JP5057083B2 - Disk unit - Google Patents

Description

  The present invention relates to a disk apparatus for recording / reproducing information by driving two types of disks having different diameters, and more specifically, a slot-in type in which the disk is supported by a plurality of guide arms and carried into or out of the inside. The present invention relates to a disk device.

  In various information devices such as a computer system, an optical disc (for example, CD, DVD, etc.) capable of storing a large amount of information is used as a recording medium. There are two types of optical disks (hereinafter simply referred to as disks) having different diameters: a 12 cm disk (large diameter disk) and an 8 cm disk (small diameter disk).

  As described in Patent Document 1, a slot-in type disk device has a bezel attached to the front surface of a main body case, and a slot is formed in the bezel. To load a disc, insert the majority of the disc into the slot on the front bezel. A disc support arm and a plurality of guide arms for supporting the outer peripheral edge of the disc are arranged inside the slot.

  When the disk is inserted, the disk support arm is pushed and the loading motor is started. By this loading motor, the loading slider travels parallel to the disc insertion direction. A plurality of guide arms and lifting frames move in conjunction with the traveling of the loading slider. The guide arm rotates to pull the disk into the main body case, and the center hole of the disk is positioned at a centering position that matches the chucking head. The elevating frame rises in conjunction with the movement of the loading slider, inserts the chucking head into the center hole of the disc, and loads the disc. Next, the elevating frame is slightly lowered and positioned at the recording / reproducing position. Finally, the disc support arm and the plurality of guide arms are retracted from the periphery of the disc. Thereafter, the turntable unit provided on the lifting frame rotates the disk, and the optical pickup provided on the lifting frame moves in the radial direction of the disk to record or reproduce information. When the eject button is operated, the loading slider travels in the reverse direction. As a result, the elevating frame is once raised and then lowered toward the retracted position, and the disk is extracted from the chucking head during that time. Thereafter, the disk is carried out through the slot by the disk support arm and the plurality of guide arms.

In the plurality of guide arms, there is a guide arm that urges a small-diameter disk from the lateral direction to regulate the position at the time of loading. The guide arm is rotatable about the rotation axis, and guides the outer peripheral edge of the disc at the tip. The guide arm is provided with a driven pin. The driven pin is engaged with a guide groove provided in the loading slider. The guide groove rotates the guide arm to load the disc when the loading slider moves. The guide arm is biased by a spring toward the direction in which the tip guides the disk.
JP 2008-4254 A

  In recent years, disks having a large writing capacity such as Bur-Ray (trade name) have been provided. This disc is reproduced / recorded using a laser having a wavelength different from that of the CD. For this reason, in order to reproduce / record on this disc, it is necessary to provide two types of optical pickups having different wavelengths. These two optical pickups are arranged so as to be shifted in the radial direction of the disk with respect to the conventional optical pickup. For this reason, the carriage holding the optical pickup is increased in size, and accordingly, the lifting frame is also increased in size. The elevating frame is disposed adjacent to the side of the loading slider. The elevating frame is exposed from the opening of the base panel. For this reason, the bent pieces forming the opening of the base panel come closer to the loading slider, so that they interfere with each other.

  It is an object of the present invention to provide a disk device that prevents a loading slider from interfering with a bent piece that forms an opening of a base panel that exposes a lifting frame.

