JPWO2005088620A1 - Optical pickup device - Google Patents

Abstract

An object of the present invention is to provide an optical pickup device that can maintain good skew accuracy. In the optical pickup device 1 of the present invention, the suspension 25 includes a wide portion 253 formed so that the width dimension in the tracking direction T is increased. Thereby, the torsion of the suspension 25 can be prevented by the wide portion 253. For this reason, the vibration by the high frequency torsional resonance which generate | occur | produces by a twist can be suppressed. Therefore, since the vibration of the movable part can be suppressed, the skew accuracy can be maintained well.

Description

The present invention relates to an optical pickup device for reading or writing information on an optical recording medium.

2. Description of the Related Art Conventionally, an optical pickup device that records information recorded on an optical recording medium such as a CD or a DVD or reproduces recorded information is known (for example, Patent Document 1).

The optical pickup device of Patent Document 1 includes an actuator unit in which a movable unit including a lens holder having a built-in objective lens and a circuit board is movably connected to an actuator base by four linear elastic members, and both sides of the movable unit. A suspension base having a pair of yokes fixed to a pair of magnets arranged opposite to each other with a predetermined time space on the surface, and a standing portion arranged opposite to surround a side surface in the tracking direction of the movable part And is configured.

In addition, a pair of fixed arms are provided on both side surfaces of the lens holder of the movable portion so as to be separated from each other by a predetermined distance in the focus direction. One end of each linear elastic member is fixed to each of the fixed arms. The other end of the linear elastic member is fixed to a groove disposed on both ends of the actuator base. Then, by controlling the magnetic force of the magnets disposed opposite to both sides of the movable part and the circuit board of the movable part, the movable part can be precisely moved in the focus direction and the tracking direction.

JP 2001-229556 A (Page 9, FIGS. 1 and 2)

However, in the optical pickup device described in Patent Document 1, the linear elastic member is formed into a shaft having the same shape and dimension by the linear member. In this case, when a large torsional force is applied to the movable portion, the objective lens is tilted and the skew characteristics are deteriorated due to the difference in strength between the four linear elastic members. That is, the tilt of the objective lens may cause a shift in the positional relationship between the objective lens and the surface of the optical recording medium, which may prevent normal writing and reading of the optical recording medium. Therefore, it is necessary to provide a mechanism for adjusting the tilt of the objective lens according to the strengths of these linear elastic members, resulting in an increase in production cost.

Conventionally, the control of the vibration attenuation rate in the focus direction and the tracking direction is performed only by filling an appropriate dumping agent between the linear elastic member and the actuator base. However, when the rotational speed of the optical recording medium is increased, if the torsional resonance frequency of the movable part is increased, it cannot be solved only by filling the dumping agent. On the other hand, it is known that the structure is not affected by torsional resonance to some extent by adjusting the installation angle of the four linear elastic members, but it is difficult to completely suppress torsional resonance. It is. When the torsional resonance occurs, the movable part is affected by the vibration and the skew accuracy is lowered.

An object of the present invention is to provide an optical pickup device capable of maintaining good skew accuracy.

An optical pickup device according to the present invention is an optical pickup device including a movable part including an objective lens and a support part that movably connects the movable part via at least a pair of elastic members, the at least one pair. The elastic member is provided at an angle crossing each other on the both side surfaces of the movable portion and the support portion, and at least one of the elastic members has a diameter dimension in the diameter direction at both ends of the elastic member. It has the wide part formed larger than a dimension, It is characterized by the above-mentioned.

It is a whole perspective view of the optical pick-up apparatus of this Embodiment. It is a front view of a pickup actuator. It is a perspective view of the pickup actuator which shows the modification of the suspension of this Embodiment. It is a front view of a stopper member. It is sectional drawing of a stopper member. It is a side view of a stopper member.

Explanation of symbols

1. Optical pickup device

20 ... Pickup actuator

21 ... Suspension base as a support

22 ... Moving part

25. Suspension as a linear elastic member

241 ... Objective lens

252 ... Shaft

253 ... Wide part

254 ... Projecting surface.

