JP4260750B2 - Optical disk device - Google Patents

Description

  The present invention relates to an optical disc apparatus for recording a signal on an optical disc as an information recording medium, such as a compact disc (so-called CD) or a digital versatile disc (so-called DVD), or reproducing the recorded signal.

  In a so-called slot-in type optical disk apparatus that directly inserts and removes an optical disk, as disclosed in, for example, Patent Document 1, in order to cope with optical disks having different diameters, An optical disk positioning member called a stopper is provided.

  The disk stopper is configured to reciprocate along the central axis from a predetermined position on the central axis. When the optical disk is stored in the optical disk apparatus, the disk stopper moves to the predetermined position according to the diameter of the optical disk. Thus, by stopping the movement there, the optical disk is automatically positioned in the advancing and retracting direction.

Japanese Patent Laying-Open No. 2004-185771 (FIG. 5)

  As described above, the conventional optical disk apparatus is configured to automatically position the optical disk in the advancement / retraction direction of the optical disk by the disk stopper, but the disk stopper is placed on the central axis along the advancement / retraction direction of the optical disk. The mechanism for enabling reciprocal movement is complicated, and structural problems are likely to occur, and an increase in manufacturing cost is expected.

  The present invention has been made to solve the above-described problems, and an object of the present invention is to provide a slot-in type optical disc apparatus in which an optical disc positioning mechanism for dealing with optical discs having different diameters is simplified. .

An optical disc device according to the present invention is an optical disc device capable of directly storing and ejecting an optical disc and recording and / or reproducing an information signal with respect to the contained optical disc. A turntable that raises and lowers the turntable between a turntable that is rotatably supported, a lowered position that avoids interference with the optical disk that is stored or ejected, and a raised position that can support the stored optical disk. An elevating mechanism, a drive source mechanism that generates at least a driving force for the turntable elevating mechanism, and a positioning mechanism that performs positioning on a central axis along the advancement / retraction direction of the optical disc, Arranged on the central axis, and when the optical disk is retracted, abuts on the optical disk, A disk stopper for restricting the retracted position of the disk, an arm part for enabling reciprocal movement of the disk stopper on the central axis, and restricting movement of the disk stopper within a predetermined range; Are arranged on planes having different height positions, and in conjunction with the movement of the arm portion, a slide plate capable of reciprocating in a direction parallel to the advancing and retracting direction of the optical disc, and the turntable lifting mechanism A part of the slide plate engages with a part of the slide plate, and is linearly slid in a first direction perpendicular to the advancing and retracting direction in conjunction with the movement of the slide plate. When the turntable is raised, the slide table is further slid in the first direction by receiving the driving force from the driving source mechanism. Possess a slider member for forcibly sliding the door, the slider member through the main surface has a groove extending in the longitudinal direction thereof, the groove has a contour the first direction Includes a stepped portion whose height decreases in the opposite second direction, and the slider is engaged with the part of the slide plate in the stepped portion of the groove. by sliding the member in the first direction, from the contact position with the disk stopper to the optical disc, Before moving to a position away to the retreat direction.

According to the optical disc apparatus of the present invention, the positioning mechanism for positioning on the central axis along the advancement and retraction direction of the optical disc enables the disc stopper and the disc stopper to reciprocate on the central axis, The arm part that restricts the movement of the disk stopper on the central axis within a specified range, and the arm part are placed on different planes, and the optical disk advances and retracts in conjunction with the movement of the arm part. A slide plate that can reciprocate in a direction parallel to the direction, and a slider member that engages with a part of the slide plate and slides linearly in the first direction in conjunction with the movement of the slide plate Therefore, the optical disk can be automatically positioned in the advancing and retracting direction with a relatively simple structure, and structural troubles are unlikely to occur, and the manufacturing cost It is possible to obtain a reduced optical disc apparatus. Further, the structure of the slider member prevents the optical disk from coming into contact with the disk stopper and prevents the disk stopper from interfering with the rotation of the optical disk.

<Embodiment>
<A. Basic configuration and operation>
A characteristic configuration and operation of the optical disc apparatus 1 according to the embodiment of the present invention will be described with reference to FIGS.

<A-1. External configuration>
FIGS. 1 and 2 show an external configuration when the optical disk device 1 is viewed obliquely from above, and the state before the optical disk PD1 (first optical disk) having a diameter of 8 cm is stored in the optical disk device 1 and stored. It is a perspective view which shows a back state. In the following description, for convenience of explanation, the axis parallel to the advancement / retraction direction of the optical disk is defined as the Y axis (the retraction direction of the optical disk is the (+) Y direction, and the advancement direction is the (−) Y direction). The axis perpendicular to the Y axis on the main surface of the optical disk is the X axis (the Y axis (+) direction is the right side is the (+) X direction and the left side is the (−) X direction)), and the main surface of the optical disk is orthogonal A description will be given assuming that the axis to be operated is the Z axis (the label surface side of the optical disc is the (+) Z direction and the recording surface side is the (−) Z direction).

  As shown in FIG. 1, the optical disc apparatus 1 includes a main chassis 11 and a cover chassis 9 that can be said to be an upper lid of the main chassis 11, and is configured so that an optical disc can be inserted into and removed from one side surface of the casing 10. A slot-like disk entrance / exit SL is formed.

  The disk entrance / exit SL is formed by combining an opening 11h provided in the main chassis 11 and an opening 9h provided in the cover chassis 9, and an optical disk called a flap 20 on the opening 9h side. A pressing plate is provided.

