JPH08263860A - Objective lens driving device - Google Patents

Abstract

PURPOSE: To suppress a resonance sharpness while making a constitution simple, to mitigate the influence due to component accuracies and an assembly accuracy and to maintain reliability with respect to a secular change and a temp. change. CONSTITUTION: This device is constituted of a bobbin 5 supporting an objective lens 4, a focusing coil 16, a tracking coil 17, and a magnetic circuit part consisting of a magnet 12 and a yoke 8 and is provided with a driving means drivingly shifting the objective lens 4 in a focusing direction and a tracking direction, plural elastic supporting members 7 supporting the bobbin 5, a supporting holder 9 constituting a fixing part and a substrate 10 fitted to the supporting holder 9 and in which one end part of the elastic members 7 are fixed. The area 10A of the substrate 10 in which the one end part of the elastic members 7 are fixed is fitted to the fitting part 9c of the supporting holder 9 as a non-fixing part.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an objective lens driving device provided in an optical disk recording and / or reproducing apparatus such as an optical disk player.

[0002]

2. Description of the Related Art In an optical disk recording and / or reproducing apparatus such as an optical disk player using an optical disk as a recording medium, an objective lens that collects a light beam emitted from a light source such as a semiconductor laser and irradiates the optical disk with an optical disk is used. An objective lens driving device for driving and displacing in a focusing direction which is a direction parallel to the axis and a tracking direction which is a direction orthogonal to the optical axis is provided.

That is, this objective lens driving device drives and displaces the objective lens in the focusing direction and the tracking direction in accordance with the focusing error signal and the tracking error signal, and thereby the signal of the optical disc which is rotationally driven by the disc rotation driving device. The light beam applied to the recording surface through the objective lens is accurately focused and the light beam is controlled so as to follow the recording track formed on the optical disc.

For example, a conventional objective lens driving device 50
As shown in FIG. 13, a focusing coil 53 is attached to a bobbin 52 holding an objective lens 51, and tracking coils 54 are joined to both side surfaces. The bobbin 52 is attached to the printed circuit board 5
The one end of each of the four metal wires 56 covered with the rubber tube 55 is joined to the wire 7 to be supported. The other end of the metal wire 56 is joined to a printed circuit board 58 fixed to a base 60 with a screw 59. The base 60 is
It is made of a magnetic material and has two magnets 61.
Are provided to form a magnetic circuit.

In the objective lens driving device 50, a current is supplied from the printed circuit board 58 side to the focusing coil 53 and the tracking coil 54 through the metal wire 56, and the base 60 and the magnet 61 are electromagnetically acted to each other. The bobbin 52 is driven and displaced, and the objective lens 51 is driven in the focusing direction and the tracking direction according to the focusing error signal and the tracking error signal.

[0006]

By the way, according to the above-mentioned conventional objective lens driving device 50, the four metal wires 5 are used.
6, the objective lens 51 and the bobbin 52 which are movable parts.
And the focusing coil 53 and the tracking coil 5
The total weight of 4 and 3 is supported. Therefore, these metal wires 56 are configured so as to maintain a required mechanical strength as a wire diameter that is somewhat thick.

Therefore, in the objective lens driving device 50, since the rigidity of the metal wire 56 is increased and the internal loss is reduced, and it is difficult to damp the resonance, as shown in FIG.
There is a problem that the frequency transfer characteristic is poor. That is, in the objective lens driving device 50, the phase change at the primary resonance frequency (f ₀ ) of the movable portion is steep and the resonance sharpness (Q ₀ ) at f ₀ is as shown in FIG. Is big. Therefore, the objective lens driving device 50 has problems that the position control characteristic of the objective lens 51 is bad and that the objective lens driving device 50 is easily affected by vibration or disturbance.

In order to solve such a problem, for example, a method of covering the outer peripheral portion of the metal wire 56 with a rubber tube or a method of inserting a coil spring in the outer peripheral portion of the metal wire 56 in a state of being slightly compressed between the fixing portions. Etc. have been proposed. These measures suppress the occurrence of an unnecessary resonance phenomenon so that highly accurate focusing control and tracking control of the objective lens are performed.

As another method, a method of attaching a viscoelastic material such as rubber to the metal wire 56 has been proposed. With this measure, it is possible to suppress Q ₀ due to the damping property of the viscoelastic material, and highly precise focusing control and tracking control of the objective lens are performed.

However, the above-mentioned first measure has a problem that the structure is complicated and the cost is increased, and it is difficult to achieve miniaturization. Also, in the second countermeasure, since Q ₀ is determined by the damping property of the viscoelastic material, there is a problem in that the characteristics deteriorate due to changes over time and changes in temperature, resulting in poor reliability.

Therefore, according to the present invention, the structure is simple, the resonance sharpness in the frequency band used is suppressed, the influence caused by the component accuracy, the assembly accuracy, etc. is alleviated, and it is reliable with respect to aging and temperature changes. The object of the present invention is to provide an objective lens driving device that maintains the property.

[0012]

An objective lens driving device according to the present invention, which has achieved this object, is a magnetic circuit section comprising a bobbin holding an objective lens at one end side, a focusing coil, a tracking coil, a magnet and a yoke. Drive means for drivingly displacing the objective lens in the focusing direction and the tracking direction, a plurality of elastic supporting members for supporting the bobbin in a cantilever manner by attaching one end to the bobbin, and these elastic supporting members. Is provided with a plurality of insertion holes through which the other end of the elastic holder is formed, and a support holder that forms a base, and the other end of the elastic support member that is attached to the support holder and that has passed through the insertion hole is fixed. And a mounting substrate. The mounting substrate is configured to be mounted on the mounting portion of the support holder with the region where the other end of the elastic support member is fixed as a non-fixed portion with respect to the mounting portion of the support holder.

