixed to a support member 61 that supports the objective lens 21, and a shaft 62 is inserted into the support member 62 and the focus coil 63 to freely rotate in the tracking direction. Supports movement in the cashing direction.
[0097]
In addition, the magnet 65 is provided at a position facing the side surface of the reflection mirror 9 below the support member 61, and the magnet 66 is provided on the side surface of the reflection mirror 9 facing the magnet 65, so that the support member 61 is in the tracking direction. , The reflecting mirror 9 is also displaced in the tracking direction in the same manner as the objective lens 21 due to the attractive force generated by the magnetic lines of force between the magnet 65 and the magnet 66.
[0098]
That is, in the pickup block 60, when a current flows through the focus coil 63 fixed to the lower side of the support member 61 and the tracking coil 64 attached to the peripheral surface of the focus coil 63, the focus coil 63 and the tracking coil 64 are passed. An electromagnetic force acts between a magnetic circuit (not shown) provided in the vicinity of the peripheral surface of the objective lens 21 and the support member 61 fixed to the focus coil 63 is rotated about the shaft 62, so that the objective lens 21 is rotated. Is rotated in the tracking direction in FIG. 10 or slides in the direction of the shaft 62 to move the objective lens 21 in the focusing direction in FIG.
[0099]
When the objective lens 21 is thus displaced in the tracking direction, the reflection mirror 9 is caused by the magnetic force between the magnet 65 provided below the support member 61 and the magnet 66 attached to the side surface of the reflection mirror 9. The parallel leaf spring 10 attached to is also bent in the tracking direction, and the reflection mirror 9 is displaced in the tracking direction in the same manner as the objective lens 21.
[0100]
Therefore, when the objective lens 21 is displaced in the tracking direction, it is reflected in a non-contact manner by the attractive force of the magnetic action generated between the magnet 65 provided on the support member 61 and the magnet 66 provided on the reflection mirror 9. Since the mirror 9 is interlocked and the reflection mirror 9 is similarly displaced in the tracking direction, the optical axis shift between the objective lens 21 and the reflection mirror 9 can be reduced.
[0101]
As a result, it is possible to reduce the occurrence of an offset with respect to the tracking error signal as described above and the reduction in the amount of return light, improve the utilization efficiency of the laser light, and extend the life of the laser diode. Further, the data writing / reading performance with respect to the optical disk of the pickup can be stabilized.
[0102]
In the pickup block 60 of the fifth embodiment, the support member 61 that supports the objective lens 21 is slid by the shaft 62 to displace the objective lens 21 in the focusing direction. For example, as shown in FIG. 11, the reflection mirror 9 may be configured to slide in the tracking direction along the axis.
[0103]
That is, in FIG. 11, the block 71 that supports the reflecting mirror 9 is provided with two holes 71a, and the fixing member 73 provided with the shaft 72 inserted through the hole 71a is fixed to the base 74, and the block 71 is fixed. A shaft 72 is slidably supported, and a magnet 75 is provided on a side surface of the block 71. Then, when the objective lens 21 is displaced in the tracking direction by the objective lens driving mechanism shown in FIG. 10, the magnetic action generated between the magnet 65 provided on the support member 61 and the magnet 75 provided on the reflection mirror 9. Thus, the block 71 slides on the shaft 72 in the tracking direction, and the reflection mirror 9 is moved in the tracking direction in the same manner as the objective lens 21.
(Sixth embodiment)
In each of the second to fifth embodiments, between the iron piece or magnet provided on the bobbin supporting the objective lens or the support member, and the magnet provided on the side surface of the reflection mirror or the reflection mirror holder or block. Therefore, the reflecting mirror cannot be adjusted in the jitter direction, and the followability of the reflecting mirror with respect to the objective lens cannot be adjusted properly.
[0104]
In the sixth embodiment, the reflecting mirror support member can be moved and adjusted in the jitter direction, the reflecting mirror followability can be appropriately adjusted, and stable driving on the servo is possible.
