JP4750826B2 - Optical pickup device - Google Patents

Description

  The present invention relates to a pickup device including a driving device that drives an objective lens for condensing a light beam on an optical disk to record or reproduce information.

  2. Description of the Related Art In recent years, optical disc apparatuses that use an optical disc as an information recording medium, record information such as audio signals and video signals at high density, and reproduce the information have been widely used. In such an optical disk device, an optical pickup device is used for condensing laser light on a recording surface on the optical disk to form a light spot and receiving reflected light from the recording surface.

  The optical pickup device forms a light spot on an optical disk by an objective lens, and controls the position of the light spot by moving the objective lens with high accuracy by an actuator. The actuator performs focusing by controlling the objective lens in the optical axis direction, and performs tracking by controlling in the direction orthogonal to the optical axis. In addition, the light emitted from the light spot is tilt-controlled in accordance with the tilt of the optical disk.

  Patent Document 1 describes an actuator that drives an objective lens, and an example in which a lens holder that holds an objective lens is arranged in the center and includes means for driving in a tracking direction and means for driving in a focus direction. It is shown. The driving means in Patent Document 1 is configured by a tracking coil, a focus coil, and a magnet, and is schematically configured as shown in FIG.

  In FIG. 20, L is an objective lens, Fo is a focus coil, Tr is a tracking coil, and Mg is a magnet. The tracking coil Tr is a vertically wound coil parallel to the surface of the magnet Mg, half of the coil faces the magnet Mg, and the other half is removed from the magnetic flux. This is because when a current is passed through the tracking coil Tr, a reverse current flows on one side and the other side of the annular coil, so if the coil regions on both sides enter the magnetic flux of the magnet Mg, the forces in the opposite directions are generated. It counteracts that they occur and cancel each other, and the driving force decreases.

In such a configuration, since half of the tracking coil Tr is outside the magnetic flux, there is a drawback that the magnetic flux cannot be used effectively. In addition, since the tracking coil Tr has a shape that protrudes to the outside, it has a structure that prevents downsizing and thinning.
Japanese Patent Laying-Open No. 2005-108366 (FIGS. 5 and 6)

  The conventional objective lens driving device cannot effectively use the magnetic flux from the magnet, and has a structure that prevents miniaturization and thinning.

  The present invention has been made in view of the above circumstances, and an object thereof is to provide an optical pickup device that can be reduced in size and thickness.

An optical pickup device according to the present invention includes an objective lens that focuses a light beam on an information recording surface of an optical disc, and at least a Z-axis direction that is a lens optical axis direction of the objective lens and an X-axis that is a radial direction of the optical disc. A drive unit that drives in a direction, and the drive unit extends in a Y-axis direction orthogonal to the Z-axis and the X-axis (where the Z-axis direction is the lens optical axis (Z-axis) direction, the X-axis The direction is the radial direction of the optical disc (tracking direction), the Y-axis direction is the direction perpendicular to the Z-axis and the X-axis), the objective lens attached to one of the bases and provided at the center thereof, and the objective lens The first and second tracking coils arranged symmetrically at both ends with respect to the center and wound around the X axis, and the first and second tracking coils arranged within the first and second tracking coils and wound around the Z axis Focus The first and second tracking coils are inserted from the side opening in the Y-axis direction on both sides, and the first and second tracking coils are inserted into the first and second tracking coils from the side opening in the X-axis direction on both sides. 1, a lens holder assembled by inserting a second focus coil, first and second magnets arranged adjacent to the outside of both ends of the first tracking coil and magnetized in the Y-axis direction, A magnetic field forming portion configured by third and fourth magnets arranged adjacent to the outside of both ends of the second tracking coil and magnetized in the Y-axis direction; and the lens holder attached to the other of the base, And a support member for movably supporting in a magnetic field formed by the first to fourth magnets.

  According to the present invention, the assembly accuracy of the focus coil and the tracking coil can be increased, and the assembly can be easily performed.