[0013]

According to the objective lens driving device of the present invention constructed as described above, the fixed side of the elastic support member for elastically displacing the bobbin forming the movable part in the focusing direction and the tracking direction is supported. On the mounting board
Since the degree of freedom is provided, even if the elastic supporting member having mechanical characteristics is provided, the phase change at f ₀ becomes gentle and Q ₀ is suppressed. Further, in the objective lens driving device, the material of the mounting substrate, the plate thickness dimension, the shape specification of the non-fixed portion, or the specification of the mounting portion of the elastic supporting member from the fixing portion with the supporting holder is selected, so that f ₀ The frequency band is adjusted, the resonance frequency of the parasitic resonance is set, and the resonance sharpness is suppressed.

[0014]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Specific embodiments of the present invention will be described below with reference to the drawings. The embodiment is a coil movable type objective that is assembled to the optical pickup device 1 and controls the objective lens 4 in the focusing direction, which is a direction parallel to the optical axis, and in the tracking direction, which is a direction orthogonal to the optical axis. The lens drive device 2 is shown. The objective lens driving device 2 is mounted on the base 13 together with the laser unit 3 or a light receiving element for detecting the returning light from the optical disk, and constitutes the optical pickup device 1.

In the objective lens driving device 2, a slide guide reference shaft 14 and a slide guide shaft 15 which constitute parallel guide portions which are arranged in parallel with each other on the disc player on opposite sides thereof are respectively inserted or engaged. Bearing portions 13A and 13B as guided portions are attached to bases 13 provided on both sides. First bearing 1
3A is composed of a pair of protrusions having shaft holes spaced in the width direction of the base 13. Second bearing portion 13
B is composed of a convex portion having a semicircular shaft hole whose one side is open.

In the objective lens driving device 2, the elastic support member 7 for elastically displacing the bobbin 4 holding the objective lens 4 extends in the axial direction of the slide guide reference shaft 14 and the slide guide shaft 15 which are parallel to each other. The slide guide reference shaft 14 and the slide guide shaft 1.
It is located at the center of the base 5 and is disposed on the base 13. A yoke 8 is attached to the base 13 using a screw or the like, and a support holder 9 is attached to the yoke 8 to form a fixed portion.

The base 13 is provided with a semiconductor laser element as a laser light source which is located on the side of the second bearing portion 13B and emits a light beam which is irradiated onto the optical disk through the objective lens 4 of the objective lens driving device 2. Laser unit 3
Further, a light receiving element for receiving the return light reflected from the optical disk, a separation optical element for separating the light beam emitted from the semiconductor laser and the return light, and the like are provided.

The optical pickup device 1 has bearing portions 13A and 13B on both sides of a base 13, and is supported by a slide guide reference shaft 14 and a slide guide shaft 15 which are arranged in parallel with each other in a disc player, and an optical disc. Is driven in the radial direction.

As shown in FIGS. 1 and 2, the objective lens device 2 includes an objective lens 4, a bobbin 5, a focusing coil 16 and a tracking coil 17 which constitute a movable part.
And a magnetic circuit portion including a yoke 8 and a magnet 12 that constitute the fixed portion side, a support holder 9 and a power feeding substrate 10. The objective lens 4 is attached to the bobbin 5, and collects the light beam emitted from the semiconductor laser of the laser unit 3 as the light source of the optical pickup device 1, irradiates the signal recording surface of the optical disc, and is reflected from the optical disc. Return light is incident.

The bobbin 5 constituting the movable portion is formed of a synthetic resin such as polystyrene as a material, and as shown in FIG. 3, a square opening 5A is formed in the center and
The objective lens mounting portion 5B is integrally provided so as to project to one end side. In this objective lens mounting portion 5B,
A mounting recess is provided in the center, and the objective lens 4 is mounted via the lens holder. A light transmission hole for transmitting a light beam emitted from the semiconductor laser which is incident on the objective lens 4 and a return light from the optical disc which is transmitted from the objective lens 4 is provided on the bottom surface of the mounting recess. .

The bobbin 5 is provided with a coil mounting plate fitting groove 5C which is located at a substantially central portion in the front-rear direction on opposite sides of the bobbin 5 so as to cross the opening 5A. In the bobbin 5, through these coil mounting plate fitting grooves 5C,
The coil attachment plate 6 formed as a rectangular flat plate member is attached. The coil mounting plate 6 is made of a material such as a glass epoxy resin plate or a synthetic resin material plate, and as shown in FIG.
When fitted to C and attached to bobbin 5, both ends are formed in a long rectangular shape having a size protruding from both sides of bobbin 5, respectively.

The coil mounting plate 6 is provided with a focusing coil 16 composed of a pair of upper and lower coil portions each having a flat rectangular frame shape on one side surface side, and on the other side surface side.
A tracking coil 17 including a pair of left and right coil portions that form a flat rectangular frame shape is provided. Each of the coil portions forming the focusing coil 16 and the tracking coil 17 is formed by etching a copper foil adhered on the coil mounting plate 6 to form a rectangular coil pattern.

Each of the coil portions constituting the focusing coil 16 and the tracking coil 17 may have a flat rectangular frame shape, and a coil wire may be wound in a flat rectangular frame shape. It may be. In this case, the coil portions formed by winding the coil wire material are bonded to the one side surface side and the other side surface side of the coil mounting plate 6 by using an adhesive.