  The flap 20 has an elongated rectangular shape in plan view, and is configured to be inserted into the disk entrance / exit SL in the width direction thereof. When the optical disk is not inserted, the main surface of the flap 20 is inclined obliquely, When the optical disc is inserted and when the optical disc is advanced and retracted, the main surface of the flap 20 is configured to be movable so as to be substantially parallel to the main surface of the optical disc. 2 shows a state in which the optical disc is stored in the optical disc apparatus 1 and the main surface of the flap 20 is substantially parallel to the main surface of the optical disc.

  Further, a cylindrical clamper accommodating portion 9a is provided on the upper surface of the cover chassis 9 at a position slightly closer to the disc inlet / outlet SL than the center, and an optical disc holding member called a clamper 18 is rotated in the clamper accommodating portion 9a. It is freely housed.

  The clamper 18 is supported at a position above the height position of the movement track of the optical disk ((+) Z direction side) so as not to interfere with the optical disk moving back and forth along the Y axis. Further, a magnet is accommodated in the clamper 18, and the clamper 18 and a turntable 52 (FIG. 3) to be described later are attracted to each other by the magnetic force of the magnet, so that the clamper 18 and the turntable 52 are attracted to each other. Hold the optical disk by pressure.

  At the left ((−) X direction) end portion of the upper surface of the cover chassis 9, an elongated member called a front arm 101 is disposed so as to extend in the Y direction. An elongated member called a stopper arm 102 is arranged so as to extend in the (+) X direction from the bottom of the tip opposite to the SL side.

  The front arm 101 and the stopper arm 102 are configured to be disengageable from each other at one end, and operate in conjunction with each other when engaged.

  That is, the stopper arm 102 has one end portion in the longitudinal direction that is extremely narrower than the other end portion, and one end portion has an opening 102c extending in the longitudinal direction. Yes. The other tip has bosses 102a and 102b (first and second bosses) (FIG. 13) arranged in series substantially along the width direction and projecting from the upper surface of the stopper arm 102. ing.

  By engaging one of the boss portions 102a and 102b with a boss receiving portion 101f (FIG. 12) provided on the back surface of the front end portion of the front arm 101 on the side opposite to the longitudinal disk inlet / outlet SL, The arm 101 and the stopper arm 102 can be interlocked.

  The front arm 101 has an elongated opening 101a extending in the longitudinal direction at a substantially central portion thereof, and a boss portion 9b protruding vertically from the upper surface of the cover chassis 9 is engaged with the opening 101a. Is configured to be reciprocally movable in the longitudinal direction along the shape of the opening 101a and to be rotatable about the boss 9b. Further, a hook portion 101c to which one end of a spring 104 (for example, a coil spring) is connected is provided on the side surface on the clamper housing portion 9a side at a substantially central portion of the front arm 101. The other end of the spring 104 is connected to a boss portion 9 c that projects vertically from the upper surface of the cover chassis 9 in the vicinity of the front arm 101. The movement of the front arm 101 biased by the spring 104 is restricted during the rotational movement and the linear movement.

  Further, the stopper arm 102 is rotatably attached to the upper surface of the cover chassis 9, and the front arm 101 reciprocates in the longitudinal direction when the stopper arm 102 rotates. The structures of the front arm 101 and the stopper arm 102 will be further described later with reference to FIGS. 12 and 13, respectively.

  The front arm 101 and the stopper arm 102 allow a member called a disk stopper 201 (FIG. 3) disposed on the back surface of the cover chassis 9 to reciprocate along the groove portion 9g (guide groove portion). This is a member for restricting the movement range of the stopper 201 along the groove portion 9g within a predetermined range according to the diameter of the optical disc. The front arm 101 and the stopper arm 102 are collectively referred to as an arm portion.

  The disc stopper 201 is disposed so that the vicinity of the turntable 52 is at the initial position so that the optical disc contacts the side surface of the optical disc when the optical disc is retracted (stored) in the optical disc apparatus 1. It is guided by the groove portion 9g formed along the central axis in the (+) Y direction from the clamper housing portion 9a, and can reciprocate along the central axis. The structure of the disk stopper 201 will be further described later with reference to FIGS.

  Since the boss portion 201a of the disk stopper protruding from the groove portion 9g is engaged with the opening portion 102c at the tip end portion of the stopper arm 102, the stopper arm 102 and the front arm are moved along with the movement of the disk stopper 201 along the groove portion 9g. 101 moves in conjunction.

  When the optical disk advances (discharges) from the optical disk apparatus 1, the disk stopper 201 is pushed back toward the initial position by the elastic force of the spring 103 that biases the stopper arm 102. As the spring 103, for example, a kind of torsion spring is used, one end of which is connected to a boss portion 9d that protrudes perpendicularly from the upper surface of the cover chassis 9, and the other end engages with the back surface of the stopper arm 102. It has become.

  1 shows a state in which the optical disk PD1 is not retracted into the optical disk apparatus 1 and the disk stopper 201 is in the initial position. However, when the optical disk PD1 is retracted into the optical disk apparatus 1 as shown in FIG. As can be seen from the position of the portion 201a, the disk stopper 201 is pushed by the optical disk PD1 and moves in the retracting direction, and the angle formed by the front arm 101 and the stopper arm 102 becomes wider than the state of FIG. 101 slides in the (−) Y direction.

<A-2. Configuration of traverse unit>
FIG. 3 illustrates a configuration called a traverse unit 50 disposed in the main chassis 11 (FIG. 1) and supported to be swingable with respect to the main chassis 11, and a configuration around the traverse unit 50. FIG. 2 is a perspective view, and illustration of a thin configuration related to the present invention is omitted.

  The traverse unit 50 has a rectangular frame body called a traverse chassis 51 as a base. In the traverse chassis 51, the end of the optical disk in the retracting direction side ((+) Y direction side) is parallel to the X direction. Thus, the rotation shafts 51a and 51b are provided, and the rotation shafts 51a and 51b are rotatably supported by the main chassis 11, so that the swing shaft P1 constituted by the rotation shafts 51a and 51b is the center. And can swing within the main chassis 11.