  Hereinafter, an embodiment of the present invention will be described with reference to the drawings.

 FIG. 1 is a block diagram showing a configuration of an optical disc apparatus including an optical pickup device of the present invention.

  In FIG. 1, an optical pickup device 11 includes an objective lens 1 and an actuator 2 that is a drive device for the objective lens 1, and faces the optical disc 3. The optical disk 3 is rotated at a constant linear velocity under the control of the motor control circuit 4, and information recording / reproduction with respect to the optical disk 3 is performed by the optical pickup device 11. The optical pickup device 11 is driven in the radial direction of the optical disc 3 by a motor such as a stepping motor, and is supported so as to be movable in the directions of arrows AB. The motor is controlled by a motor control circuit 5.

 The objective lens 1 of the optical pickup device 11 is controlled by the actuator 2 to move in the focusing direction (optical axis direction of the objective lens 1) and in the tracking direction (direction orthogonal to the optical axis of the objective lens 1). Tilt control is performed.

  Information writing to the optical disk 3 is performed by irradiating the optical disk 3 with a light beam emitted from the semiconductor laser 12 via the beam splitter 13 and the objective lens 1, and reading (reading) of information from the optical disk 3 is performed as follows. The reflected light from the optical disk 3 is guided to the photoelectric converter 14 via the objective lens 1 and the beam splitter 13.

  A semiconductor laser 12 that is a light source is driven and controlled by a laser control circuit 6, and a constant level of laser light modulated in accordance with recording information is condensed on the optical disc 3 via the beam splitter 13 and the objective lens 1. Information is recorded on the optical disc 3.

  The laser light reflected by the optical disk 3 is bent backward by the beam splitter 13 through the objective lens 2 and enters the photoelectric converter 14. The photoelectric converter 14 includes a photodetector, converts the detected light into an electric signal, and supplies the electric signal to the signal processing circuit 7. The signal processing circuit 7 outputs a signal for data reproduction based on the output signal of the photoelectric converter 14 and outputs a signal for focus control and a signal for tracking control.

  A signal for focus control is supplied to the actuator 2 via the focus control circuit 8. A tracking control signal is supplied to the actuator 2 via the tracking control circuit 9. Further, a tilt control circuit 10 is provided to control the tilt of the light emitted from the light spot with respect to the tilt of the optical disc 3, and a tilt correction signal is supplied to the actuator 2.

  The objective lens 1 is supported by an actuator 2 so that focus control, tracking control, and tilt control are possible. Each coil (described later) for controlling the focus, tracking, and tilt of the objective lens 1 is provided. The printed wiring board 15 is connected via a flexible printed wiring board 16.

  The semiconductor laser 12 is also connected to the printed wiring board 15 via the flexible printed wiring board 17, and the photoelectric converter 14 is electrically and mechanically connected to the printed wiring board 15. As a result, the optical pickup device 11 can be electrically connected to the outside via the printed wiring board 15 to control the semiconductor array 12 and the actuator 2 and to extract a signal generated by the photoelectric converter 14. it can. Reference numeral 100 denotes a controller including a CPU, which controls the exchange of information with each unit and the operation of each unit via the bus 200.

  Next, the configuration of the actuator 2 that is a driving device of the objective lens 1 of the optical pickup device will be described with reference to FIGS.

  2 is a perspective view showing the appearance of the actuator 2, FIG. 3 is a plan view and a side view of the actuator 2, and FIG. 4 is a plan view and a side view showing the arrangement of magnets and coils in the actuator 2. FIG.

  2 to 4, reference numeral 21 denotes a metal base serving as a fixing member. One end of the base 21 is fixed to the wire holder 22. The wire holder 22 integrally includes a main body 221 and a fixing plate 222 for attaching one end of the metal base 21, and one end of a plurality of (for example, six) wires 23 is attached to the main body 221. . The wires 23 are made of a conductive material having elasticity and are formed in a rod shape, extending in parallel three by three, and supporting the lens holder 24 at the tip portion thereof.