[0105]
FIG. 12 is a diagram showing a configuration of a pickup block according to a sixth embodiment to which the objective lens driving device of the present invention is applied. In the description of the present embodiment, the same components as those of the pickup block 20 of the second embodiment are denoted by the same reference numerals, and detailed description thereof is omitted.
[0106]
FIG. 12 is a partial front sectional view of the pickup block 80 according to the sixth embodiment. In FIG. 12, the pickup block 80 has screw holes 81 a and 81 b in vertical and horizontal portions of an L-shaped fixing member 81 attached to the end of the parallel leaf spring 10 that supports the reflecting mirror 9. The U-shaped base 82 to which the fixing member 81 is fixed has screw holes 82a in the vertical and horizontal portions so that screws can be passed through the screw holes 81a and 81b formed in the fixing member 81. , 82b are opened.
[0107]
The fixing screw 81 is attached to the fixing member 81 according to the amount of the adjustment screw 83 screwed into the screw hole 81a formed in the vertical portion of the base 82 with respect to the screw hole 81a formed in the vertical portion of the fixing member 81 When the parallel leaf spring 10 and the reflection mirror 9 are moved in the jitter direction indicated by the double arrows in FIG. 12, the magnet 26 provided on the side surface of the reflection mirror 9 is moved in the jitter direction in FIG.
[0108]
By adjusting the jitter direction of the reflection mirror 9 by the adjustment screw 83, the distance (indicated by Δl in FIG. 12) between the magnet 34 on the reflection mirror 9 side and the magnet 25 on the opposite bobbin 22 side is adjusted. . After adjusting Δl between the magnets 25 and 26, when the fixing screw 84 is screwed into the screw hole 81b opened in the horizontal portion of the base 82 with respect to the screw hole 81b opened in the horizontal portion of the fixing member 81, The fixing member 81 is fixed to the base 82, and Δl between the magnets 25 and 26 is fixed. In FIG. 12, reference numeral 85 denotes a leaf spring.
[0109]
The bobbin 22, the wire spring 23, and the base 82 function as an objective lens support mechanism 80a, and the parallel leaf spring 10 and the fixing member 81 function as a reflection mirror support mechanism 80b. The fixing member 81, the base 82, the adjusting screw 83, and the fixing screw 84 as a whole adjust the jitter direction so that the position of the reflecting mirror 9 can be adjusted in the jitter direction orthogonal to both the optical axis of the objective lens 21 and the tracking direction. Acts as a mechanism.
[0110]
As described above, in the pickup block 80 of the sixth embodiment, the reflecting mirror support mechanism 80b is moved in the jitter direction by the adjusting screw 83 from the base 82 side with respect to the screw holes 8a and 81b opened in the fixing member 81. The distance between the magnet 25 provided on the side of the reflecting mirror 9 and the magnet 26 on the opposite bobbin 22 side, that is, in FIG. Can be finely adjusted appropriately.
[0111]
Conventionally, when Δl varies due to component dimensions, the magnetic attractive force between the magnets varies, and the tracking characteristics of the reflecting mirror 9 vary, and in particular, when Δl is small due to the characteristics of the magnet, The variation in Δl greatly affected the variation in the attractive force between the magnets.
[0112]
However, in the pickup block 80 of the sixth embodiment, since a Δl adjusting mechanism between the magnets 25 and 26 is provided, Δl is adjusted so that the attractive force between the magnets 25 and 26 is stabilized. Accordingly, it is possible to appropriately set the followability of the reflecting mirror 9 with respect to the objective lens 21, and it is possible to drive the servo stably.
[0113]
Note that the adjustment mechanism of Δl provided in the pickup block 80 shown in FIG. 12 of the sixth embodiment is not limited to the adjustment mechanism shown in FIG. The adjustment mechanism shown in FIG. 13 is provided with a screw hole 91a and an adjustment long hole 91b in the horizontal portion of the fixing member 91 of the reflection mirror, and a recess 94a is formed in the base 94 at a position where the fixing member 91 is fixed. Screw holes 94b and holes 94c corresponding to the screw holes 91a and the long holes 91b formed in the fixing member 91 are formed in the recess 94a.