  Since the traverse chassis 51 swings about the swing axis P1 as described above, the end of the traverse chassis 51 on the advancing direction side ((−) Y direction side) of the optical disk is referred to as a swing displacement side end. To do. Note that the turntable 52 is moved up and down by the swing of the traverse chassis 51.

  As shown in FIG. 3, a turntable 52 is provided in the vicinity of the tip of the swing displacement side end of the traverse chassis 51. The turntable 52 is made of a material such as iron that has a property of being attracted by a magnetic force, and is configured to sandwich the optical disk with the clamper 18 (FIG. 1). In this state, it receives a driving force of a spindle motor 54 as a rotational drive source mechanism described later and rotates integrally with the optical disk.

  In the traverse chassis 51, an optical pickup 57 that is movable along the Y axis by receiving the driving force of the dual-purpose motor 62 is disposed between the turntable 52 and the end portion on the swing shaft P1 side. ing. The optical pickup 57 has a configuration for recording a signal on the optical disc and / or reproducing a signal recorded on the optical disc. A slide rack 58 that converts the driving force of the dual-purpose motor 62 into a driving force for movement along the Y axis of the optical pickup 57 is provided on the (+) X direction side of the optical pickup 57. The slide rack 58 has a spring 59 that prevents backlash when the gear that drives the slide rack 58 is engaged.

  A dual-purpose motor 62 is provided outside one side surface of the optical pickup 57. The dual-purpose motor 62 is used as a drive source for the disc transport operation, the turntable lifting / lowering operation, and the pickup feeding operation.

  A trigger plate 69 that is movable substantially along the X axis is disposed at the end of the traverse chassis 51 on the swing displacement side. The trigger plate 69 has a rectangular shape in plan view. The trigger plate 69 engages with the cam slider 30 (slider member) at one side surface in the width direction, and the trigger plate 69 at the edge on the other side surface side. A cam groove 69b is formed in the middle portion in the longitudinal direction. The cam groove 69b is formed in a groove shape that can be engaged with the boss portion 58a of the slide rack 58, and is bent at an intermediate portion in the extending direction thereof. When the slide rack 58 moves in the (−) Y direction and the boss portion 58a is inserted into the cam groove 69b and moves in the cam groove 69b, the trigger plate 69 corresponds to the bent shape of the cam groove 69b. Moved in the direction.

  The cam slider 30 is capable of reciprocating along the direction (X axis) perpendicular to the advancing and retracting direction of the optical disc at the end of the main chassis 11 (not shown) on the advancing direction ((−) Y direction) side of the optical disc. The overall shape is configured by a first piece 30p having a rectangular shape in plan view and a second piece 30q extending vertically from one side surface thereof.

  A gear portion 30d having a rack gear 30a provided on the side surface extends from one end portion in the longitudinal direction of the first piece 30p. The plan view shape of the gear portion 30d is an elongated rectangular shape, extends along the longitudinal direction of the first piece 30p, has a width narrower than that of the first piece 30p, and the rack gear 30a is provided with the second piece 30q. It is provided on a part of the side surface opposite to the opposite side.

  Moreover, the small piece part 30b which contributes to opening and closing of the flap 20 so that it may protrude horizontally from the side surface on the opposite side to the side provided with the 2nd piece 30q of the other end part side of the longitudinal direction of the 1st piece 30p. Is provided. The small piece portion 30b is configured to extend to the side opposite to the gear portion 30d along the longitudinal direction of the first piece 30p.

  Further, a groove portion 30c penetrating the main surface of the first piece 30p is provided on the other end side in the longitudinal direction of the first piece 30p.

  The groove 30c has a substantially L shape in plan view, a substantially linear portion along the longitudinal direction of the first piece 30p, and a portion extending obliquely toward the side surface on which the second piece 30q is provided. have. The slide plate 40 is engaged with the groove 30c.

  The slide plate 40 is supported at the end of the main chassis 11 (not shown) on the (−) X direction side so as to be able to reciprocate substantially along the advancing and retracting direction (Y axis) of the optical disc. Is composed of a first piece 40p having a rectangular shape in plan view, and a second piece 40q extending along the longitudinal direction from one end of the first piece 40p in the longitudinal direction. . And the boss | hub part 40t (FIG. 16) which protrudes perpendicularly | vertically from the back surface of the front-end | tip part 40a of the 2nd piece 40q is engaging with the groove part 30c. Accordingly, the slide plate 40 reciprocates substantially along the Y axis in conjunction with the cam slider 30 reciprocating along the X axis.

  Further, the first piece 40p is provided with a groove 40b that penetrates the main surface and extends substantially along the width direction. In addition, the part provided with the groove part 40b is a part which a part of side surface of the 1st piece 40p protruded in the horizontal direction, and the groove part 40b is formed so that some arc may be drawn.

  The protrusion 40b extending in the vertical direction from the back surface of the front arm 101 described in FIG. 1 is engaged with the groove 40b, and interlocked with the reciprocation of the front arm 101 substantially along the Y axis. The slide plate 40 is also configured to move along the Y axis.

  3 shows a transport roller 21b, a roller gear 22 and a gear 23 used for transporting the optical disc, and is rotatably supported on the inner wall of the side surface of the main chassis 11 (not shown). A gear 68 that engages with the gear 23 and a gear 67 that is rotatably supported on the inner bottom surface of the main chassis 11 (not shown) and that engages with the gear 23 and the gear 66 are also shown. The gear 66 and the gear 67 constitute a part of a series of gear groups that transmit the rotational driving force of the dual-purpose motor 62 as the driving force of each mechanism, but the description of the gear that is not related to the present invention is omitted. To do.