In order to achieve the above object, according to the present invention, a loading slider that is driven by a motor when a small-diameter or large-diameter disk is loaded / unloaded and linearly moves substantially parallel to the moving direction of the small-diameter or large-diameter disk; For a small-diameter disk that is supported and inserted from the slot, from the guide position that guides the periphery of the small-diameter disk at the tip, through the push-in position that pushes the peripheral edge, and after the chucking of the small-diameter disk is completed, A guide arm that rotates between a retreating position and a retreat position; a driven pin formed on the guide arm between the tip and the rotation shaft; formed on the loading slider and having cam wall surfaces on both sides; The leading end of the guide arm has an inclined first both-side cam groove for pushing the peripheral edge of the small-diameter disk, and a cam wall surface on one side, A first cam groove portion extending in the moving direction of the loading slider and a cam wall surface on both sides, and an inclined second both cam groove portion for moving the tip to a retracted position so as to keep the id arm stationary. And when the driven pin is present in the one-side cam groove, the guide arm is urged away from the peripheral edge of the small-diameter disk so that the driven pin comes out of the one-side cam groove. And a biasing means for preventing the ring lever, a torsion spring for biasing the link lever, a groove formed in the link lever, and a groove formed in the guide arm. The groove is formed in front of the guide arm via the torsion spring and the link lever until just before centering of the small-diameter disk. A first linear cam that urges the periphery of the small-diameter disk in a pushing direction, and a first inclined cam that is inclined with respect to the first linear cam in order to reverse the urging direction of the guide arm immediately before centering the small-diameter disk. When the driven pin slides into the one-side cam groove, the pin of the guide arm is fitted into the second linear cam, and the biasing means is configured so that the driven pin is The guide arm is urged in a direction that does not come out of the one-side cam groove .

  According to the present invention, the cam groove is notched on the outer cam wall surface to narrow the width of the loading slider, so the lifting frame is enlarged without the loading slider interfering with the bent piece of the opening exposing the lifting frame. be able to. In addition, since the biasing means for biasing the guide arm in the direction away from the peripheral edge of the small-diameter disk is provided when the driven pin exists in the one-side cam groove, the driven pin comes out from the one-side cam groove of the loading slider And can slide along the cam groove on one side.

  In FIG. 1, a disk device 1 includes a main body case 2, and a bezel 3 is attached to the front surface thereof. The bezel 3 includes a slot 3a into which a large diameter disk (12 cm disk) D1 or a small diameter disk (8 cm disk) D2 is inserted, a push button 4 for instructing ejection of the disks D1 and D2, and an operation state of the disk device 1. And an indicator 5 for displaying.

  When the disks D1 and D2 are inserted from the slot 3a, the disk loading mechanism starts operating, and the disks D1 and D2 are carried into the main body case 2. When the push button 4 is operated, the disk loading mechanism is reversed, and the disks D1 and D2 are unloaded from the slot 3a.

  A top plate 6 is attached to the main body case 2. An opening 2a through which the chucking head 13 (see FIG. 2) slightly enters when the disks D1 and D2 are chucked is formed almost at the center of the top plate 6. A recess 2b for forming a protruding portion on the inner wall of the main body case 2 is provided around the opening 2a. The protrusion of the main body case 2 receives the disks D1 and D2 when the chucking head 13 is inserted into the center holes D1a and D2a of the disks D1 and D2.

  In FIG. 2, the base panel 7 is fixed to the main body case 2 so as to partition the main body case 2 up and down. The base panel 7 has an opening 7a extending obliquely from the center. A lift frame 8 is disposed in the opening 7a. The lifting frame 8 is formed with an opening 8a extending obliquely from the center.

  When the disks D1 and D2 are carried into or out of the main body case 2, the elevating frame 8 rotates in the vertical direction at the front end located at the center of the apparatus with the shaft 9 on the front bezel 3 side as a fulcrum. In order to mitigate the impact during the up-and-down movement and the impact due to the disturbance during the data recording / reading operation, the up-and-down frame 8 is attached to the base panel 7 at a plurality of locations by an impact support structure (not shown).

  A turntable unit 10 is attached to the tip of the lifting frame 8. The turntable unit 10 includes a spindle motor 11, a turntable 12, and a chucking head 13. The spindle motor 11 is fixed to the inner surface of the elevating frame 8, and the turntable 12 is fixed to the rotor. A chucking head 13 is formed integrally with the turntable 12. The chucking head 13 chucks the disks D1 and D2 set at the centering position when the elevating frame 8 is raised. The chucking head 13 is provided with a plurality of chucking claws 13a biased by springs, and detachably engages the disks D1 and D2. The chucking release pin 71 receives the disks D1 and D2 and removes them from the chucking head 13 when the elevating frame 8 is lowered.