The coil mounting plate 6 provided with the focusing coil 16 and the tracking coil 17 as described above is fitted over the both sides of the bobbin 5 in the coil mounting plate fitting groove 5C. The coil mounting plate 6 is positioned and integrally mounted so that the plane on which the focusing coil 16 and the tracking coil 17 are provided is parallel to the optical axis of the objective lens 4 mounted on the objective lens mounting portion 5B. . The coil mounting plate 6 is firmly attached to the bobbin 5 by applying an adhesive to the coil mounting plate fitting groove 5C.

The coil mounting plate 6 is arranged in advance in a mold for molding the bobbin 5, and is integrally mounted on the bobbin 5 by an insert molding method which is mounted simultaneously with the molding of the bobbin 5. Good. The objective lens 4 is attached to the objective lens attachment portion 5B after attaching the coil attachment plate 6 to the bobbin 5. This is to prevent the objective lens 4 from being damaged when the coil attachment plate 6 is attached to the bobbin 5.

As described above, the bobbin 5 to which the coil mounting plate 6 and the objective lens 4 are mounted is provided with the yoke 8 constituting the magnetic circuit portion via the elastic supporting member 7 such as four linear wires. Support holder 9 attached to
Supported by a cantilever. At this time, the bobbin 5 is supported by the pair of elastic support members 7 on opposite sides of the bobbin 5 to support the holder 9.
By being supported in a cantilever manner, the focusing direction is a direction parallel to the optical axis of the objective lens 4 and the tracking direction is a direction orthogonal to the optical axis of the objective lens 4 with the elastic support member 7 as an elastic displacement portion. It can be driven and displaced. The elastic support member 7 is formed of a conductive material such as a thin metal wire or a thin long metal leaf spring.

In order to support the bobbin 5, the four elastic supporting members 7 have fitting holes 6A provided at both ends of the coil mounting plate 6 integrally attached to the bobbin 5 so as to project from both sides thereof. One end side is inserted into each. In addition,
Although not shown, the coil attachment plate 6 is provided with a connection terminal portion extending from the coil ends of the focusing coil 16 and the tracking coil 17 around the fitting hole 6A.

Each elastic supporting member 7 is, as shown in FIG.
It is fixed to the coil mounting plate 6 by solder which is inserted into the fitting holes 6A and applied onto the connection terminal portions. Each elastic support member 7 constitutes a power feed line for the focusing coil 16 and the tracking coil 17, as described later. Each elastic support member 7 may be fixed to the coil attachment plate 6 so as to be electrically conducted to the connection terminal portion, and a conductive adhesive may be used instead of solder.

As described above, the four elastic supporting members 7 are cantilevered by being fixed in a state in which one end side is electrically connected to the coil mounting plate 6, and the other end portion supports the bobbin 5 in a cantilevered manner. It is fixed in a state of being electrically connected to the power supply board 10 integrally attached to the back surface of the support holder 9 constituting the.

The support holder 9 is made of synthetic resin such as polystyrene and is formed in a substantially rectangular block shape as a whole, and faces the objective lens mounting portion 5B of the bobbin 5 on one end side of the yoke 8 as described later. It is attached in this way to form a fixed portion. The support holder 9 faces the coil attachment plate 6 attached to the bobbin 5 in parallel. The support holder 9 includes coil mounting plates 6 on both sides 9A.
A pair of upper and lower insertion holes 9B whose axis is aligned with the fitting hole 6A are provided. Each of these insertion holes 9B penetrates one end of the elastic support member 7.

A board mounting portion 9C is integrally formed on the back surface of the support holder 9, and the power feeding board 10 is joined and fixed onto the board mounting portion 9C. Board mounting part 9
As shown in FIG. 3, C is formed in a pedestal shape protruding in the longitudinal center of the support holder 9 with a height dimension G and a width dimension L ₂ .

As will be described later, the power supply board 10 has a central mounting area firmly bonded and fixed onto the board mounting portion 9C of the support holder 9 by a method such as a double-sided adhesive tape or ultrasonic welding to form a fixed portion 10C. are doing. Power supply board 1
0 is formed of a material such as a glass epoxy resin plate or a synthetic resin material plate, and as shown in FIG.
Since A is slightly projected in the up-down direction, the whole is formed in a laterally elongated substantially H-shape. As shown in FIG. 4, the power supply board 10 is provided with a pair of laterally elongated cutout holes 10D that are spaced apart in the width direction. A circuit conductor 11 connected to an objective lens drive control circuit (not shown) is formed on the main surface of the power feeding substrate 10.

As will be described later, the power supply board 10 is configured such that the areas that are projected to both sides are non-fixed parts 10A when the power supply board 10 is bonded and fixed to the board mounting part 9C of the support holder 9. The non-fixed portion 10A is provided with a pair of left and right fitting holes 10B whose axes coincide with the insertion holes 9B of the support holder 9 in a state where the power supply board 10 is joined and fixed to the support holder 9. Has been. The elastic support members 7 penetrate the insertion holes 9B of the support holder 9 and are fitted into the fitting holes 10B of the power supply board 10. The power supply board 10 is provided with lands 11A of the circuit conductor 11 surrounding the outer periphery of the fitting hole 10B. Therefore, the elastic support member 7 is mechanically coupled with the circuit conductor 11 of the power supply board 10 electrically connected by soldering the fitted end portion and the land portion 11A.

The method of electrically connecting and mechanically connecting the elastic supporting member 7 and the power feeding substrate 10 is, in addition to soldering, a conductive adhesive, for example, may be used on the outer circumference of the other end of each elastic supporting member 7. Alternatively, the coating may be applied from the portion to the land portion 11A.