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

[Configuration of pickup device]

In FIG. 1, the optical pickup device 1 includes an actuator base 10, a pickup actuator 20, and a stopper member 30. The optical pickup device 1 is incorporated in a recording medium driving device that records information on a disc-shaped optical recording medium having an information recording surface such as a CD or DVD, or reproduces the recorded information.

As the recording medium driving device, for example, a CD drive or a DVD drive connected to the inside or the outside of a terminal device such as a personal computer, a CD player or a DVD player connected to a television or audio, or a single function And a portable CD player. The optical pickup device 1 is attached to a position facing the information recording surface of the optical recording medium stored in such a recording medium driving device so as to be movable in the radial direction (tracking direction T) of the information recording surface. Yes.

[Configuration of actuator base]

The actuator base 10 is attached to a pickup support (not shown). This pickup support is connected to a drive mechanism (not shown), and moves the optical pickup device in the tracking direction T along the surface of the optical recording medium under the control of the drive mechanism. A laser light source (not shown) is attached to the pickup support, and the laser light emitted from the laser light source passes below an objective lens 241 described later through an optical path constituted by an optical system. A rising mirror (not shown) is disposed below the objective lens 241. The laser beam is routed upward by the rising mirror and passes through the objective lens 241 from the bottom to the top. An optical recording medium (not shown) is disposed above the objective lens 241. The objective lens 241 focuses laser light on the information recording surface of the optical recording medium.

The actuator base 10 is made of a relatively lightweight metal such as aluminum. The actuator base 10 includes a base portion 11 formed in a substantially flat rectangular shape, a pair of rising portions 13 rising in a direction orthogonal to the tracking direction of the base portion 11, and a pair of yokes 14 rising substantially parallel to the tracking direction of the base portion 11. And a pair of magnets 15 fixed to the yoke 14.

The base 11 has an attachment hole 12, and is attached to the pickup support by screwing the attachment hole 12 or the like. A pickup actuator 20 is fixed to the base 11. Mounting of the pickup actuator 20 will be described later so that a movable portion 22 described later is disposed between the pair of upright portions 13 and the pair of magnets 15 and spaced apart from the upright portions 13 and the magnets 15 by a predetermined distance. A suspension base 21 as a supporting portion is fixed to the base portion 11 of the actuator base 10.

The base 11 of the actuator base 10 is provided with a hole at a position corresponding to the base fixing hole 211 provided in the suspension base 21, and the suspension base is fixed by screwing the hole and the base fixing hole 211. 21 is fixed to the base 11. The attachment of the suspension base 21 is not limited to screwing, but may be locked by a pin member or may be bonded and fixed by an adhesive. Further, the base 11 is formed with a protruding piece 16 in accordance with the shape of the M-shaped groove 212 formed in the suspension base 21. The protrusions 16 function as positioning when the suspension base 21 is fixed by engaging the M-shaped grooves 212 of the suspension base 21.

A positioning groove 131 is formed in the upright portion 13, and a stopper member 30 described later is positioned and fixed in the positioning groove 131. Further, the yoke 14 has a concave portion 141 formed in a part of the upper surface portion. The recess 141 is formed for introducing an adhesive for fixing the magnet 15. The magnet 15 is fixed to the mutually opposing surfaces of the pair of yokes 14 to form a magnetic field.

[Configuration of pickup actuator]

1 and 2, the pickup actuator 20 includes a suspension base 21 as a support portion fixed to the base portion 11 of the actuator base 10, a movable portion 22 movably attached to the suspension base 21, and the suspension base 21. And a suspension 25 as a linear elastic member that couples the movable portion 22.

The suspension base 21 and the movable part 22 are made of synthetic resin. The suspension 25 is formed of a material having a high strength that can withstand a strong bending stress as a spring material and having excellent fatigue resistance against repeated action, for example, a metal such as beryllium copper. The suspension base 21 and the movable portion 22 are insert-molded with the suspension 25 inserted. The suspension base 21 and the movable portion 22 are formed with a plurality of thinned portions 214 so that the thickness of the synthetic resin is substantially uniform, and sink marks are generated by insert molding, resulting in dents on the surface. It prevents it from being made.