[0114]
The screw 92 is screwed into the screw hole 91a formed in the fixing member 91, and the pin portion 93a of the eccentric pin 93 is passed through the hole 94c of the base 94 through the long hole 91b, thereby rotating the eccentric portion 93a of the eccentric pin 93. it can. Therefore, when adjusting Δl, after fixing the eccentric portion 93a of the eccentric pin 93 to the elongated hole 91b and the hole 94c of the base 94 through the pin portion 93b of the eccentric pin 93, the fixing member 91 is moved in the jitter direction. Can be moved to. Then, after adjusting Δl, the fixing member 91 is fixed by screwing the fixing screw 92 into the screw hole 91 a of the fixing member 91 and the screw hole 94 b of the base 94.
(Seventh embodiment)
14 and 15 are views showing a seventh embodiment of the objective lens driving device of the present invention. In the description of this embodiment, the same components as those of the second embodiment shown in FIG. 4 are denoted by the same reference numerals, and detailed description thereof is omitted.
[0115]
FIG. 14 is an exploded perspective view of a pickup block 100 to which the objective lens driving device of the present invention is applied. The pickup block 100 includes an objective lens 21 supported by a bobbin 22 and a bobbin 22 having four wire springs 23. Thus, the support member 24 is connected. A tube-like elastic member (tube-like elastic body) 101 is attached to the side surface of the bobbin 22 on the reflection mirror 9 side. The tube-like elastic member 101 is made of, for example, tube-like rubber, and is focused. As shown in FIG. 15, the cylindrical center axis is attached to the bobbin 22 so that the spring constant in the direction is low and the spring constant in the tracking direction is high. The tubular elastic member 101 has an adhesive surface 101a in which an adhesive is applied to the surface on the reflection mirror 9 side, and when the pickup block 101 is assembled as shown in FIG. The bonding surface 101 a of the member 101 is bonded to the reflection mirror 9.
[0116]
As shown in FIG. 16, the support member 24 is fixed by screwing a screw 102 penetrating the hole 24 a into a screw hole 104 a of the fixing member 104 fixed to the base 103.
[0117]
The reflection mirror 9 is attached to a parallel leaf spring holding member 105, and one end of a pair of parallel leaf springs 106 is fixed to the parallel leaf spring holding member 105. The other end of the pair of parallel plate springs 106 is fixed to a fixing member 107 formed on the base 103, and the reflection mirror 9 includes a fixing member 107, a pair of parallel plate springs 106 in parallel and a parallel plate spring holding member. It is held via 105 via a displacement in the tracking direction. Therefore, the bobbin 22, the wire spring 23, and the support member 24 function as the objective lens support mechanism 100a, and the parallel plate spring holding member 105, the parallel plate spring 106, and the fixing member 107 function as the reflection mirror support mechanism 100b. .
[0118]
Next, the operation of the present embodiment will be described. In the pickup block 100, when a focusing force is applied in a focusing direction by a focus drive mechanism (not shown), the wire spring 23 holding the bobbin 22 bends upward or downward, and the objective lens 21 held by the bobbin 22 moves upward. Alternatively, it is displaced in the downward focusing direction.
[0119]
Furthermore, when a force in the tracking direction is applied to the bobbin 22 by a tracking drive mechanism (not shown), the bobbin 22 is pulled rightward or leftward and the wire spring 23 is bent, so that the objective lens 21 is moved in the tracking direction in FIG. Is displaced.
[0120]
Thus, when the objective lens 21 is displaced in the tracking direction, the tubular elastic member 101 provided on the bobbin 22 is fixed to the reflecting mirror 9 and the reflecting mirror 9 is held by the parallel leaf spring 106. The reflecting mirror 9 is displaced following the tracking direction by the elasticity of the tubular elastic member 101 and the elasticity of the parallel leaf spring 106.