<A-3.8 cm Optical Disk Retraction Operation>
Next, the progress of the retracting operation of the optical disk PD1 and the positional relationship between the disk stopper 201 and the members related thereto will be described with reference to FIGS. 4 to 6, the cover chassis 9 is removed, and the thin configuration related to the disc stopper 201 in the optical disc apparatus 1 is omitted.

  FIG. 4 shows a state immediately after the optical disk PD1 is accommodated in the optical disk apparatus 1 by the transport roller 21b (FIG. 3) and the edge in the retracting direction of the optical disk PD1 comes into contact with the disk stopper 201. In this state, the turntable 52 is at the lowest position. The state of the traverse chassis 51 at this time will be further described later with reference to FIG.

  FIG. 5 shows a state in which the center of the turntable 52 and the center of the optical disk PD1 coincide with each other after the optical disk PD1 has come into contact with the disk stopper 201 and moved so as to push the disk stopper 201 a little further in the retracting direction. The front arm 101 slides in the (−) Y direction in conjunction with the stopper arm 102, and the slide plate 40 slides in the (−) Y direction accordingly.

  Then, as the slide plate 40 slides in the (−) Y direction, the cam slider 30 is slightly pulled back to the (−) X direction side. As a result, the cam slider 30 meshes with the gear 67 (FIG. 3), The cam slider 30 is further slid in the (−) X direction by the rotational driving force 67, and accordingly, the swing displacement side end of the traverse chassis 51 causes the turntable 52 (FIG. 3) to clamp the clamper 18 (FIG. 1). And the turntable 52 starts to rise. The operation of the traverse chassis 51 at this time will be further described later with reference to FIG.

  FIG. 6 shows that the turntable 52 (FIG. 3) is lifted completely, the clamper 18 (FIG. 1) and the turntable 52 are sucked together, and the optical disc PD1 is held between the clamper 18 and the turntable 52 by pressure bonding. It represents the state that was done.

  When the turntable 52 is completely raised, the disk stopper 201 is moved further in the retracting direction by the contact prevention mechanism, so that the optical disk PD1 does not contact the disk stopper 201, and the disk stopper 201 interferes with the rotation of the optical disk PD1. Is prevented. The contact prevention mechanism described above will be further described later with reference to FIG.

  Here, the disk stopper 201 is disposed so that the vicinity of the turntable 52 is an initial position, and this initial position is set to a position suitable for storing the optical disk PD1, and the front arm 101 is also set. Is engaged with the boss portion 102a of the stopper arm 102, the front arm 101 and the stopper arm 102 operate only in a range corresponding to the optical disc PD1 having a diameter of 8 cm, and the disc stopper 201 is retracted to exceed this range. It cannot be moved in the direction.

<A-4. Retraction operation of 12-cm optical disk>
FIGS. 7 and 8 show the external configuration when the optical disk device 1 is viewed obliquely from above, and the state before the optical disk PD2 (second optical disk) having a diameter of 12 cm is stored in the optical disk device 1 and stored. It is a perspective view which shows a back state. 7 and FIG. 8 are the same as those in FIG. 1 and FIG. 2 in terms of the device configuration, and therefore, a duplicate description will be omitted, and description will be made focusing on differences in operation of each member.

  7 shows a state where the optical disk PD2 is not retracted into the optical disk apparatus 1 and the disk stopper 201 is in the initial position. However, when the optical disk PD2 is retracted into the optical disk apparatus 1 as shown in FIG. As can be seen from the position of the portion 201a, the disk stopper 201 is pushed by the optical disk PD1 and moves in the retracting direction, and the angle formed by the front arm 101 and the stopper arm 102 becomes wider than the state of FIG. 101 slides in the (−) Y direction.

  At this time, the front arm 101 performs a rotation operation in addition to the linear operation, and the boss portion 102 b on the stopper arm 102 engages with the front arm 101.

  Next, the progress of the retracting operation of the optical disk PD2 and the positional relationship between the disk stopper 201 and the members related thereto will be described with reference to FIGS. 9 to 11, the cover chassis 9 is removed, and the thin configuration related to the disc stopper 201 in the optical disc apparatus 1 is omitted.

  FIG. 9 shows a state immediately after the optical disk PD1 is housed in the optical disk apparatus 1 by the transport roller 21b (FIG. 3) and the edge in the retracting direction of the optical disk PD1 comes into contact with the disk stopper 201.

  As described above, in a state where the front arm 101 is engaged with the boss portion 102a of the stopper arm 102, the front arm 101 and the stopper arm 102 operate only within a range corresponding to the optical disc PD1 having a diameter of 8 cm. The disk stopper 201 cannot be moved in the retreat direction so as to exceed the range.

  However, when the optical disk PD2 having a diameter of 12 cm is stored in the optical disk apparatus 1, the disk stopper 201 must be further moved in the retracting direction, and the configuration for this is the release rod 101e provided on the front arm 101.

  The release rod 101e extends vertically from the back surface of the front end portion of the front arm 101 on the longitudinal side of the disk entrance / exit SL, and its length is equal to the side surface of the optical disk PD2 when the optical disk PD2 is stored and ejected. The initial position in the horizontal direction is set to a position that contacts the side surface of the optical disk PD2 only when the optical disk PD2 is stored and ejected.

  FIG. 9 shows a state in which more than half of the optical disk PD2 is stored, the side surface in the retreat direction abuts on the disk stopper 201, and the side surface in the (−) X direction abuts on the release rod 101e.