The suspension base 21 is formed with a base fixing hole 211, an M-shaped groove 212, and a suspension insertion groove 213. The base fixing hole 211 is a hole that penetrates the suspension base 21 in the tracking direction. As described above, the base fixing hole 211 serves as a screw or pin insertion hole for fixing the suspension base 21 to the base 11 of the actuator base 10 by screwing or pinning. The M-shaped groove 212 is formed on the surface of the suspension base 21 that faces the actuator base 10. As described above, the M-shaped groove 212 is engaged with the protruding piece 16 formed on the base 11 of the actuator base 10 and used for positioning the actuator base 10 and the suspension base 21.

The suspension insertion grooves 213 are formed in a substantially concave shape in substantially the same direction as the longitudinal direction of the suspension 25 at the four corners of the surface of the suspension base 21 facing the movable portion 22. The suspension insertion groove 213 is a groove through which the suspension 25 is passed. The suspension insertion groove 213 is filled with a damping agent between the suspension 25 and the suspension 25 to prevent vibration of the suspension 25 up to a predetermined frequency. This damping agent is a gel-like vibration-damping chemical substance, and is filled between the suspension 25 and the suspension insertion groove 213 so as to buffer the vibration of the suspension 25 and strengthen the fixing force of the suspension 25. Yes.

The movable portion 22 includes a lens holder 24 that holds an objective lens 241 (see FIG. 1), a fixed arm 23 that protrudes from the both side surfaces of the movable portion 22 in total, and a coil substrate 26. . The lens holder 24 is formed in a hollow shape so as to penetrate in the focus direction substantially at the center of the movable portion. An objective lens 241 is fixed to the upper surface side of the lens holder 24. As described above, the lens holder 24 passes laser light having a predetermined luminous intensity emitted from a laser light source of a pickup support (not shown), and the objective lens 241 transmits this laser light to the information recording surface of the optical recording medium. Condensate.

The fixed arms 23 are formed to protrude in the tracking direction T at the four corners of the movable portion 22 opposite to the side facing the suspension base 21. In addition, the pair of fixed arms 23 protruding from one side surface of the movable portion 22 are formed apart from each other by a predetermined distance in the focus direction. A suspension 25 is fixed to the fixed arm 23, and the movable portion 22 is swingably connected to the suspension base 21 by the suspension 25.

A pair of coil substrates 26 are fixed to the movable portion 22 on the surface of the movable portion 22 facing the suspension base 21 and the opposite surface. When the pickup actuator 20 is attached to the actuator base 10, the movable portion 22 is disposed so as to be surrounded by the pair of upright portions 13 and the pair of yokes 14 as described above. At this time, the coil substrate 26 is arranged to face the magnet 15 fixed to the yoke 14. Accordingly, the movable portion 22 is disposed in the magnetic field of the magnet 15, and the frequency of a predetermined servo band (for example, 0 to 5 KHz) is applied to the focus coil (not shown) and the tracking coil (not shown) formed on the coil substrate 26. When the drive current is applied, the movable portion 22 moves in the focus direction F and the tracking direction T due to the force generated by the current in the coil and the magnetic field.

The suspension 25 is integrally formed with a flat plate portion 251 formed at both ends, a shaft portion 252 connected to the flat plate portion 251, and a wide portion 253 connected to the shaft portion 252. At this time, the shaft portion 252 formed on both ends of the suspension and the wide portion 253 sandwiched between the shaft portions 252 are formed over approximately one third of the entire length of the suspension 25 in the longitudinal direction. . Here, the overall length of the suspension 25 in the longitudinal direction means the length from the shaft portion 252 formed on one end side of the suspension 25 to the shaft portion 252 formed on the other end. That is, the length dimension L1 of the shaft part 252 formed on one end side, the length dimension L3 of the shaft part 252 formed on the other end side, and the length of the wide part 253 connected to these shaft parts 252 The dimension L2 is formed to have substantially the same length.