  A pickup unit 14 is attached to the lifting frame 8. The pickup unit 14 includes a carriage 15 disposed below the opening 8a of the elevating frame 8, and two types of pickups 16a and 16b held by the carriage 15.

  Each pickup 16a, 16b includes a laser light source and a light receiver. For the pickup 16a, for example, a DVD + R / RW wavelength 650 nm (infrared) laser and a CD-R / RW wavelength 780 nm (red) laser are used. The pickup 16b uses a 405 nm (blue) laser for Blu-ray Disc (BD).

  The carriage 15 is slidably supported by a pair of guide rods 17 and 18 attached in parallel to the inner surface of the elevating frame 8. Further, as is well known, a screw shaft driven by a thread motor is passed through the carriage 15, and the carriage 15 moves in the radial direction of the disks D1 and D2. In this embodiment, since two types of pickups 16a and 16b are used, the guide rods 17 and 18 are made longer and the stroke of the carriage 15 is made longer than in the conventional disk device. At the same time, the diameters of the guide rods 17 and 18 are made small so as not to hit the bottom plate of the main body case 2, thereby ensuring a lifting stroke of the lifting frame 8.

  2 and 3, a loading motor 38 is disposed on the back surface of the base panel 7. The rotation of the loading motor 38 is transmitted to the disk loading mechanism via the gear train 68, and the disks D1 and D2 are carried in or Unloading is performed. The main parts of the disk loading mechanism are a loading slider 43, a disk support arm 19, a loading arm 22, a left front guide arm 25, a centering arm 27, a right front guide arm 29, and a right rear guide arm 35. All arms are used for loading and unloading the large-diameter disk D1, and arms other than the loading arm 22 are used for loading and unloading the small-diameter disk D2.

  The disk support arm 19 holds the front peripheral edges of the disks D1 and D2 with a holder 21 provided at the tip, and rotates around the rotation shaft 20. The loading arm 22 holds the rear periphery of the large-diameter disk D1 with a loading roller 22a at the tip, and rotates about the rotation shaft 22b. In order to rotate the loading arm 22, a link lever 24 is provided. The link lever 24 is provided with a link pin 24a and an engagement pin 24b. The engaging pin 24 b is engaged with a long hole 22 c provided in the loading arm 22. When the link lever 24 rotates with the link pin 24a as a fulcrum, the loading arm 22 rotates in conjunction with the link lever 24 by the combination of the long hole 22c and the engagement pin 24b. The link pin 24 a enters the guide slit 70 formed in the base panel 7.

  The loading slider 43 has a rack gear 43 a provided at an end thereof meshed with the last gear of the gear train 68. The loading slider 43 reciprocates along a direction parallel to the insertion direction by the rotation of the loading motor 38. When the loading slider 43 moves (advances) in a direction away from the slot 3a, the disks D1 and D2 are loaded into the interior, and when the loading slider 43 moves backward, it is unloaded from the slot 3a.

  In addition, cam grooves 43 d and 43 b are formed in the loading slider 43. The cam groove 43d overlaps the guide slit 70 formed in the base panel 7, and the link pin 24a of the link lever 24 is engaged with these. As the loading slider 43 moves forward / backward, the cam groove 43d and the guide slit 70 work together to rotate the link lever 24. Further, the cam groove 43b is fitted with a driven pin 45a of the first link lever 45 and a cam pin 47a of the second link lever 47. When the loading slider 43 moves forward / backward, the link lever 45, 47 rotates with the rotating shafts 44 and 46 as fulcrums.

  A link pin 47 b is formed on the second link lever 47. The link pin 47 b is fitted in the long hole 48 a of the driven slider 48. The driven slider 48 moves straight in a direction orthogonal to the insertion direction.