  Here, as described with reference to FIG. 1, the front arm 101 is configured to be rotatable about the boss portion 9b, and the release rod 101e that contacts the side surface of the optical disk PD2 is (−) X. Accordingly, the front arm 101 rotates so that the tip on the side opposite to the tip provided with the release rod 101e moves in the (+) X direction.

  At this time, the engagement between the front arm 101 and the boss portion 102a of the stopper arm 102 is released, and only the disk stopper 201 and the stopper arm 102 are pushed by the optical disk PD2 and further proceed in the retracting direction.

  When the retracting operation of the optical disk PD2 further proceeds, the engagement between the released front arm 101 and the boss portion 102a of the stopper arm 102 causes the front arm 101 to rotate counterclockwise by the elastic force of the spring 104. In the position immediately before the center of the turntable 52 and the center of the optical disk PD2 coincide, the boss portion 102b of the stopper arm 102 and the boss receiving portion 101f (FIG. 12) provided on the back surface of the front arm 101 are engaged. Switch.

  When the front arm 101 is engaged with the boss portion 102b, the stopper arm 102 cannot return to the initial position, and the disk stopper 201 further advances in the retracting direction as the retracting operation of the optical disk PD2 proceeds.

  As described above, the front arm 101 and the stopper arm 102 are configured such that the engagement position is switched according to the diameter of the optical disk, whereby the disk stopper 201 on the central axis along the Y axis. The moving range can be switched according to the diameter of the optical disk. Therefore, it is possible to automatically perform positioning on the central axis along the advancement / retraction direction for optical disks having different diameters.

  Further, since the engagement between the front arm 101 and the stopper arm 102 is released using a simple configuration such as a release rod 101e formed integrally with the front arm 101, the structure is simplified, The occurrence of trouble can be prevented.

  FIG. 10 shows a state in which the center of the turntable 52 and the center of the optical disk PD2 coincide with each other after the optical disk PD2 has come into contact with the disk stopper 201 and moved further to push the disk stopper 201 in the retracting direction. The front arm 101 slides in the (−) Y direction in conjunction with the stopper arm 102, and the slide plate 40 slides in the (−) Y direction accordingly.

  Then, as the slide plate 40 slides in the (−) Y direction, the cam slider 30 is slightly pulled back to the (−) X direction side. As a result, the cam slider 30 meshes with the gear 67 (FIG. 3), The cam slider 30 is further slid in the (−) X direction by the rotational driving force 67, and accordingly, the swing displacement side end of the traverse chassis 51 causes the turntable 52 (FIG. 3) to clamp the clamper 18 (FIG. 1). And the turntable 52 starts to rise.

  When the optical disk PD2 is retracted so far, the edge of the optical disk PD2 does not come into contact with the release rod 101, and the next contact is when the optical disk PD2 moves in the advance direction, and at that time, the front arm 101 is disengaged from the boss portion 102b, and the front arm 101 is engaged with the boss portion 102a.

  FIG. 11 shows that the turntable 52 (FIG. 3) is lifted completely, the clamper 18 (FIG. 1) and the turntable 52 are sucked together, and the optical disk PD2 is held between the clamper 18 and the turntable 52 by pressure bonding. It represents the state that was done.

  When the turntable 52 is completely lifted, the disk stopper 201 is further moved in the retracting direction by a contact prevention mechanism described later, and the optical disk PD2 does not contact the disk stopper 201, and the disk is rotated when the optical disk PD2 is rotated. The stopper 201 is prevented from interfering.

<B. Configuration of each part>
Here, with reference to FIG. 3 again, the configuration of each member related to the disk stopper 201 and its operation will be described with reference to FIGS.

<B-1. Front arm configuration>
FIG. 12 is a perspective view when the front arm 101 is viewed from the rear surface side (that is, the main surface side facing the upper surface of the cover chassis 9).
As shown in FIG. 12, a release rod 101e extending perpendicularly from the main surface at one front end portion in the longitudinal direction is disposed on the back surface of the front arm 101, and a protrusion is provided at the other front end portion. A groove-like boss receiving portion 101f having an opening is provided on the side surface on which 101b is provided. The portion closer to the opening 101a than the boss receiving portion 101f is a boss storage portion 101g, and has an opening on the same side as the boss receiving portion 101f.

  As described above, when one of the boss portions 102a and 102b provided on the stopper arm 102 is engaged with the boss receiving portion 101f and the boss portion 102b is engaged with the boss receiving portion 101f. The boss 102a is stored in the boss storage portion 101g.

  Further, the protrusion 101b is provided between the boss housing 101g and the opening 101a.

<B-2. Configuration of stopper arm>
FIG. 13 is a perspective view when the stopper arm 102 is viewed from the upper surface side (that is, the main surface side opposite to the side facing the upper surface of the cover chassis 9).
As shown in FIG. 13, the upper surface of the stopper arm 102 is provided with an opening 102 c extending in the longitudinal direction at one longitudinal end, and extending perpendicularly from the main surface at the other distal end. Boss portions 102a and 102b are provided. The boss portions 102a and 102b are arranged in series substantially along the width direction.

<B-3. Disc stopper configuration>
FIG. 14 shows a perspective view when the disk stopper 201 is viewed from the upper surface side, and FIG. 15 shows a perspective view when the disk stopper 201 is viewed from the back surface side.

  14 and 15, an elongated upper surface plate 201c, a side surface plate 201e provided perpendicular to the back surface of the upper surface plate 201c, and extending in an arc along the longitudinal direction of the upper surface plate 201c, Two contact pillars 201d projecting vertically from the back surface of the upper surface plate 201c are provided so as to be in contact with both ends in the longitudinal direction of the face plate 201c. The contact column 201d has a diameter larger than the thickness of the side plate 201c, and the side surfaces of the optical disks PD1 and PD2 are in contact with the contact column 201d and do not contact the side plate 201c directly. Yes.