The flat plate portion 251 is embedded and fixed to the suspension base 21 and the fixed arm 23 of the movable portion 22 at the time of insert molding. Further, the flat plate portion 251 is fixed in a state where the tip portion protrudes from the suspension base 21 or the fixed arm 23. And the wiring part which is not shown in figure is electrically connected to the protrusion part of the front-end | tip of the flat plate part 251 fixed to the suspension base 21, and the electric circuit which is not shown in figure is connected. On the other hand, the protruding portion at the tip of the flat plate portion 251 fixed to the fixed arm 23 is connected to the coil substrate 26 fixed to the movable portion 22 so that current flows from the electric circuit to the coil substrate 26 via the suspension 25. It is configured.

The shaft portion 252 is formed to extend substantially linearly in a shaft shape. Further, as described above, the damping agent is filled between the shaft portion 252 on the suspension base 21 side and the suspension insertion groove 213 to enhance the fixing force between the suspension base 21 and the suspension 25 and to vibrate up to a predetermined frequency. Is buffering. Here, the frequency which can be buffered is a frequency up to about 60 Hz, for example, which can be adjusted by the type of the damping agent and the like.

The wide portion 253 is connected to the shaft portion 252 and is formed to have a large width dimension in the tracking direction T. At this time, the wide part 253 is formed in a taper shape in which the width dimension increases as the distance from the connecting position with the shaft part 252 increases. For this reason, since an excessive force is not applied to the connecting portion between the shaft portion 252 and the wide portion 253, the suspension 25 can be prevented from being damaged. By forming the wide portion 253 having a large width dimension as described above, the strength against torsion is improved, and high-frequency vibration that cannot be buffered by the above-described damping agent, for example, the torsional resonance frequency of the suspension 25 is used as the disk rotation frequency. Contributes to higher than the area.

As shown in FIG. 3, the shaft portion 252 of the suspension 25 may have a protruding surface 254 extending in the radial direction. When such a protruding surface 254 is provided, the contact area between the damping agent filled in the suspension insertion groove 213 and the suspension 25 is increased, and the buffering effect of the suspension by the damping agent can be further expected.

[Configuration of stopper member]

4 to 6, the stopper member 30 is formed in a substantially U shape using, for example, a synthetic resin as a material. The stopper member 30 is integrally formed with a stopper base 31, a connection part 32 connected to the stopper base 31, and an arm 33 fixed to the tip of the connection part 32.

When the stopper member 30 is attached to the actuator base 10, the stopper base 31 includes a locking piece 38 that protrudes in the direction of the yoke 14, a presser piece 39 that protrudes in the direction of the yoke 14 from the four corners of the stopper base 31, have. The locking piece 38 is locked to a recess 141 formed in the yoke 14 that is far from the suspension base 21 among the pair of yokes 14 of the actuator base 10. Further, the pressing piece 39 sandwiches the yoke 14 with which the locking piece 38 is locked and the magnet 15 fixed to the yoke 14 from the tracking direction. The stopper base 31 is positioned with respect to the tracking direction of the actuator base 10 by the locking piece 38 and the pressing piece 39.

The connection portion 32 is formed on both side surfaces of the stopper base portion 31 toward the tracking direction T side. A pair of arms 33 formed at the tip of the connection portion 32 are provided substantially in parallel on both side surfaces of the stopper base 31. Further, the arm 33 is formed with a direction substantially orthogonal to the tracking direction T and the focus direction F as a longitudinal direction. Here, the position of the arm 33 away from the stopper base 31 is the distal end side of the arm 33, the position close to the stopper base 31 is the base end of the arm 33, and the direction in which the stopper member 30 is attached to the actuator base 10 is the attachment direction. Then, the arm 33 is always urged by the connecting portion 32 in a direction in which the distal end sides are separated from each other.

At the front end side of the opposing surfaces of the pair of arms 33, a wall portion 34 that restricts the movable range in the tracking direction T of the movable portion 22, and a focus direction of the movable portion 22 that protrudes from these wall portions 34. A protrusion 35 that regulates the movable range of F is integrally formed.