The power supply board 10 configured as described above is
By being bonded and fixed onto the board mounting portion 9C of the support holder 9, the central region L ₂ is fixed to the board mounting portion 9C as the fixing portion 10C as shown in FIG. L ₃ overhanging to the side,
The region L ₄ is the non-fixed portion 10A.

In FIGS. 3 and 4, L ₁ is the space between the left and right fitting holes 10B to which the elastic support member 7 is fixed, L ₂ is the length of the fixing portion 10C, and L ₃ and L _{4 are shown.} Is
It is the length dimension of the non-fixed portion 10A. Further, t is the thickness dimension of the power feeding board 10, G is the height dimension of the board mounting portion 9C of the support holder 9, and is the non-fixed portion 10 of the power feeding board 10.
It is a gap between A and the back surface of the support holder 9. further,
W ₃ is the upper and lower fitting holes 10 to which the elastic support member 7 is fixed.
The spacing dimension of B, W ₁ and W ₂ are the spacing dimension of the fitting hole 10B and the notch hole 10C.

Therefore, in the objective lens driving device 2, by appropriately selecting the shape specification of the power supply board 10 or the mounting specification of the power supply board 10 and the support holder 9, the thickness t of the power supply board 10 and the non-fixed portion. It is possible to adjust the attachment specifications of the elastic support member 7 to the power supply board 10 with the length dimensions L ₃ and L _{4 of} 10A and the gap dimensions W ₁ and W ₂ of the fitting hole 10B and the cutout hole 10C as variables.

FIGS. 7 to 9 show the support holder 9 and the power supply board 10 which constitute the support portion 20 on the fixed portion side of the elastic support member 7.
And As described above, the support holder 9 has a pedestal-like substrate mounting portion 9C integrally formed on the back surface thereof. The power supply board 10 has the above-described L ₂ × W with respect to the support holder 9.
The range of ₃ is used as the fixing portion 10C, and the double-sided adhesive tape 21 is used to firmly bond and fix the area. The power supply board 10 has a cutout hole 10D to gradually reduce the resonance frequency band.

FIGS. 10 to 12 show another supporting portion 25 including the support holder 9 and the power feeding board 10, and the power feeding plate 10 is shown in FIG.
Is a substrate mounting portion 9 of the support holder 9 utilizing the pair of positioning holes 27, 27 that have a function of gradually reducing the resonance frequency band.
It is joined and fixed in a state of being positioned at C. That is,
The support holder 9 has a pair of positioning bosses 26, which are integrally provided on the board mounting portion 9C so as to be spaced apart from each other in the longitudinal direction. The power supply board 10 is positioned and assembled with the support holder 9 by fitting the positioning bosses 26, 26 into the cutout holes 27, 27.

In this case, the support holder 9 and the power supply board 10 are firmly joined and fixed by the adhesive previously filled in the adhesive filling concave portion 28 provided in the surface of the board mounting portion 9C. Needless to say, the support holder 9 and the power supply board 10 may be joined and fixed by the double-sided adhesive tape described above. Further, it goes without saying that the support holder 9 and the power supply board 10 may be firmly joined and fixed by subjecting the positioning bosses 26, 26 to a heat welding process.

As described above, the yoke 8 has the support holder 9 attached to one end thereof, and the pair of rising pieces 8A and 8B are formed in a substantially central portion so as to rise. Magnets 12A and 12B are attached to the yoke 8 on opposite side surfaces of the rising pieces 8A and 8B. York 8
Composes a magnetic circuit section with these magnets 12A and 12B, and cooperates with the focusing coil 16 and the tracking coil 17 provided on the coil mounting plate 6 to drive and displace the objective lens 4 in the focusing direction and the tracking direction. To generate a driving force.

The yoke 8 has a magnet 12 on the back side.
A holder mounting portion is formed upright in parallel with the rising pieces 8A and 8B to which A and 12B are mounted. Then, the support holder 9 has the yoke 8 by fitting the fitting support portions formed on both sides facing each other on both sides of the holder mounting portion.
Attached to. In the state where the support holder 9 is attached, the yoke 8 is positioned so that the rising pieces 8A and 8B to which the magnets 12A and 12B are attached are inserted into the opening 5A provided in the bobbin 5. The rising pieces 8A and 8B are located on both sides of the opening 5A of the bobbin 5 that are orthogonal to the optical axis of the coil mounting plate 6.
The focusing coil 16 and the tracking coil 17 provided in the above are arranged in the magnetic gap formed by the pair of magnets 12A and 12B.

The pair of rectangular frame-shaped coil portions forming the focusing coil 16 has a horizontal portion parallel to the longitudinal direction of the coil attachment plate 6 which is a direction orthogonal to the optical axis of the objective lens 4 attached to the bobbin 5. Long side, objective lens 4
Is formed in a rectangular frame-like flat plate shape whose short side is a vertical portion parallel to the short side direction of the coil mounting plate 6 which is a direction parallel to the optical axis direction of. The coil portions of the focusing coil 16 are formed such that the winding directions thereof are opposite to each other, and are provided in parallel on one side surface of the coil mounting plate 6 with a slight gap provided between adjacent horizontal portions. There is.