  A printed board 223 is attached to one end of the wire holder 22, and one end of the flexible printed wiring board 16 is connected to the printed board by a connector or the like, and one end of each wire 23 passes through the wire holder 22. The printed circuit board 223 is electrically connected to the flexible printed circuit board 16. The other end of the flexible printed wiring board 16 is connected to the printed wiring board 15.

  The other ends of the plurality of wires 23 penetrate the protruding piece 241 of the lens holder 24, and the other ends are electrically connected to a coil (described later). The lens holder 24 has a lens attachment portion 242 for attaching the objective lens 1 at the center thereof, and has a coil attachment portion 243 so as to sandwich the objective lens 1. The lens holder 24 is movably supported by the wire 23, and the objective lens 1 is focused on the base 21 in the focus direction (lens axis direction: Z-axis direction) and the tracking direction (X-axis direction) that is the radial direction of the optical disc 3. ) Is shiftable. Moreover, it is supported so that tilt control is possible.

  As shown in FIG. 4, a pair of focus coils 26 a and 26 b and a pair of tracking coils 27 a and 27 b are attached to the lens attachment portion 242 diagonally symmetrically with respect to the objective lens 1. The tilt control coil is wound around the focus coils 26a and 26b. On the other hand, four magnets 29a to 29d used for driving the objective lens 1 in the focus direction and the tracking direction are attached to the base 21.

  FIG. 4 is a diagram in which the lens holder 24 is omitted. The focus coil 26a and the tracking coil 27a are located between the magnets 29a and 29b, and the tracking coil 27b and the focus coil 26b are located between the magnets 29c and 29d. ing.

  In the following description, the focus coils 26a and 26b are collectively referred to as the focus coil 26, the tracking coils 27a and 27b are collectively referred to as the tracking coil 29, and the magnets 29a to 29d are collectively referred to as the magnet 29. is there.

  The magnets 29a to 29d form a magnetic field, and a part of the focus coil 26 and the tracking coil 27 is exposed to the magnetic field, and controls the magnitude and direction of the current flowing through the focus coil 26 and the tracking coil 27. Thus, the lens holder 24 (objective lens 1) can be shifted in the focus direction and the tracking direction. Further, the objective lens 1 can be tilt-controlled by controlling the magnitude and direction of the current passed through the tilt coil (not shown) wound around the focus coil 26 in multiple layers.

  Thus, the lens holder 24 supported by the wire 23, the focus coil 26, the tracking coil 27, the tilt coil, and the like attached thereto constitute a movable part together with the objective lens 1.

  Next, an arrangement example of the focus coil 26 and the tracking coil 27 in the actuator 2 of the present invention will be described in detail.

  FIG. 5 shows the arrangement of the focus coil 26, the tracking coil 27, and the magnet 29. The metal base 21 has one end 211 fixed to the wire holder 22, and the other end 212 has a U-shaped yoke 213. The magnets 29a to 29d are fixed to the inside of the yoke 213 facing each other. The one end portion 211 and the other end portion 212 are integrated by a connecting portion 214, and a yoke 215 rising from the base 21 is provided between the magnets 29a and 29b and between the magnets 29c and 29d.

  Although the focus coils 26a and 26b and the tracking coils 27a and 27b are fixed to the lens holder 24, in order to make the arrangement and structure of each coil easy to understand, the lens holder 24 is shown by a one-dot chain line in FIG. The focus coils 26a and 26b have a lateral winding structure wound around the Z-axis, are arranged near the magnets 29a and 29c located diagonally, and a yoke 215 penetrates through the central portion thereof. Further, the tracking coils 27a and 27b have a vertically wound structure wound around the Y axis, and are arranged near the magnets 29b and 29d positioned diagonally.

  Further, the magnets 29a and 29c adjacent to the focus coils 26a and 26b are respectively magnetized in the Y direction, and the magnets 29b and 29d adjacent to the tracking coils 27a and 27b are respectively magnetized in the X axis direction.