  In FIG. 15, the optical disc PD1 (and PD2) is virtually shown, but as described above, this prevents contact after the optical disc PD1 (and PD2) abuts against the disc stopper 201. The positional relationship between the disc stopper 201 and the optical disc PD1 (and PD2) when the disc stopper 201 is moved further in the retracting direction by the mechanism is shown. In which part of the disc stopper 201 the optical disc PD1 (and PD2) is located Therefore, the disk stopper 201 does not interfere with the rotation of the optical disk PD1 (and PD2).

  Further, a boss portion 201a is provided at the central portion in the longitudinal direction of the upper surface of the upper surface plate 201c so as to protrude perpendicularly to the upper surface, and from both ends in the width direction of the upper surface of the upper surface plate 201c with the boss portion 201a as the center. Each of the two guide portions 201b is provided so as to protrude vertically and engage with a groove portion 9g (FIG. 1) of the cover chassis 9.

  The guide portion 201b is a member that is slightly wider than the width of the groove portion 9g of the cover chassis 9, and is disposed on the base 201x having the same width as the groove portion 9g together with the boss portion 201a. The guide portion 201b protrudes so as to cover the groove portion 9g in the groove width direction in a state where the disc stopper 201 is detached from the groove portion 9g, and the disc stopper 201 rotates around the boss portion 201a. To prevent that.

<C. Device operation>
Next, with reference to FIGS. 1 to 3, the operations of the disc transport operation, the turntable lifting operation and the pickup feeding operation in the optical disc apparatus 1 will be described with reference to FIGS. 16 to 18.

<C-1. Operation when optical disk is not evacuated>
In FIG. 16, as shown in FIGS. 4 and 9, the optical disk is not completely retracted into the optical disk apparatus 1, and the traverse chassis 51 in which the turntable 52, the optical pickup 57, etc. are arranged In order to avoid interference between the optical disk drawn into the apparatus 1 and the turntable 52, the turntable 52 is clamped on the swing displacement side end of the traverse chassis 51 around the rotation shafts 51a and 51b (FIG. 1). It shows a state in which it swings in a direction away from the main chassis 11 and is inclined with respect to the main chassis 11.

  At this time, the cam slider 30 is positioned at the final point in the (+) X direction, the rack gear 30a of the gear portion 30d of the cam slider 30 is not meshed with the gear 67, and the rotational driving force of the gear 67 is the sliding force of the cam slider 30. It does not contribute to the operation. In this state, the rotational driving force of the gear 67 contributes only to the rotation of the transport roller 21b (FIG. 3) in the direction in which the optical disk is retracted.

  Further, since the cam slider 30 is located at the final point in the (+) X direction, the boss portion 40t protruding vertically from the back surface of the tip portion 40a of the second piece 40q of the slide plate 40 is formed in the groove portion 30c of the cam slider 30. (−) Located at the extreme end on the X direction side.

  Further, on the side surface of the second piece 40q of the slide plate 40 on the side where the boss portion 40t is provided, an engagement pin 40f protruding in the same direction as the boss portion 40t is provided. The engaging pin 40f is disposed at a position slightly away from the boss portion 40t along the longitudinal direction of the slide plate 40, and its tip end portion has a conical shape.

  On the other hand, the traverse chassis 51 is provided with a pin engagement wall 51x at a position facing the engagement pin 40f. The traverse chassis 51 is provided on the side surface in the (−) X direction of the end portion on the swing displacement side so as to protrude perpendicularly to the side surface.

  The engagement pin 40f and the pin engagement wall 51x constitute a contact prevention mechanism between the optical disk PD1 (and PD2) and the disk stopper 201.

  In addition, the first piece 40p of the slide plate 40 has openings 40d and 40e that are elongated along the longitudinal direction thereof, the center axes of the two in the longitudinal direction match, and the opening 40d and The slide plate 40 is attached to the bottom surface of the main chassis 11 by being screwed through 40e. The screws are attached so that the slide plate 40 can reciprocate in the Y direction.

<C-2. Operation after saving optical disc>
FIG. 17 shows a traverse chassis with the pivot shafts 51a and 51b as the center after the optical disk has been retracted into the apparatus 1 and the optical disk has reached a position directly above the turntable 52, as shown in FIGS. The end portion on the swing displacement side of 51 swings in a direction in which the turntable 52 is brought closer to the clamper 18 (FIG. 1), and the turntable 52 is in the middle of rising.

  This operation will be further described. When the optical disk moves to a position directly above the turntable 52, the disk stopper 201 (FIGS. 4 and 9) disposed on the back surface of the cover chassis 9 is guided to the groove 9g (FIG. 1) and (+) Y Move in the direction. At this time, the front arm 101 (FIG. 3) slides in the (−) Y direction in conjunction with the stopper arm 102 (FIG. 3), but as described with reference to FIG. Since the protrusions 101b extending in the vertical direction from the rear surface of the front arm 101 are engaged, the slide plate 40 slides in the (−) Y direction simultaneously with the sliding of the front arm 101 in the (−) Y direction.

  When the slide plate 40 slides in the (−) Y direction, the boss portion 40t of the slide plate 40 that has been positioned at the end on the (−) X direction side of the groove 30c of the cam slider 30 until then is in the state shown in FIG. Then, the groove portion 30c is pressed on the inclined surface of the bent portion where the shape in plan view is substantially L-shaped, and the cam slider 30 is pulled back to the (−) X direction side.

  Although the moving distance of this retraction is slight, it is set to a distance sufficient for the rack gear 30a of the gear portion 30d of the cam slider 30 to mesh with the gear 67, and the rotational driving force of the gear 67 is linearized by the rack gear 30a. It is converted into driving force, and the cam slider 30 is slid in the (−) X direction.