  The first link lever 45 has a pin 55 inserted in a connection hole 45 c formed at one end, and is connected to the link arm 54 via the pin 55. The link arm 54 includes a first arm 54a, a second arm 54b slidably connected to the first arm 54a, and a spring 56 for keeping the link arm 54 in the shortest state. One end of the link arm 54 is connected to the base portion 19 a and the gear disc 59. The base portion 19a is provided with the rotating shaft 20 of the disk support arm 19 and a connecting pin 57. The rotating shaft 20 is integrally connected to the rotating shaft 59b of the gear disc 59. The connection pin 57 is inserted into a connection hole 59 a provided at an eccentric position of the gear disk 59, and transmits the rotation of the disk support arm 19 to the gear disk 59. The link arm 54 expands and contracts to enable the disk support arm 19 to rotate without rotating the first link lever 45 while the disks D1 and D2 are pushed into the slot 3a.

  A switch 60 is disposed around the gear disk 59. The switch 60 is turned on when the disk support arm 19 is rotated by a predetermined amount by pushing the disks D1 and D2. In response to a signal from the switch 60, a control circuit (not shown) rotates the loading motor 38 and starts automatic loading of the disks D1 and D2 by the disk loading mechanism.

  In the loading slider 43, a cam groove 43 e for moving the lifting frame 8 up and down is formed on the side facing the lifting frame 8. The driven slider 48 is also formed with a cam groove 48c for moving the lifting frame 8 up and down. The elevating frame 8 has cam pins (not shown) that engage with the cam grooves 43e and 48c, respectively, and moves up and down in conjunction with the movement of the loading slider 43 and the driven slider 48. In FIG. 3, the cam groove 43e does not appear, but this is shown for convenience of explanation.

  The left front guide arm 25 rotates about the rotation shaft 26 as a fulcrum between a guide position where the support member 25a provided at the tip enters the rotation area of the disks D1 and D2 and a retreat position where the support member 25a retreats outside the rotation area. Is biased toward the guide position. In the left front guide arm 25, the support member 25a abuts against the large-diameter disk D1 and rotates clockwise against the bias of the spring 63. A driven pin 25 b is provided at one end of the left front guide arm 25.

  The centering arm 27 is provided with a support portion 27a at the tip, and rotates about the rotating shaft 28 as a fulcrum. The support portion 27a contacts the peripheral edge of the disks D1 and D2 and is positioned at the centering position. A link pin 27 b is fixed to the base end portion of the centering arm 27. The centering arm 27 has a position where the support portion 27a enters the rotation region of the disks D1 and D2 with the rotation shaft 28 as a fulcrum by the rotation of the third link lever 51, and a retracted position away from the peripheral edge of the disks D1 and D2. Rotate between.

  The third link lever 51 is rotatably provided with the rotation shaft 50 as a fulcrum. A link pin 51a is provided at one end, and a connection hole 51b into which the link pin 27b of the centering arm 27 is inserted is provided at the other end. ing. The third link lever 51 is biased by a spring 53 so as to rotate the support portion 27a of the centering arm 27 toward the peripheral edges of the disks D1 and D2. The link pin 51a is engaged with one end 52a of the link wire 52 and a rectilinear cam groove 48b provided in the driven slider 48 along a direction orthogonal to the insertion direction. The other end 52 b of the link wire 52 is engaged with a part 45 b of the first link lever 45. The rotation of the centering arm 27 includes the rotational force transmitted to the third link lever 51 via the loading slider 43 and the link wire 52, and the third link lever via the loading slider 43, the second link lever 47 and the driven slider 48. This is performed by combining with the straight force transmitted to 51.

  The rack slider 65 is disposed along the inner surface of the side wall of the main body case 2. The rack slider 65 includes a rack 65 a that meshes with a gear 59 d of a gear disk 59 that rotates together with the disk support arm 19, and moves forward / backward in conjunction with the rotation of the disk support arm 19. The rack slider 65 moves (retracts) in the direction approaching the slot 3a (the direction opposite to the insertion direction) when the disks D1 and D2 are loaded, and moves away from the slot 3a when the disks D1 and D2 are unloaded (insertion direction). Move to (forward).