  FIG. 6 is a schematic diagram of the actuator 2 of the present invention described above, and shows the positional relationship between the magnetic poles of the magnets 29a to 29d and the focus coils 26a and 26b and the tracking coils 27a and 27b.

  In this arrangement, when a current is passed counterclockwise through the focus coils 26a and 26b, a driving force is generated in the Z-axis direction in accordance with Fleming's law, and the movable part including the lens holder 24 supported by the wire 23 Moves upward in the Z-axis by the Lorentz force generated from the magnetic flux and current. Conversely, when a current is passed clockwise in the Z axis, the movable part moves downward in the Z axis.

  On the other hand, when a clockwise current in the Y-axis is passed through the tracking coils 27a and 27b, a driving force in the X-axis direction is generated, and the movable portion moves in the + X-axis direction (left direction in the figure). On the other hand, when a current flowing counterclockwise in the Y-axis is passed, the movable portion moves in the −X-axis direction (right direction in the drawing). Further, the movable portion can be tilt-controlled by controlling the magnitude and direction of the current flowing through the tilt coil wound around the focus coil 26 in multiple layers.

  With such a magnet arrangement and coil arrangement, it is not necessary to release half of the tracking coil out of the magnetic flux as in the prior art, so that the magnetic flux can be used effectively. Therefore, a sufficient driving force can be obtained even if the driving component is downsized. Also, the width of the movable part can be reduced in terms of shape, and it can be made small and thin. By reducing the size, the driving force can be increased by the amount that the weight of the movable part is reduced.

  That is, when the conventional example (FIG. 20) is compared with the present invention, the conventional tracking coil is arranged to be about half of the magnetic field of the magnet. For this reason, in order to ensure the required movable range of a movable part, the width | variety is needed for the part which protruded. On the other hand, in the present invention, since the tracking coil 27 and the focus coil 26 are on the Y axis connecting the centers of the magnets 29a and 29b, the protrusion can be eliminated. Therefore, the magnetic flux can be effectively used and the size can be reduced.

  7 to 12 show some modified examples of the embodiment of the optical pickup device of the present invention. (A) is a plan view of the actuator 2 and (b) is a side view of the actuator 2. FIG. In the following description, the focus coil 26a, the tracking coil 27a, and the magnets 29a and 29b will be mainly described for convenience. The other pair of the focus coil 26b, the tracking coil 27b, and the magnets 29c and 29d are not shown. .

  In FIG. 7, a magnet 29a magnetized in the Y-axis direction is arranged adjacent to the focus coil 26a wound around the Z-axis, but the tracking coil 27a has a structure wound around the X-axis. The difference is that the magnet 29b arranged adjacent to the tracking coil 27a is magnetized in the Y-axis direction in the X-axis direction.

  The focus coil 26b and tracking coil 27b, which are the other pair, are arranged in a diagonally symmetrical manner with respect to the focus coil 26a and tracking coil 27a. Also in this configuration, the magnetic flux can be used effectively, and the shape can be reduced in size and thickness.

  In FIGS. 8A and 8B, two focus coils 26a wound around the Z axis are arranged in the tracking coil 27a wound around the X axis, and the Y axis is adjacent to the tracking coil 27a. Magnets 29a and 29b magnetized in the direction are arranged. FIG. 8C is a perspective view in which the focus coil 26a and the tracking coil 27a are combined. Since the configuration of FIG. 8 is symmetrical with respect to the X axis, the other pair of focus coil 26b, tracking coil 27b, and magnets 29c and 29d are arranged symmetrically with respect to the Y axis. That is, it becomes diagonally symmetric with the objective lens 1 as the center.

  Further, as shown in FIG. 8D, the focus coil 26 may have a trapezoidal shape with a wide magnet side and a narrow opposite side. In the configuration of FIG. 8D, since the effective area of the magnetic flux is widened by increasing the width on the magnet side, the driving force can be increased.