When the objective lens 4 is driven and displaced in the tracking direction, which is a plane direction orthogonal to the optical axis, the focusing coil 16 has a pair of magnets 1 having vertical portions.
It is formed in a rectangular frame shape having a length that does not face the magnetic gap formed by 2A and 12B. That is, in the focusing coil 16, the distance between the vertical portions is at least the width of the magnets 12A and 12B.
The length is set to the sum of the driving displacement in the tracking direction. In the objective lens driving device 2, the vertical portion has the magnet 12A,
Located in the magnetic gap formed between 12B, the drive current supplied to the focusing coil 16 does not generate unnecessary drive force other than the drive force for driving the objective lens 4 in the direction parallel to the optical axis.

The tracking coil 17 has a long side which is a vertical portion parallel to the short side direction orthogonal to the longitudinal direction of the coil mounting plate 6 which is a direction parallel to the optical axis of the objective lens 4 mounted on the bobbin 5. It is formed in a rectangular frame-like flat plate shape whose short side is a horizontal portion parallel to the long side direction of the coil mounting plate 6 which is a direction orthogonal to the optical axis of the objective lens 4. The tracking coils 17 are formed such that the winding directions thereof are opposite to each other, and are provided in parallel on the other side surface of the coil attachment plate 6 with a slight gap provided between adjacent one vertical portions.

The tracking coil 17 includes the objective lens 4
Is driven and displaced in the focusing direction, which is a direction parallel to the optical axis, the horizontal portion has a pair of magnets 12A,
It is formed in a rectangular frame shape having a length that does not face the magnetic gap formed by 12B. That is,
The spacing between the horizontal portions of the tracking coil 17 is set to at least the height of the magnets 12A and 12B plus the drive displacement amount of the objective lens 4 in the focusing direction. Further, the tracking coil 17 is provided on the coil mounting plate 6 such that one vertical portion adjacent to each other is laminated at the center of one horizontal portion adjacent to each other of the focusing coil 16.

In the above-mentioned embodiment, the focusing coil 16 and the tracking coil 17 are provided on the opposite side surfaces of the coil mounting plate 6, respectively. However, one side surface or the other side surface side of the coil mounting plate 6 is arranged. Alternatively, they may be stacked on each other. Also, magnet 1
The magnets 2A and 12B are magnetized in the thickness direction with single pole magnetization, and are magnetized with opposite surfaces on opposite sides.

In the objective lens driving device 2 configured as described above, the control current corresponding to the focusing error signal is supplied from the objective lens driving control circuit to the power feeding board 10. Then, this focusing control current is supplied from the circuit conductor 11 of the power supply board 10 to the focusing coil 16 via the elastic supporting member 7 having conductivity. The focusing coil 16 drives and displaces the bobbin 5 in a direction parallel to the optical axis of the objective lens 4 by a current flowing in one horizontal portion adjacent to each other and a magnetic flux from the magnets 12A and 12B radiated in the magnetic gap. Generates driving force.

In the bobbin 5, the elastic support member 7 is elastically displaced by the driving force in the direction parallel to the optical axis as an elastic displacement portion, and the objective lens 4 mounted on the objective lens mounting portion 5B is parallel to the optical axis. Drive displacement in any direction. Therefore, the objective lens driving device 2 controls the focusing of the light beam emitted through the objective lens 4.

In the objective lens driving device 2, a control current corresponding to the tracking error signal is supplied from the objective lens driving control circuit to the power feeding board 10. Then, this tracking control current is supplied from the circuit conductor 11 of the power supply substrate 10 to the tracking coil 17 via the elastic supporting member 7 having conductivity. Tracking coil 17
Is a driving force for driving and displacing the bobbin 5 in a plane direction orthogonal to the optical axis of the objective lens 4 by an electric current flowing in one vertical portion adjacent to each other and a magnetic flux from the magnets 12A and 12B radiated in the magnetic gap. Generate.

In the bobbin 5, the elastic support member 7 is elastically displaced in the plane direction orthogonal to the optical axis as an elastic displacement portion by this driving force, and the objective lens 4 attached to the objective lens attachment portion 5B is used as the optical axis. Drive displacement is performed in the plane direction orthogonal to each other. Therefore, the objective lens driving device 2 performs tracking control of the light beam emitted through the objective lens 4.

In the objective lens driving device 2, one end of the elastic supporting member 7 that supports the bobbin 5 on which the objective lens 4 is supported so as to be displaceable in the focusing direction and the tracking direction constitutes a fixed portion. Power supply board 10
Supported by. Then, in the power supply board 10, the non-fixed portion 10 </ b> A that is a support portion of the elastic support member 7 is configured as a non-fixed portion with respect to the support holder 9.

Therefore, as shown in FIG. 3, in the objective lens driving device 2, in the non-fixed portion 10A of the power feeding substrate 10, the material characteristics of the power feeding substrate 10 cause the thickness direction (Y-Y).
A degree of freedom Δy is given to the (axial direction).
The objective lens driving device 2 supports the objective lens 4 by a resilient supporting member 7 having a sufficient rigidity so that the objective lens 4 can be driven and displaced in the focusing direction and the tracking direction. It is configured to have a damping effect of resonance.

In the objective lens driving device 2 configured as described above, as shown in FIG. 5A, the phase change in the primary resonance frequency band f ₀ is in a gentle state. Further, the objective lens driving device 2 can suppress the resonance sharpness Q ₀ in the primary resonance frequency band f _{0 as shown} in FIG. Further, in the objective lens driving device 2, variations in the primary resonance frequency band f ₀ and the resonance sharpness Q ₀ caused by the wire diameter, the length dimension of the elastic support member 7 or the parallelism at the time of assembly are alleviated.