The rack slider 65 is formed with a receiving portion 65b, a pressing cam portion 65c, a linear cam portion 65d, a retracting cam portion 65e, a retracting maintaining cam portion 65f, a rotation preventing portion 65g, and a protrusion 65h. The receiving portion 65b receives the driven pin 25b biased by the spring 63 when the disks D1 and D2 are not inserted. The pressing cam portion 65c receives the driven pin 25b when the small-diameter disk D2 is carried in, and rotates the left front guide arm 25 counterclockwise so that the small-diameter disk D2 is pushed toward the centering position. The straight cam portion 65d is formed in a straight line in the insertion direction so as to receive the driven pin 25b when the small-diameter disk D2 is loaded and the left front guide arm 25 does not rotate. The retracting cam portion 65e receives the driven pin 25b when the small-diameter disk D2 is carried in, and rotates the left front guide arm 25 in the clockwise direction so as to retract from the periphery of the small-diameter disk D2. The rear end portion (downstream in the insertion direction) of the retracting cam portion 65e abuts on the driven pin 25b and rotates the left front guide arm 25 in the clockwise direction when both the disks D1 and D2 are carried. The retraction maintaining cam portion 65f is linearly formed in the insertion direction so as to receive the driven pin 25b and maintain the left front guide arm 25 in a retracted state.

  The rotation preventing part 65g is provided so as to face the pressing cam part 65c. The rotation prevention part 65g contacts the driven pin 25b that has entered between the pressing cam part 65c and prevents the left front guide arm 25 from rotating to the retracted position.

  As shown in FIG. 4, the right front guide arm 29 is provided with a support member 29a that supports the peripheral edges of the disks D1 and D2 at the tip and carries them to the centering position. The right front guide arm 29 is provided with a first pin 29b, a guide groove 29c, and a second pin 29d. The second pin 29d is provided in the vicinity of the rotation shaft 30. The right front guide arm 29 rotates about the rotation shaft 30 between a position where the support member 29a enters the rotation area of the disks D1 and D2 and a position where the support member 29a retreats outside the rotation area.

  A central portion of the loading slider 43 is formed with a large-diameter disc regulating portion 43c-1, a small-diameter disc cam portion 43c-2, and a common portion 43c-3. The large-diameter disk restricting portion 43c-1 and the small-diameter disk cam portion 43c-2 are connected to the common portion 43c-3. The large-diameter disk regulating portion 43c-1 engages with the second pin 29d with play in order to push the large-diameter disk D1 toward the centering position with the right front guide arm 29. Since two types of pickups 16a and 16b are provided and the pickup unit 14 is increased in size, the stroke of the carriage 15 is increased and the area of the elevating frame 8 is increased as compared with the conventional case. Along with this, the bent piece forming the opening 7a of the base panel 7 approaches the loading slider 43, so that they interfere with each other. In order to prevent this, the small-diameter disk cam portion 43c-2 is cut out on one side at the center.

  The second pin 29d is engaged with the shared portion 43c-3 in the initial state with play, and when the support member 29a is pushed by the large-diameter disk D1 and the right front guide arm 29 is rotated counterclockwise, It rotates on a trajectory entering the large-diameter disk regulating portion 43c-1. Further, when the small-diameter disk is automatically loaded, the support member 29a is not pushed, so that the state remains as it is, and the small-diameter disk is positioned on the locus that enters the small-diameter disk cam portion 43c-2.

  The link lever 33 is rotatably provided with the rotation shaft 32 as a fulcrum. The link lever 33 is formed with a cam portion 33a having a “h” shape with one end opened. The first pin 29b of the right front guide arm 29 is fitted to the cam portion 33a. A torsion spring 31 is hung on the other end of the link lever 33. The link lever 33 changes the urging direction of the support member 29a to prevent the second pin 29d from separating from the small-diameter disk cam portion 43c-2.