When the stopper member 30 is attached to the actuator base 10 (see FIG. 1), the wall portion 34 is disposed at a predetermined distance from the distal end portion of the fixed arm 23 of the movable portion 22 and is movable between the pair of wall portions 34. This is a movable range in the tracking direction T of the portion 22. When a displacement amount exceeding the movable range is given to the movable portion 22, the distal end portion of the fixed arm 23 comes into contact with the wall portion 34, and the swing of the movable portion 22 is restricted. Further, the protrusion 35 is disposed at an intermediate position between the pair of fixed arms 23 that are separated from each other in the focus direction. The distance until the projection 35 and the fixed arm 23 come into contact is the movable range of the movable portion 22 in the focus direction F. When the amount of displacement exceeding the movable range is given to the movable portion 22, the fixed arm comes into contact with the protruding portion 35 and the swinging of the movable portion 22 is restricted. Further, since the movable part 22 may move in both the focus direction F and the tracking direction T, the dimension of the wall part 34 in the focus direction is formed to be larger than the movable range dimension of the movable part 22 in the focus direction. .

A first engagement claw 36 and a second engagement claw 37 are formed on the surface opposite to the surface on which the projections 35 of the pair of arms 33 are formed, that is, on the surfaces separated from each other. The first engagement claw 36 is formed on the distal end side of the arm 33, and the second engagement claw 37 is provided on the proximal end side of the arm 33. These engaging claws 36 and 37 are each formed in a taper shape whose projecting dimension becomes smaller toward the mounting direction of the stopper member 30.

As described above, the engaging claws 36 and 37 are engaged with the positioning grooves 131 formed in the rising portion 13 of the actuator base 10 to fix the stopper member 30 to the actuator base 10. At this time, the positioning groove 131 is formed so as to extend in a direction substantially orthogonal to the focus direction F and the tracking direction T. Therefore, when fixing the stopper member 30, the first engaging claw 36 of the stopper member 30 is first moved. The stopper member 30 is slid along the positioning groove 131 as it is engaged with the positioning groove 131 and the second engaging claw is engaged.

At this time, if the length dimension of the positioning groove 131 in the longitudinal direction and the distance dimension from the distal end side of the first engagement claw 36 to the proximal end side of the second engagement claw 37 are the same, the stopper is surely secured. The engaging claws 36 and 37 of the member 30 can be fitted into the positioning groove 131 of the actuator base 10 and fixed. Further, at this time, the distal end side of the arm 33 is urged toward the positioning groove 131 by the connecting portion 32, so that the fixing force of the stopper member 30 is further improved.

[Effects of pickup actuator]

In such a pickup actuator 20 of the present embodiment, the suspension 25 includes the wide portion 253 formed so that the width dimension in the tracking direction T becomes large. Thereby, since the torsion of the suspension 25 can be prevented by the wide portion 253, vibration due to high-frequency torsional resonance generated by torsion can be suppressed. Therefore, since the vibration of the movable part can be suppressed, the skew accuracy can be maintained well.

And this wide part 253 is formed in the approximate center of the suspension 25 on both sides of the shaft part 252 formed in the both ends of the suspension 25. Thereby, since the wide part 253 is formed in the approximate center part of the suspension 25 which receives the influence of the twist most, the suspension 25 becomes the least affected by the twist. Accordingly, the suspension 25 can be efficiently prevented from being twisted.

Further, at this time, the length dimension of the shaft portion 252 and the wide width portion 253 is formed to be approximately one third of the overall length of the suspension 25, and each length dimension is substantially the same dimension. It has become. As a result, the overall strength and bending rigidity of the suspension 25 become symmetrical. Therefore, the suspension 25 can distribute the force received when the movable portion swings to the entire suspension 25 in a symmetric manner.

Moreover, the wide part 253 is formed in the taper shape from which a width dimension becomes large toward the center of the wide part 253 from the connection position with the axial part 252. As shown in FIG. Thereby, when a torsional force is applied to the suspension 25, the force can be distributed to the tapered portion, and an excessive force is not applied to the connecting position between the shaft portion 252 and the wide portion 253. Therefore, it is possible to prevent the connection position from being damaged.