Further, the objective lens driving device 2 is a parasitic caused by the displacement between the center of gravity of the movable portion composed of the objective lens 4, the holder 5, the focusing coil 16 and the tracking coil 17 shown in FIG. 6 and the center of the driving point. It is possible to set the resonance generation frequency band f _D and suppress the resonance sharpness Q _D in this frequency band f _D. That is, in the objective lens driving device 2, as described above, the plate thickness dimension t of the power supply board 10, the length dimensions L ₃ , L _{4 of} the non-fixed portion 10A, the fitting hole 10B and the notch hole 10C interval dimension W _{1 are used.} , W ₂ are variables, the amplitude of the degree of freedom Δy in the Y-Y axis direction is adjustable.

The degree of freedom Δy is set to a large value as shown in FIG. 6 so that the parasitic resonance frequency band f _D is generated.
Is shifted to a low frequency band and is set to be small, the frequency band f _{D at} which parasitic resonance occurs is shifted to a high frequency band. The degree of freedom Δy is, for example, the thickness t
Is thinned or the length dimension L ₃ and L ₄ of the non-fixed portion 10A is increased, or the space dimension W between the fitting hole 10B and the cutout hole 10C is increased.
It is set to a large value by reducing ₁ and W ₂ .

In this way, the objective lens driving device 2 can set the frequency band f _D of the parasitic resonance, which is difficult in the conventional objective lens driving device. It is possible to set the second resonance frequency band in a range that is not affected by the resonance frequency band of the base 13 that constitutes the fixed part. Therefore, the base 13 does not have to be made of metal as in the conventional case, and can be made lightweight by being made of synthetic resin, for example.

In the objective lens driving device 2 of the above-described embodiment, the focusing coil 16 and the tracking coil 17 are arranged on the bobbin 5 side, which is the movable portion, via the coil mounting plate 6, and the yoke 8 on the fixed portion side is arranged. Although the so-called movable coil type objective lens driving device in which the magnet 12 is disposed is shown in FIG. 1, the present invention is not applicable to a so-called magnet movable type objective lens driving device in which the magnet 12 is disposed on the bobbin 5 side. Of course.

Further, the focusing coil 16 and the tracking coil 17 are each formed on the side surface of the coil mounting plate 6 with a flat rectangular frame. However, in the present invention, the coil frame body is wound. It goes without saying that the focusing coil and the tracking coil coil thus constructed may be fixed to the opening 5A of the bobbin 5.

Further, the elastic support member 7 may be formed of not only a linear member but also a spring plate material. Further, the elastic support member 7 also serves as a power supply line to the focusing coil and the tracking coil,
It goes without saying that power may be supplied to the focusing coil and the tracking coil by an independent power supply line.

[0061]

As described in detail above, according to the objective lens driving device of the present invention, one end of the elastic supporting member that supports the objective lens so as to be displaceable in the focusing direction and the tracking direction is fixed. By supporting the holder that constitutes the part in the area of the non-fixed part, the resonance sharpness that occurs within the operating frequency band is suppressed, and unnecessary resonance due to disturbance or vibration does not occur. The objective lens can be controlled with good responsiveness to the focusing error signal and the tracking error signal. Further, according to the objective lens driving device of the present invention,
It is possible to set the frequency band of parasitic resonance due to the deviation of the center of gravity of the movable part and the center of the driving point due to the accuracy of parts and assembly, and to control the sharpness of the resonance, enabling highly accurate control of the objective lens. Becomes

Further, according to the objective lens driving device of the present invention, since the viscoelastic material such as rubber is not added to the elastic supporting member, the reliability can be improved with respect to temperature change and aging change. To be

[Brief description of drawings]

FIG. 1 is an overall perspective view of an optical pickup device including an objective lens driving device according to the present invention.

FIG. 2 is a perspective view of the objective lens driving device.

FIG. 3 is a plan view of relevant parts for explaining the basic configuration of the objective lens driving device.

FIG. 4 is a side view illustrating a basic configuration of a support holder and a power feeding substrate that form a fixed portion of the objective lens driving device.

FIG. 5 is a frequency response characteristic diagram of an objective lens position when a constant input is applied in the same objective lens driving device, and FIG. 5A shows a phase frequency characteristic diagram in a primary resonance frequency band f ₀ . The diagram (B) shows the primary resonance frequency band f _0.
6 is a diagram showing the amplitude frequency characteristic of the resonance sharpness Q ₀ in FIG.

FIG. 6 is a phase frequency / amplitude frequency characteristic diagram showing a frequency characteristic diagram in the objective lens driving device and explaining a phase change and a generation of a resonance sharpness in a parasitic resonance frequency band f _D.

FIG. 7 is a perspective view illustrating a configuration of a support holder and a power feeding substrate provided in the objective lens driving device.

FIG. 8 is a plan view illustrating the configurations of a support holder and a power supply board included in the objective lens driving device.

FIG. 9 is a side view illustrating the configurations of a support holder and a power supply board included in the objective lens driving device.

FIG. 10 is a perspective view showing another embodiment of the support holder and the power feeding board.

FIG. 11 is a plan view of the support holder and the power feeding board.

FIG. 12 is a side view of the support holder and the power feeding board.

FIG. 13 is a perspective view showing an example of a conventional objective lens driving device.

FIG. 13 is a frequency response characteristic diagram of an objective lens position when a constant input is applied in the same objective lens driving device, and FIG. 13A shows a phase frequency characteristic diagram in a primary resonance frequency band f ₀ . The figure (B) shows the primary resonance frequency band f.
₀ shows the amplitude frequency characteristic diagram of the resonance sharpness Q ₀ at.