  9A and 9B, two tracking coils 27a wound around the X axis are arranged in the focus coil 26a wound around the Z axis, and the Y axis is adjacent to the focus coil 26a. Magnets 29a and 29b magnetized in the direction are arranged. FIG. 9C is a perspective view in which the focus coil 26a and the tracking coil 27a are combined. Since the configuration in FIG. 9 is symmetrical with respect to the X axis, the other pair of focus coil 26b, tracking coil 27b, and magnets 29c and 29d are arranged symmetrically with respect to the Y axis.

  Furthermore, as shown in FIG. 9D, the tracking coil 27a may have a trapezoidal shape with a wide magnet side and a narrow opposite side. By increasing the width on the magnet side, the effective area for the magnetic flux is widened, and the driving force can be increased.

  10A and 10B, the focus coil 26a wound around the Z axis is arranged in the tracking coil 27a wound around the X axis, and two of these configurations are arranged in the Y axis direction. Magnets 29a and 29b magnetized in the Y-axis direction are arranged adjacent to the tracking coil 27a. Since the configuration of FIG. 10 is symmetrical with respect to the X axis, the other pair of focus coil 26b, tracking coil 27b, and magnets 29c and 29d are arranged symmetrically with respect to the Y axis.

  In FIGS. 11A and 11B, a tracking coil 27a wound around the X axis is arranged in the focus coil 26a wound around the Z axis, and two of these configurations are arranged in the Y axis direction. Magnets 29a and 29b magnetized in the Y-axis direction are arranged adjacent to the focus coil 26a. Since the configuration of FIG. 11 is also symmetric with respect to the X axis, the other pair of focus coil 26b, tracking coil 27b, and magnets 29c and 29d can be arranged symmetrically with respect to the Y axis.

  12 (a) and 12 (b), a tracking coil 27a wound around the X axis is arranged in the focus coil 26a wound around the Z axis, and a tracking coil 27a 'wound around the X axis. A focus coil 26a 'wound around the Z-axis is arranged in the inside.

  These are arranged in the Y-axis direction, and magnets 29a and 29b magnetized in the Y-axis direction are arranged adjacent to the focus coil 26a and the tracking coil 27a ', respectively. In the case of the configuration of FIG. 12, the other pair of focus coil 26b, tracking coil 27b, and magnets 29c and 29d must be arranged diagonally symmetrically.

  In the configurations of FIGS. 8 to 11, the driving force of the coil close to the magnet 29 is higher, so that the driving force of either focus or tracking is higher. However, in the configuration of FIG. A good driving force can be secured.

  As described above, according to the first embodiment of the present invention, the magnetic flux can be used effectively, and a sufficient driving force can be obtained even if the driving component is downsized. Also, the width of the movable part can be reduced in terms of shape, and it can be made small and thin.

  Next, a second embodiment of the present invention will be described with reference to FIGS. FIG. 13 is a perspective view showing an appearance of the actuator 2 of the optical pickup device according to the second embodiment, FIG. 14 is a plan view and a side view, and FIG. 15 is an arrangement of magnets and coils with the lens holder 24 omitted. It is a top view and a side view.

  13 to 15, the configuration of the metal base 21, the wire holder 22, and the wire 23 is substantially the same as that in FIG. Thus, it is possible to shift in the focus direction (Z-axis direction) and the tracking direction (X-axis direction). Moreover, it is supported so that tilt control is possible.

  13 and 14, the configuration of the lens holder 24 is characteristic. As shown in FIG. 15, a tracking coil 27 is disposed in the focus coil 26, and the Y-axis direction is adjacent to the coils 26 and 27. The magnet 29 magnetized in is arranged. The focus coil 26 is horizontally wound around the Z axis, and the tracking coil 27 is vertically wound around the X axis.

  16 and 17 are exploded perspective views showing in detail the configuration of the lens holder 24, the focus coil 26, and the tracking coil 27. FIG.