And the wide part 253 is formed in the flat form from which the width dimension of the tracking direction T becomes large. As a result, the suspension 25 spreads in only one direction, and therefore, when the pickup actuator 20 is attached to the actuator base 10, it does not get in the way without taking extra space. The wide portion 253 is formed so as to expand in the tracking direction T. That is, the wide portion 253 is substantially perpendicular to the optical axis direction of the objective lens. Thereby, the suspension 25 can hold the movable portion 22 substantially perpendicular to the optical axis in a state where no other force is applied. For this reason, the power for making the movable part 22 substantially perpendicular to the optical axis can be suppressed, and the power consumption can be suppressed.

A projecting surface 254 is formed on the suspension base 21 side of the shaft portion 252 of the suspension 25. As a result, when the damping agent is filled between the suspension insertion groove 213 and the suspension 25 of the suspension base 21, the contact area of the damping agent with the suspension 25 is increased by the surface integral of the protruding surface 254. Therefore, the low frequency vibration caused by the damping agent can be more effectively suppressed, and the fixing force of the suspension 25 is also improved.

[Modification of Embodiment]

It should be noted that the present invention is not limited to the above-described embodiment, and modifications, improvements, and the like within the scope that can achieve the object of the present invention are included in the present invention.

For example, as described above, the shaft portion 252 may be formed with a protruding surface 254 that protrudes in the radial direction. Further, as the projecting surface 254, for example, as shown in FIG. 3, a plurality of pin-shaped projecting surfaces 254 may project from the shaft portion 252, and a ring-shaped projecting formed on the peripheral portion of the shaft portion. It may be a surface.

Moreover, although the wide part 25 was formed in the flat plate shape substantially orthogonal to the focus direction, it is not limited to this. For example, the flat plate surface of the wide portion may substantially intersect the focus surface. Further, the shape of the wide portion is not limited to a flat plate, and may be, for example, a wide portion having a substantially cross-shaped cross section in which two flat plates are crossed, or a wide portion in which two or more flat plates are crossed. Also good. Further, it may be a wide portion having a substantially circular cross section and having a larger diameter than the shaft portion. As described above, by forming a shape in which a plurality of flat plates are crossed or a shaft shape having a large diametrical dimension, stress against torsion is further increased and torsional resonance can be prevented.

Moreover, although the connection part with the axial part 252 of the both ends of the wide part 253 was formed in the taper shape, it is not restricted to this. For example, it may have a shape that is not formed in a tapered shape. In this case, in order to reinforce the connection portion between the shaft portion and the wide portion, it is conceivable to separately provide a reinforcing member at this connection portion.

Further, the wide portion 253 has a length dimension of one third of the entire length at the center of the suspension 25.

Although formed, it is not limited to this. For example, a configuration in which substantially the entire width of the suspension 25 is formed large and the length of the shaft portion is shortened may be employed. With such a configuration, the movable range of the movable portion is limited, but the strength of the suspension and the strength against torsion are increased, and suspension breakage and torsional resonance can be prevented.

The best configuration, method and the like for carrying out the present invention have been disclosed in the above description, but the present invention is not limited to this. That is, the invention has been illustrated and described primarily with respect to particular embodiments, but may be configured for the above-described embodiments without departing from the scope and spirit of the invention. Various modifications can be made by those skilled in the art in terms of materials, quantity, and other detailed configurations.

Therefore, the description limiting the shape, material, etc. disclosed above is an example for easy understanding of the present invention, and does not limit the present invention. The description by the name of the member which remove | excluded the limitation of one part or all of such restrictions is included in this invention.

[Effect of the embodiment]

In the optical pickup device 1 of this embodiment, the suspension 25 includes the wide portion 253 formed so that the width dimension in the tracking direction T is large. Thereby, since the torsion of the suspension 25 can be prevented by the wide portion 253, vibration due to high-frequency torsional resonance generated by torsion can be suppressed. Therefore, since the vibration of the movable part can be suppressed, it is possible to suppress a decrease in skew accuracy.