[Explanation of symbols]

 1 Optical Pickup Device 2 Objective Lens Driving Device 3 Laser Unit 4 Objective Lens 5 Bobbin 6 Coil Mounting Plate 7 Elastic Support Member 8 Yoke 9 Support Holder 9B Insertion Hole 10 Power Supply Board (Mounting Board) 10A Unfixed Part 10B One End of Elastic Support Member Fitting hole to which the part is attached 10C Fixed part 12 Magnet 13 Base 16 Focusing coil 17 Tracking coil

[Procedure amendment]

[Submission date] April 12, 1995

[Procedure Amendment 1]

[Document name to be amended] Statement

[Correction target item name] 0018

[Correction method] Change

[Correction content]

The optical pickup device 1 has bearing portions 13A and 13B on both sides of a base 13 and a slide guide reference shaft 14 and a slide guide shaft in which an objective lens driving device 2 is arranged in parallel with each other in a disc player. 15
It is supported by and is driven in the radial direction of the optical disk.

[Procedure Amendment 2]

[Document name to be amended] Statement

[Correction target item name] 0033

[Correction method] Change

[Correction content]

As will be described later, the power supply board 10 is configured such that the areas that are projected to both sides are non-fixed parts 10A when the power supply board 10 is bonded and fixed to the board mounting part 9C of the support holder 9. The non-fixed portion 10A is provided with a pair of left and right fitting holes 10B whose axes coincide with the insertion holes 9B of the support holder 9 in a state where the power supply board 10 is joined and fixed to the support holder 9. Has been. The elastic support members 7 penetrate the insertion holes 9B of the support holder 9 and are fitted into the fitting holes 10B of the power supply board 10. The power supply board 10 is provided with lands 11A of the circuit conductor 11 surrounding the outer periphery of the fitting hole 10B. Therefore, the elastic support member 7 is mechanically coupled with the circuit conductor 11 of the power supply board 10 electrically connected by soldering the fitted end portion and the land portion 11A.

[Procedure 3]

[Document name to be amended] Statement

[Correction target item name] 0035

[Correction method] Change

[Correction content]

The power supply board 10 configured as described above is
By being bonded and fixed onto the board mounting portion 9C of the support holder 9, the region L ₂ of the central portion shown in FIG.
Areas L ₃ and L ₄ which are fixed to the board mounting portion 9C as C and project laterally from the board mounting portion 9C are non-fixing portions 10A.

[Procedure amendment 4]

[Document name to be amended] Statement

[Correction target item name] 0036

[Correction method] Change

[Correction content]

In FIGS. 3 and 4, L ₁ is the space between the left and right fitting holes 10B to which the elastic support member 7 is fixed, L ₂ is the length of the fixing portion 10C, and L ₃ and L _{4 are shown.} Is
It is the length dimension of the non-fixed portion 10A. Further, t is the thickness dimension of the power feeding board 10, G is the height dimension of the board mounting portion 9C of the support holder 9, and is the non-fixed portion 10 of the power feeding board 10.
It is a gap between A and the back surface of the support holder 9. further,
W ₃ is the upper and lower fitting holes 10 to which the elastic support member 7 is fixed.
The spacing dimension of B, W ₁ and W ₂ are the spacing dimension between the fitting hole 10B and the cutout hole 10D.

[Procedure Amendment 5]

[Document name to be amended] Statement

[Name of item to be corrected] 0037

[Correction method] Change

[Correction content]

Therefore, the objective lens driving device 2 selects the shape specification of the power feeding board 10 or the mounting specification of the power feeding board 10 and the support holder 9 as appropriate, so that the thickness t of the power feeding board 10 is not fixed. With the length dimensions L ₃ and L _{4 of the} portion 10A and the spacing dimensions W ₁ and W ₂ between the fitting hole 10B and the cutout hole 10D as variables, the attachment specifications of the elastic support member 7 to the power supply board 10 can be adjusted. .

[Procedure correction 6]

[Document name to be amended] Statement

[Correction target item name] 0042

[Correction method] Change

[Correction content]

The yoke 8 has a magnet 12 on the back side.
A holder mounting portion is formed upright in parallel with the rising pieces 8A and 8B to which A and 12B are mounted. Then, the support holder 9 is attached to the yoke 8 by fitting the fitting support portions formed on both sides facing each other on both sides of the holder mounting portion. In the state where the support holder 9 is attached, the yoke 8 is positioned so that the rising pieces 8A and 8B to which the magnets 12A and 12B are attached are inserted into the opening 5A provided in the bobbin 5. The rising pieces 8A and 8B are located on both sides of the opening 5A of the bobbin 5 which are orthogonal to the optical axis of the coil mounting plate 6, and the focusing coil 16 and the tracking coil 17 provided on the coil mounting plate 6 are disposed on the both sides. It is placed in a magnetic gap formed by a pair of magnets 12A and 12B.

[Procedure Amendment 7]

[Document name to be amended] Statement

[Name of item to be corrected] 0045

[Correction method] Change

[Correction content]

Further, the tracking coil 17 has a long side which is a vertical portion parallel to the short side direction orthogonal to the longitudinal direction of the coil mounting plate 6 which is the direction parallel to the optical axis of the objective lens 4 mounted on the bobbin 5. It is formed in a rectangular frame-like flat plate shape whose short side is a horizontal portion parallel to the long side direction of the coil mounting plate 6 which is a direction orthogonal to the optical axis of the objective lens 4. The tracking coils 17 are formed such that the winding directions thereof are opposite to each other, and are provided in parallel on the other side surface of the coil attachment plate 6 with a slight gap provided between adjacent one vertical portions.