  As shown in FIG. 16, the lens holder 24 includes a protruding piece 241 through which the wire 23 penetrates, a lens attachment portion 242, and a coil attachment portion 243.

  The coil attachment portion 243 is provided symmetrically in the tracking direction (X-axis direction) with the lens attachment portion 242 as the center, the focus coil 26 is inserted from the side surface of the lens holder 24 in the Y-axis direction, and the tracking coil 27 is inserted in the Z-axis direction. A series of openings 24a and 24b are formed from the side surface in the Y-axis direction to the upper surface of the lens holder 24 so as to be inserted in the direction.

  As shown in FIG. 17, the focus coil 26 is first inserted from the side surface in the Y-axis direction of the openings 24a and 24b, and then the upper surface side of the openings 24a and 24b is inserted into the cavity in the Z-axis direction of the inserted focus coil 26. The tracking coil 27 is inserted and assembled. With such a configuration, the assembly accuracy of the focus coil 26 and the tracking coil 27 is high, and the assembly is facilitated.

  Further, since the magnetic flux from the magnet can be used effectively as in the previous embodiment, a sufficient driving force can be obtained even if the driving component is downsized. Also, the width of the movable part can be reduced in terms of shape, and it can be made small and thin.

  FIG. 18 is a schematic diagram of the actuator 2 described above. (A) is a plan view and (b) is a side view showing the positional relationship between the magnetic poles of the magnets 29a and 29b, the focus coil 26, and the tracking coil 27. FIG. 18C is a perspective view showing the positional relationship between the focus coil 26 and the tracking coil 27. Note that the tracking coil 27 divided as shown in FIG. 9 can also be used.

  Further, FIGS. 19A and 19B are modifications of FIG. 18, in which a focus coil 26 wound around the Z axis is inserted into the tracking coil 27 wound around the X axis, and tracking is performed. Magnets 29 a and 29 b magnetized in the Y-axis direction are arranged adjacent to the coil 27.

  FIG. 19C is a perspective view in which the focus coil 26 and the tracking coil 27 are combined. Note that the divided focus coil 26 as shown in FIG. 8 may be used.

  In the example of FIG. 19, a continuous opening is formed on the outer wall surface in the X-axis direction from the side surface in the Y-axis direction of the lens holder 24, and the tracking coil 27 is inserted from the side surface in the Y-axis direction of the opening. The coil 26 is inserted from the side surface of the opening in the X-axis direction (lateral direction). In order to insert the focus coil 26 from the lateral direction, it is necessary to provide an opening in the lateral outer wall surface of the coil mounting portion 243. For example, the position of the protruding piece 241 to which the wire 23 is attached is shifted to the wire holder 22 side, or the focus It is necessary to devise such as forming the protruding piece 241 separately from the lens holder 24 so that the protruding piece 241 can be fixed to the lens holder 24 after the coil 26 is inserted.

  Further, a continuous opening may be formed from the inner wall surface in the X-axis direction of the coil mounting portion 243 to the side surface in the Y-axis direction, and the focus coil 26 may be inserted into the opening from the inner wall surface. In this case, the space between the inner wall surfaces of the two coil attachment portions 243 and 243 formed below the lens attachment portion 242 can be used effectively.

  In the case of the example shown in FIGS. 16 to 19, openings 24a and 24b are formed on the side surface in the Y-axis direction of the lens holder 24, and the coil 26 (27) can be inserted from either side in the Y-axis direction. Can be accurately and easily performed, and the coil 26 (27) to be inserted can be formed in the same size as the size between both side surfaces of the lens holder 24 in the Y-axis direction, so that the lens holder 24 and thus the actuator 2 can be kept small. Sufficient driving force can be obtained.