[0121]
When the objective lens 21 is displaced in the focusing direction, similarly, the reflection mirror is fixed to the tubular elastic member 101 attached to the bobbin 22, and the reflection mirror 9 is held by the parallel leaf spring 106. However, since the spring constant of the tubular elastic member 101 is set high in the tracking direction and low in the focusing direction, the objective lens 21 reflecting mirror 9 follows the tracking direction due to the elasticity of the tubular elastic member 101. To be displaced.
[0122]
Since the spring constant of the tubular elastic member 101 is set high in the tracking direction and low in the focusing direction as described above, the followability of the reflecting mirror 9 in the tracking direction can be improved. The driving current of the focusing drive mechanism in the focusing direction can be reduced.
[0123]
In this embodiment, the bobbin 22 that holds the objective lens 21, the parallel leaf spring holding member 105 that holds the objective lens 9, and the parallel leaf spring 106 are attached to the opposite sides of the base 103. However, as shown in FIG.17 and FIG.18, you may attach to the one side of the base 103 collectively.
[0124]
That is, as shown in FIGS. 17 and 18, in the pickup block 110, a pair of parallel leaf springs 106 is attached to a fixing member 111 fixed to one side of the base 103, and the other end of the parallel leaf spring 106 is A reflection mirror 9 is attached via a parallel leaf spring holding member 105. A magnet 113 of a tracking / focusing drive mechanism 112 is attached to the fixed member 111, and a magnet 114 and a coil 115 of the tracking / focusing drive mechanism 112 are mounted on the base 103 at a position facing the magnet 112. It is arranged.
[0125]
The bobbin 22 that holds the objective lens 21 is connected and held to a support member 24 by a wire spring 23, and the support member 24 is fixed to the fixing member 111 by a screw (not shown) that passes through the hole 24a. .
[0126]
A tubular elastic member 101 is attached to the surface of the bobbin 22 on the reflection mirror 9 side, and the tubular elastic member 101 is bonded to a parallel leaf spring holding member 105 to which the reflection mirror 9 is attached.
[0127]
Therefore, according to the pickup block 110, the same effect as that of the pickup block 100 can be obtained, and even when the inclination of the tracking / focusing drive mechanism 112 is adjusted, the reflection mirror 9 is not inclined and the objective lens 21 is not inclined. It is possible to prevent the laser light incident on the light from being inclined.
[0128]
As mentioned above, although each invention made | formed by this inventor was concretely demonstrated based on each suitable embodiment, this invention is not limited to said thing, A various change is possible in the range which does not deviate from the summary. Needless to say.
[0129]
【The invention's effect】
BookAccording to the objective lens driving device of the invention, the objective lens support mechanism that supports the objective lens that condenses and irradiates light onto the optical disk surface so as to be movable in the tracking direction and the focusing direction, and the light incident from the tracking direction is focused. A reflection mirror support mechanism that supports the reflection mirror that reflects in the direction and enters the objective lens so as to be movable in the tracking direction;With elastic bodyWhen the objective lens supported by the objective lens support mechanism moves in the tracking direction in cooperation with the linkage means, the reflection mirror supported by the reflection mirror support mechanism moves in association with the tracking direction.Simple structure and low costThe followability of the movement of the reflecting mirror in the tracking direction with respect to the movement of the objective lens in the tracking direction can be improved, and the amount of deviation of the optical axis can be reduced.
[0131]
BookAccording to the objective lens driving device of the invention, the objective lens support mechanism and the reflection mirror support mechanism are linked by the tube-like elastic body, and the center line of the tube-like elastic body in the cylinder direction is made coincident with the tracking direction. The elastic constant in the direction can be increased, the elastic constant in the focusing direction can be decreased, the followability of the reflecting mirror to the objective lens can be improved, and the driving current in the focusing direction can be reduced.
[0132]
BookAccording to the objective lens driving device of the present invention, the objective lens support mechanism and the reflection mirror support mechanism are separated from each other with a magnetized member such as an iron piece attached to one of the objective lens support mechanism and the magnetized member at a predetermined interval. And the magnetic member attached to the other of the reflecting mirror support mechanism, the objective lens and the reflecting mirror can be moved in the tracking direction in a non-contact manner, and are stable against environmental changes such as temperature changes. The followability of the reflecting mirror with respect to the objective lens can be improved. As a result, the amount of deviation of the optical axis can be further reduced.