[Procedure Amendment 8]

[Document name to be amended] Statement

[Correction target item name] 0055

[Correction method] Change

[Correction content]

Further, the objective lens driving device 2 is a parasitic caused by the displacement between the center of gravity of the movable portion composed of the objective lens 4, the holder 5, the focusing coil 16 and the tracking coil 17 shown in FIG. 6 and the center of the driving point. It is possible to set the resonance generation frequency band f _D and suppress the resonance sharpness Q _D in this frequency band f _D. That is, in the objective lens driving device 2, as described above, the thickness t of the power supply board 10, the lengths L ₃ and L _{4 of} the non-fixed portion 10A, and the distance between the fitting hole 10B and the cutout hole 10D. By setting W ₁ and W ₂ as variables, the amplitude of the degree of freedom Δy in the Y-Y axis direction is adjustable.

[Procedure Amendment 9]

[Document name to be amended] Statement

[Correction target item name] 0056

[Correction method] Change

[Correction content]

The degree of freedom Δy is set to a large value as shown in FIG. 6 so that the parasitic resonance frequency band f _D is generated.
Is shifted to a low frequency band and is set to be small, the frequency band f _{D at} which parasitic resonance occurs is shifted to a high frequency band. The degree of freedom Δy is, for example, the thickness t
Set to a large value by thinning the length, increasing the length dimensions L ₃ and L ₄ of the non-fixed portion 10A, and decreasing the distance dimensions W ₁ and W ₂ between the fitting hole 10B and the notch hole 10D. To be done. ─────────────────────────────────────────────────── ───

[Procedure amendment]

[Submission date] August 1, 1995

[Procedure Amendment 1]

[Document name to be amended] Statement

[Name of item to be corrected] Brief description of the drawing

[Correction method] Change

[Correction content]

[Brief description of drawings]

FIG. 1 is an overall perspective view of an optical pickup device including an objective lens driving device according to the present invention.

FIG. 2 is a perspective view of the objective lens driving device.

FIG. 3 is a plan view of relevant parts for explaining the basic configuration of the objective lens driving device.

FIG. 4 is a side view illustrating a basic configuration of a support holder and a power feeding substrate that form a fixed portion of the objective lens driving device.

FIG. 5 is a frequency response characteristic diagram of an objective lens position when a constant input is applied in the same objective lens driving device, and FIG. 5A shows a phase frequency characteristic diagram in a primary resonance frequency band f ₀ . The diagram (B) shows the primary resonance frequency band f _0.
6 is a diagram showing the amplitude frequency characteristic of the resonance sharpness Q ₀ in FIG.

FIG. 6 is a phase frequency / amplitude frequency characteristic diagram showing a frequency characteristic diagram in the objective lens driving device and explaining a phase change and a generation of a resonance sharpness in a parasitic resonance frequency band f _D.

FIG. 7 is a perspective view illustrating a configuration of a support holder and a power feeding substrate provided in the objective lens driving device.

FIG. 8 is a plan view illustrating the configurations of a support holder and a power supply board included in the objective lens driving device.

FIG. 9 is a side view illustrating the configurations of a support holder and a power supply board included in the objective lens driving device.

FIG. 10 is a perspective view showing another embodiment of the support holder and the power feeding board.

FIG. 11 is a plan view of the support holder and the power feeding board.

FIG. 12 is a side view of the support holder and the power feeding board.

FIG. 13 is a perspective view showing an example of a conventional objective lens driving device.

FIG. 14 is a frequency response characteristic diagram of an objective lens position when a constant input is applied in the same objective lens driving device, and FIG. 14A shows a phase frequency characteristic diagram in a primary resonance frequency band f ₀ . The figure (B) shows the primary resonance frequency band f.
₀ shows the amplitude frequency characteristic diagram of the resonance sharpness Q ₀ at.

[Explanation of reference numerals] 1 optical pickup device 2 objective lens driving device 3 laser unit 4 objective lens 5 bobbin 6 coil mounting plate 7 elastic support member 8 yoke 9 support holder 9B insertion hole 10 power supply board (mounting board) 10A non-fixed portion 10B Fitting hole to which one end of the elastic support member is attached 10C Fixed part 12 Magnet 13 Base 16 Focusing coil 17 Tracking coil

Claims (3)

[Claims] 1. A drive for driving and displacing an objective lens in a focusing direction and a tracking direction, the bobbin holding an objective lens at one end side thereof, and a magnetic circuit section including a focusing coil, a tracking coil, a magnet and a yoke. A plurality of elastic support members, one end of each of which is attached to the bobbin and the other end of which is attached to the fixed portion so as to support the bobbin in a cantilever manner; A support holder that is provided with an insertion hole and that constitutes a fixed portion, and a mounting substrate that is mounted on this support holder and to which the other end of the elastic support member that is penetrated through the insertion hole is fixed, The area where the other end of the elastic support member is fixed is the non-fixed part with respect to the mounting part of the support holder. The objective lens driving device, characterized in that attached to the attachment portion of the support holder. 2. The elastic supporting member is made of a conductive material having elasticity and has one end electrically connected to the focusing coil and the tracking coil. The other end of the elastic supporting member is inserted into the substrate. A connection circuit is formed around the insertion hole that is fixed and connected to the wiring circuit connected to the power supply unit, and the connection terminal unit and the elastic support member are electrically connected. The objective lens driving device according to claim 1, wherein: 3. The substrate is selected from at least one of a material, a plate thickness dimension, a shape specification of a non-fixed portion, and a specification of a mounting portion of an elastic supporting member from a fixing portion of a support holder. The objective lens drive device according to claim 1 or 2.