The present invention can be used as an optical pickup device for reading or writing information on an optical recording medium.

[0002]
Queue characteristics deteriorate. That is, the tilt of the objective lens may cause a shift in the positional relationship between the objective lens and the surface of the optical recording medium, which may prevent normal writing and reading of the optical recording medium. Therefore, it is necessary to provide a mechanism for adjusting the tilt of the objective lens according to the strengths of these linear elastic members, resulting in an increase in production cost.
[0006] Conventionally, control of the vibration attenuation rate in the focus direction and the tracking direction is performed only by filling an appropriate dumping agent between the linear elastic member and the actuator base. However, when the rotational speed of the optical recording medium is increased, if the torsional resonance frequency of the movable part is increased, it cannot be solved only by filling the dumping agent. On the other hand, it is known that the structure is not affected by torsional resonance to some extent by adjusting the installation angle of the four linear elastic members, but it is difficult to completely suppress torsional resonance. It is. When the torsional resonance occurs, the movable part is affected by the vibration and the skew accuracy is lowered.
[0007] An object of the present invention is to provide an optical pickup device capable of maintaining good skew accuracy.
[Means for Solving the Problems]
[0008] The optical pickup device of the present invention is an optical pickup device including a movable portion including an objective lens and a support portion that movably connects the movable portion via at least a pair of elastic members, The at least one pair of elastic members are provided at angles intersecting with each other on both side surfaces of the movable portion and the support portion, and the width dimension of the substantially central portion in the longitudinal direction of the elastic member is larger than both end portions of the elastic member. And a wide portion that is formed to be large.
[Brief description of the drawings]
[0009] FIG. 1 is an overall perspective view of an optical pickup device of the present embodiment.
FIG. 2 is a front view of the pickup actuator.
FIG. 3 is a perspective view of a pickup actuator showing a modification of the suspension of the present embodiment.
FIG. 4 is a front view of a stopper member.
FIG. 5 is a cross-sectional view of a stopper member.


2

An optical pickup device according to the present invention is an optical pickup device including a movable part including an objective lens and a support part that movably connects the movable part via at least a pair of elastic members, the at least one pair. the elastic members, together provided at an angle to intersect with each other on both side surfaces of the movable portion and the support portion, a portion of the elastic member, the diameter dimension than the diameter of the shaft portion at both ends of the elastic member And a wide portion having a substantially circular cross section, which is formed to be large.

Claims (7)

An optical pickup device comprising: a support portion; and a movable portion connected to the support portion via at least a pair of linear elastic members and having an objective lens.

The pair of linear elastic members have one end fixed to the movable portion and the other end fixed to the support portion so that imaginary lines extending in the longitudinal direction intersect with each other. , Having a wide portion formed so that the diameter dimension is larger than the diameter dimension of both ends of the linear elastic member in at least one radial direction

An optical pickup device characterized by that.

The optical pickup device according to claim 1,

The wide portion is formed at a substantially central portion in the longitudinal direction of the linear elastic member.

An optical pickup device characterized by that.

The optical pickup device according to claim 1 or 2,

The wide portion is formed over approximately one third of the length of the linear elastic member in the longitudinal direction.

An optical pickup device characterized by that.

The optical pickup device according to any one of claims 1 to 3,

The wide portion is formed in a tapered shape in which the width dimension increases from both ends of the wide portion toward the center.

An optical pickup device characterized by that.

The optical pickup device according to any one of claims 1 to 4,

The wide part is formed in a flat plate shape.

An optical pickup device characterized by that.

The optical pickup device according to claim 5,

The flat plate surface of the wide portion is substantially orthogonal to the optical axis direction of the objective lens.

An optical pickup device characterized by that.

The optical pickup device according to any one of claims 1 to 6,

An end portion of the linear elastic member is formed with an axial shaft portion connected to the wide portion, and a protruding surface is formed on a part of the shaft portion while projecting in a radial direction.

A dumping agent is filled between a part of the shaft portion and the protruding surface and the support portion.

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