[0133]
BookAccording to the objective lens driving device of the invention, the objective lens support mechanism and the reflection mirror support mechanism are attached to one of them, the first magnet disposed with its magnetic pole dividing line coinciding with the focusing direction, and the objective lens The other one of the support mechanism and the reflection mirror support mechanism is attached to the first magnet so as to be opposed to each other at a predetermined interval, and the magnetic pole dividing line is disposed so as to coincide with the focusing direction, and the first is opposed to the polarity. Since the second magnet having a polarity opposite to that of the magnet is linked with the second magnet, the tracking performance of the reflecting mirror with respect to the objective lens can be further improved by a strong attraction force in the tracking direction, and focusing. The driving current in the direction can be reduced.
[0134]
BookAccording to the objective lens driving device of the present invention, since it further includes a jitter direction adjusting mechanism capable of adjusting the position of the reflecting mirror in the jitter direction orthogonal to both the optical axis and the tracking direction of the objective lens, The distance between the members or the distance between the opposing magnets can be adjusted, and these attractive forces can be stabilized to further improve the followability of the reflecting mirror with respect to the objective lens.
[Brief description of the drawings]
FIG. 1 is an exploded perspective view of a pickup block mounted on an objective lens driving device to which a first embodiment of an objective lens driving device of the present invention is applied.
FIG. 2 is a partial plan view of a plane of a linkage portion that links the reflection mirror of FIG. 1 and a tracking holding member.
3 is a plan view showing another example of a linkage portion that links the reflection mirror and the tracking holding member of FIG. 1; FIG.
FIG. 4 is an exploded perspective view of a pickup block mounted on an objective lens driving device to which a second embodiment of the objective lens driving device of the present invention is applied.
FIG. 5 is a perspective view of a reflection lens portion of a pickup block mounted on an objective lens driving device to which a third embodiment of the objective lens driving device of the present invention is applied.
6 is a perspective view showing a state where an objective lens portion is attached to the pickup block of FIG. 5. FIG.
7 is a perspective view showing a magnetic pole arrangement of magnets respectively provided on the bobbin and the reflection mirror of FIG. 5;
FIG. 8 is a partially broken perspective view of a pickup block mounted on an objective lens driving device to which a fourth embodiment of the objective lens driving device of the present invention is applied.
9 is an exploded perspective view of the pickup block of FIG.
FIG. 10 is a perspective view of a pickup block mounted on an objective lens driving device to which a fifth embodiment of the objective lens driving device of the present invention is applied.
11 is an exploded perspective view showing an example of a sliding mechanism of a reflecting mirror with respect to the objective lens of FIG.
FIG. 12 is a front partial cross-sectional view of a pickup block mounted on an objective lens driving device to which a sixth embodiment of the objective lens driving device of the present invention is applied.
13 is an exploded perspective view of a fixing member adjusting mechanism of another example of the reflecting mirror fixing member adjusting mechanism of FIG. 12; FIG.
FIG. 14 is an exploded perspective view of a pickup block mounted on an objective lens driving device to which a seventh embodiment of the objective lens driving device of the present invention is applied.
15 is an enlarged perspective view of the tubular elastic member of FIG.
16 is a partial front sectional view of the pickup block of FIG. 14;
17 is a perspective view showing another example of the pickup block of FIG. 14;
18 is an exploded perspective view of the pickup block of FIG.
FIG. 19 is a diagram illustrating a relationship between a conventional objective lens, a reflection mirror, and an optical axis.