  Further, as the slide plate 40 slides in the (−) Y direction, the position of the engagement pin 40f is also moved in the (−) Y direction accordingly, and the pin engagement wall is adjusted to the position after the movement. 51x rises as the traverse chassis 51 rises. In the state shown in FIG. 17, the traverse chassis 51 has not been completely raised yet, and the engagement pin 40 f and the pin engagement wall 51 x are not engaged.

  Here, as described with reference to FIG. 3, the cam slider 30 includes the second piece 30q extending vertically from one side surface of the first piece 30p. The second piece 30q includes a traverse chassis. A cam groove 30f having a Z-shape in a plan view is provided to be engaged with a driven boss 51c (FIG. 16) projectingly formed on the end surface of the swing displacement side end of 51, and (−) X of the cam slider 30 is provided. As the direction slides, the driven boss portion 51c is guided so as to be pulled up in the (+) Z direction in the cam groove 30f, so that the end portion on the swing displacement side of the traverse chassis 51 becomes the turntable. 52 is swung in a direction approaching the clamper 18 (FIG. 1). This operation is called ascending operation of the turntable 52.

  When the optical disk advances, the traverse chassis 51 swings so that the turntable 52 is separated from the clamper 18 by sliding the cam slider 30 in the opposite direction. This operation is referred to as a lowering operation of the turntable 52.

  As described above, the driven boss 51c and the cam slider 30 are the main components of the turntable lifting mechanism that lifts and lowers the turntable.

  The arrangement length of the rack gear 30a of the cam slider 30 is such that the turntable 52 is mounted with an optical disk, and the optical pickup 57 can record and / or read information (+) in the Z direction (predetermined height). The position is set to a length that allows the cam slider 30 to move to the position), and after the rack gear 30a is released from meshing with the gear 67, the sliding operation in the X direction of the cam slider 30 stops.

  When the turntable 52 rises to a predetermined height position, the optical disk is sandwiched between the turntable 52 and the clamper 18 by the attractive force generated by the magnetic force of the clamper 18.

<C-3. Optical pickup feeding operation>
18, as shown in FIGS. 6 and 11, the traverse chassis 51 is completely raised, and the optical disk is sandwiched between the turntable 52 and the clamper 18, so that information can be recorded and / or read out. This shows the state.

  In this state, the boss 58a provided at the end of the slide rack 58 on the turntable 52 side is not engaged with the cam groove 69b of the trigger plate 69, and the engagement between the optical pickup 57 and the trigger plate 69 is released. Thus, it is possible to slide independently in the Y direction. As a result, the optical pickup 57 can reciprocate along the predetermined radial direction (Y axis) according to the rotation direction of the dual-purpose motor 62.

  When recording and / or reproducing information signals, the optical disk is rotated by the rotational driving force of the spindle motor 54 (FIG. 3), and the optical pickup 57 reciprocates along the Y axis, thereby causing a predetermined on the optical disk. An information signal is recorded and / or reproduced in the data area.

  Here, the cam slider 30 is shown in the most moved state in the (−) X direction, the rack gear 30a does not mesh with the gear 67, and the slide plate is placed on the (+) X direction side end of the groove 30c. Forty boss portions 40t are engaged. 3, the groove portion 30c of the cam slider 30 has a substantially L shape in plan view, and is provided with a substantially straight portion along the longitudinal direction of the first piece 30p and a second piece 30q. However, the substantially linear portion has a step-like outline, and the cam slider 30 slides in the (−) X direction. Accordingly, the slide plate 40 is slid in the (−) Y direction.

  With this structure, when the traverse chassis 51 is completely raised and the optical disk is sandwiched between the turntable 52 and the clamper 18, the disk stopper 201 (FIG. 3) is retracted from the side surface of the optical disk PD1 (and PD2). The optical disk PD1 (and PD2) does not come into contact with the disk stopper 201, and the disk stopper 201 is prevented from interfering with the rotation of the optical disk PD1.

  Therefore, it can be said that the groove 30c of the cam slider 30 is also one of the elements constituting the contact prevention mechanism between the optical disk PD1 (and PD2) and the disk stopper 201.

  On the other hand, when the traverse chassis 51 is completely raised, the engagement pin 40f and the wall surface on the (−) Y direction side of the pin engagement wall 51x are engaged, and the slide plate 40 moves in the (+) Y direction. This prevents the disk stopper 201 from moving in the advancing direction of the optical disk PD1 (and PD2), that is, approaching the optical disk PD1 (and PD2). The tip of the engagement pin 40f has a conical shape, and the edge portion of the wall surface on the (−) Y direction side of the pin engagement wall 51x is configured to be rounded. Can be reliably engaged.

<D. Characteristic effects>
As described above, in the optical disc apparatus 1 according to the embodiment of the present invention, the disc stopper 201 can automatically perform positioning on the central axis along the advancing and retracting direction of the optical disc, and a mechanism therefor Is composed of a front arm 101 and a stopper arm 102 provided on the upper surface of the cover chassis 9, and a slide plate 40 and a cam slider 30 provided on the same bottom surface of the main chassis 11, so that the optical disk positioning mechanism is simplified. Structural troubles are less likely to occur, and manufacturing costs can be reduced.

  The optical disc apparatus 1 described above is configured to support optical discs having diameters of 8 cm and 12 cm. However, the type of optical disc is not limited to this, and each member can be adapted to other diameters. It goes without saying that any size optical disk can be accommodated by changing the dimensions.