  The present invention is not limited to the above-described embodiment, and various modifications can be made without departing from the scope of the claims. For example, as for the tilt coil, two sets similar to the focus coil are prepared, one is used as the focus coil, the other is used as the tilt coil, and the winding of the tilt coil arranged on the left and right with the objective lens 1 as the center is used. Tilt correction can be performed by appropriately setting the direction and the like so that the driving force is reversed left and right. Further, the tilt coil can be wound in multiple layers when creating the focus coil, and the portion added to the multilayer can be used as the tilt coil.

1 is a block diagram showing an optical disk device using an optical pickup device of the present invention. The principal part perspective view which shows the structure of one Embodiment of the optical pick-up apparatus of this invention. The top view and side view of the objective-lens drive device used for the optical pick-up apparatus of the embodiment. The top view and side view which show the principal part structure of the objective lens drive device used for the embodiment. The perspective view which shows the principal part structure of the objective lens drive device used for the embodiment. The top view explaining operation | movement of the objective lens drive device used for the embodiment. The top view and side view which show the modification of the objective lens drive device used for the embodiment. The top view, side view, and principal part perspective view which show the modification of the objective lens drive device used for the embodiment. The top view, side view, and principal part perspective view which show the modification of the objective lens drive device used for the embodiment. The top view and side view which show the modification of the objective lens drive device used for the embodiment. The top view and side view which show the modification of the objective lens drive device used for the embodiment. The top view and side view which show the modification of the objective lens drive device used for the embodiment. The perspective view which shows the structure of the objective lens drive device in other embodiment of the optical pick-up apparatus of this invention. The top view and side view of the objective lens drive device used for other embodiment. The top view and side view which show the principal part structure of the objective lens drive device used for other embodiment. The disassembled perspective view which shows the principal part structure of the objective lens drive device used for other embodiment. The perspective view which shows the assembly state of FIG. The top view which shows the modification of the objective lens drive device used for other embodiment, a side view, and a principal part perspective view. The top view which shows the modification of the objective lens drive device used for other embodiment, a side view, and a principal part perspective view. The top view for demonstrating operation | movement of the conventional objective lens drive device.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Objective lens 2 ... Actuator (objective lens drive device)
DESCRIPTION OF SYMBOLS 3 ... Optical disk 11 ... Optical pick-up apparatus 12 ... Semiconductor laser 13 ... Beam splitter 14 ... Photoelectric converter 15 ... Printed wiring board 16, 17 ... Flexible printed wiring board 21 ... Base 22 ... Wire holder 23 ... Wire 24 ... Lens holder 242 ... Objective Lens mounting part 243 ... Coil mounting part 26a, 26b ... Focus coil 27a, 27b ... Tracking coil 29a, 29b, 29c, 29d ... Magnet

Claims (1)

An objective lens for condensing a light beam on the information recording surface of the optical disc; and a drive device for driving the objective lens in at least the Z-axis direction that is the optical axis direction of the lens and the X-axis direction that is the radial direction of the optical disc. , The driving device is
Base extending in the Y-axis direction orthogonal to the Z-axis and X-axis (where the Z-axis direction is the lens optical axis (Z-axis) direction, the X-axis direction is the radial direction of the optical disk (tracking direction), and the Y-axis direction is Z axis, direction orthogonal to X axis),
The objective lens attached to one of the bases and provided at the center thereof, first and second tracking coils that are symmetrically arranged at both ends around the objective lens and wound around the X axis, and the first The first and second focus coils are disposed in the second tracking coil and wound around the Z-axis, and the first and second tracking coils are formed from side openings in the Y-axis direction on both sides. A lens holder that is inserted and assembled by inserting the first and second focus coils into the first and second tracking coils from the side opening in the X-axis direction on both sides;
The first and second magnets arranged adjacent to the outside of both ends of the first tracking coil and magnetized in the Y-axis direction, and the Y-axis arranged adjacent to the outside of both ends of the second tracking coil A magnetic field forming section constituted by third and fourth magnets magnetized in the direction;
A support member attached to the other side of the base and movably supporting the lens holder in a magnetic field formed by the first to fourth magnets;
An optical pickup device comprising:

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