[Explanation of symbols]
1, 20, 30, 40, 50, 60, 80, 100 Pickup block
1a, 20a, 30a, 40a, 50a, 60a Objective lens support mechanism
80a, 100a Objective lens support mechanism
1b, 20b, 30b, 40b, 50b, 60b Reflective mirror support mechanism
80b, 100b Reflective mirror support mechanism
2, 21 Objective lens
3 Focus leaf spring
3a hole
4 Spacer
5 Fixing pin
6 Tracking holding member
7 Hinge leaf spring
8 Hinge leaf spring holding member
9 Reflection mirror
10, 34 Parallel leaf spring
11 Shaft
12, 81 Fixing member
13 Cylindrical elastic member
14 Parallel leaf spring fixing member
14a screw
15, 35 Parallel leaf spring holding member
22, 41 Bobbins
23 wire spring
24, 61 Support member
25 Shingles
26, 36, 37 Magnet
31 base
32, 33, 48 Fixing member
42 Rotating hinge
43 Tracking hinge member
44 base
45 Parallel link members
45a Focus hinge
46 Reflective mirror holder
47 Reflector mirror tracking leaf spring
49 Bobbin side magnet
50 Reflective mirror side magnet
51 inner yoke
52 Outer York
53, 65, 66, 75 Magnet
54 Focusing coil
55 Tracking coil
56 pins
62 axes
63 Focus coil
64 Tracking coil
71 blocks
71a hole
72 axes
73 Fixing member
74 base
75 magnet
81a, 81b, 82a, 82b Screw hole
83 Adjustment screw
84 Fixing screw
91 Fixing member
91a Screw hole
91b oblong hole
92 screws
93 Eccentric pin
94 base
94a recess
94b Screw hole
94c hole
101 Tubular elastic member
101a Adhesive surface
102 screws
103 base
104 Fixing member
104a Screw hole
105 Parallel leaf spring holding member
106 Parallel leaf spring
107 Fixing member

Claims (5)

An objective lens support mechanism that supports an objective lens that condenses and irradiates light onto an optical disk surface so as to be movable in a tracking direction and a focusing direction; and the objective lens that reflects light incident from the tracking direction in the focusing direction. A reflection mirror support mechanism for supporting the reflection mirror incident on the lens movably in the tracking direction by two parallel leaf springs extended in the jitter direction , and an objective lens driving device comprising:
The objective lens support mechanism and the reflection mirror support mechanism are linked by a linkage means made of an elastic body attached over both the support mechanisms,
By driving the objective lens support mechanism by a tracking drive mechanism, the objective lens moves in the tracking direction, and
The reflection mirror supported by the reflection mirror support mechanism on a side surface that is a surface opposed to the jitter direction is linked to the tracking direction movement of the objective lens by the tracking drive mechanism and the linking means. Is displaced by the same amount as the objective lens,
2. The objective lens driving device according to claim 1, wherein the displacement reduces an optical axis shift between the objective lens and the reflection mirror. In claim 1,
2. The objective lens driving device according to claim 1, wherein the linking means is a tubular elastic body, and is arranged in a direction in which a center line of the tubular elastic body in the cylindrical direction coincides with the tracking direction. In claim 1,
Instead of the elastic body, the linking means includes a magnetic member such as an iron piece attached to one of the objective lens support mechanism and the reflection mirror support mechanism, and the objective member in opposition to the magnetic member at a predetermined interval. An objective lens driving device comprising: a lens support mechanism; and a magnetic member attached to the other of the reflection mirror support mechanism. In claim 1,
The linking means, instead of the elastic body, is attached to one of the objective lens support mechanism and the reflection mirror support mechanism, and has a first magnet disposed with its magnetic pole dividing line aligned with the focusing direction. The other one of the objective lens support mechanism and the reflection mirror support mechanism is attached to the first magnet so as to face each other at a predetermined interval, and the magnetic pole dividing line is disposed so as to coincide with the focusing direction. An objective lens driving device comprising: a second magnet having a polarity opposite to the polarity of the first magnet facing each other. In claim 3 or 4,
The objective lens driving device further includes a jitter direction adjusting mechanism capable of adjusting a position of the reflecting mirror in a jitter direction orthogonal to both the optical axis of the objective lens and the tracking direction. Drive device.

Images