It is a perspective view which shows the external appearance of the state in the middle of accommodating the optical disk of diameter 8cm in the optical disk apparatus of embodiment which concerns on this invention. It is a perspective view which shows the external appearance of the state which accommodated the optical disk of diameter 8cm in the optical disk apparatus of embodiment based on this invention. It is a perspective view which shows the structure of a traverse chassis. It is a perspective view explaining the operation | movement which accommodates the optical disk of diameter 8cm in the optical disk apparatus of embodiment which concerns on this invention. It is a perspective view explaining the operation | movement which accommodates the optical disk of diameter 8cm in the optical disk apparatus of embodiment which concerns on this invention. It is a perspective view explaining the operation | movement which accommodates the optical disk of diameter 8cm in the optical disk apparatus of embodiment which concerns on this invention. It is a perspective view which shows the external appearance of the state in the middle of accommodating the optical disk of diameter 12cm in the optical disk apparatus of embodiment which concerns on this invention. It is a perspective view which shows the external appearance of the state which accommodated the optical disk of diameter 12cm in the optical disk apparatus of embodiment which concerns on this invention. It is a perspective view explaining the operation | movement which accommodates the optical disk of diameter 12cm in the optical disk apparatus of embodiment which concerns on this invention. It is a perspective view explaining the operation | movement which accommodates the optical disk of diameter 12cm in the optical disk apparatus of embodiment which concerns on this invention. It is a perspective view explaining the operation | movement which accommodates the optical disk of diameter 12cm in the optical disk apparatus of embodiment which concerns on this invention. It is a perspective view explaining the structure of a front arm. It is a perspective view explaining the structure of a stopper arm. It is a perspective view explaining the structure of a disk stopper. It is a perspective view explaining the structure of a disk stopper. It is a perspective view which shows the state of the traverse unit in the stage where the optical disk is not retracted. It is a perspective view which shows the state of the traverse unit in the middle of retracting | saving an optical disk. It is a perspective view which shows the state of the traverse unit in the stage where the optical disk retracted.

Explanation of symbols

9 Cover chassis, 11 Main chassis, 20 Flap, 40 Slide plate, 51c Driven boss, 52 Turntable, 57 Optical pickup, 101 Front arm, 101e Release rod, 102 Stopper arm, 201 Disc stopper, PD1, PD2 Optical disc, SL Disc doorway.

Claims (2)

An optical disk device capable of directly storing and ejecting an optical disk, and recording and / or reproducing information signals with respect to the stored optical disk,
A turntable for rotatably supporting the stored optical disk;
A turntable lifting mechanism that lifts and lowers the turntable between a lowered position that avoids interference with the optical disk that is stored or ejected and a raised position that can support the stored optical disk;
A drive source mechanism that generates a driving force for at least the turntable lifting mechanism;
A positioning mechanism for positioning on a central axis along the advancement and retraction direction of the optical disc,
The positioning mechanism is
A disk stopper disposed on the central axis and in contact with the optical disk when the optical disk is retracted, and restricts the retracted position of the optical disk;
An arm portion that enables reciprocal movement of the disk stopper on the central axis and restricts movement of the disk stopper within a predetermined range;
A slide plate that is disposed on a plane having a different height from the arm portion, and is capable of reciprocating in a direction parallel to the advancing and retracting direction of the optical disc in conjunction with the movement of the arm portion;
It constitutes a part of the turntable elevating mechanism, engages with a part of the slide plate, and moves in a straight line in a first direction perpendicular to the advancing and retracting direction in conjunction with the movement of the slide plate. And a slider member that forcibly slides the slide plate by further sliding in the first direction upon receiving the driving force from the drive source mechanism when the turntable is raised It has a door,
The slider member has a groove portion that penetrates the main surface and extends in the longitudinal direction,
The groove includes a portion formed in a staircase shape whose height decreases as the contour goes in a second direction opposite to the first direction,
With the part of the slide plate engaged with the stepped portion of the groove, the slider member is slid in the first direction so that the disk stopper comes into contact with the optical disk. , Before moving to a position away to the retreat direction, the optical disk apparatus. An optical disk device capable of directly storing and ejecting an optical disk, and recording and / or reproducing information signals with respect to the stored optical disk,
A turntable for rotatably supporting the stored optical disk;
A turntable lifting mechanism that lifts and lowers the turntable between a lowered position that avoids interference with the optical disk that is stored or ejected and a raised position that can support the stored optical disk;
A drive source mechanism that generates a driving force for at least the turntable lifting mechanism;
A positioning mechanism for positioning on a central axis along the advancement and retraction direction of the optical disc,
The positioning mechanism is
A disk stopper disposed on the central axis and in contact with the optical disk when the optical disk is retracted, and restricts the retracted position of the optical disk;
An arm portion that enables reciprocal movement of the disk stopper on the central axis and restricts movement of the disk stopper within a predetermined range;
A slide plate that is disposed on a plane having a different height from the arm portion, and is capable of reciprocating in a direction parallel to the advancing and retracting direction of the optical disc in conjunction with the movement of the arm portion;
It constitutes a part of the turntable elevating mechanism, engages with a part of the slide plate, and moves in a straight line in a first direction perpendicular to the advancing and retracting direction in conjunction with the movement of the slide plate. And a slider member that forcibly slides the slide plate by further sliding in the first direction upon receiving the driving force from the drive source mechanism when the turntable is raised And
The turntable is mounted on a traverse chassis that lifts and lowers the turntable by its swinging motion,
The slide plate is
On the side surface side adjacent to the traverse chassis, it has an engagement pin arranged to protrude vertically from the back surface side of the slide plate,
When the turntable is moved up to a state where the optical disc records and / or reproduces the information signal, the engagement pin is engaged with a pin engagement wall provided in the traverse chassis, the movement in the advancing direction of the optical disc of the slide plate is restricted, the optical disk apparatus.

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