  The right rear guide arm 35 is provided with a support portion 35a at the tip and a follower pin 35b. The driven pin 35 b is fitted in the guide groove 29 c of the right front guide arm 29. For this reason, in the right rear guide arm 35, the support portion 35 a rotates around the rotation shaft 36 in conjunction with the rotation of the right front guide arm 29. By this rotation, when the disks D1 and D2 are carried in, the support portion 35a supports the front peripheral edges of the disks D1 and D2, positions the disks D1 and D2 at the centering position, and moves to the retracted position at the end of loading.

  As shown in FIG. 5, the cam portion 33 a of the link lever 33 connects one ends of the first linear cam 33 a-1 and the second linear cam 33 a-2 in a “h” shape, and the second linear cam 33 a The other end of -2 is open.

The rotational position of the right front guide arm 29 shown in the figure is in an initial state. In this initial state, the second pin 29d is located in the shared part 43c-3.

  When the small-diameter disk D2 is automatically loaded, the support member 29a is not pushed, so the right front guide arm 29 does not rotate, and therefore the second pin 29d is positioned on the locus of entering the small-diameter disk cam portion 43c-2. Yes. When the loading slider 43 moves forward, as shown in FIG. 6, the second pin 29d enters the cam portion 43c-2 for the small diameter disk. When the disk D2 is carried into the small-diameter disk cam portion 43c-2, the common portion 43c-3, both side cam surfaces (first both-side cam groove portions of the present invention) 40, and the surface on the lifting frame 8 side are cut. The second pin 29d is arranged in the order of the missing one-side cam surface (one-side cam groove portion of the present invention) 41 and both-side cam surfaces 42 (second two-side cam groove portions of the present invention) for moving the arm 29 to the retracted position. Pass through.

  When the second pin 29d is engaged with the cam surfaces 40 on both sides, the first pin 29b is engaged with the first linear cam 33a-1. The cam surfaces 40 on both sides are inclined surfaces that rotate the right front guide arm 29 in the clockwise direction by the bias of the torsion spring 31. At this time, the first pin 29b is engaged with the first linear cam 33a-1.

  When the small-diameter disk D2 is before centering, it is immediately before the second pin 29d enters the one-side cam surface 41. At this time, as shown in FIG. 7, the first pin 29b engages with a main part 33a-3 between the first linear cam 33a-1 and the second linear cam 33a-2. At this time, the urging force B of the link lever 33 acts on a straight line A passing through the rotary shaft 30 and the first pin 29b. For this reason, no rotational force is applied to the right front guide arm 29.

  When the second pin 29d enters the one-side cam surface 41, the right front guide arm 29 slightly rotates clockwise, and the urging force of the torsion spring 31 acts on the right front guide arm 29 as shown in FIG. At this time, the first pin 29b engages with the second linear cam 33a-2. The second linear cam 33a-2 is a portion bent into a “he” shape, and has a posture substantially parallel to the insertion direction. For this reason, the urging force B in a direction substantially perpendicular to the second linear cam 33a-2 acts on the link lever 33. This urging force B is in a direction that urges the support member 29a in the outward direction opposite to the chucking head 13 with respect to the axis A passing through the rotation shaft 30 and the first pin 29b. For this reason, the right front guide arm 29 is biased counterclockwise about the rotation shaft 30. Accordingly, the second pin 29d does not leave the one-side cam surface 41. Further, the one-side cam surface 41 restricts the rotation of the right front guide arm 29 that is biased counterclockwise. This position is a position where the support member 29a positions the small-diameter disk D2 at the centering position.

  While the second pin 29d slides on the one-side cam surface 41, the right front guide arm 29 is urged counterclockwise about the rotation shaft 30, and the second pin 29d is pressed against the one-side cam surface 41. Become. When the loading slider 43 moves forward in this state, the second pin 29 d smoothly enters the cam surfaces 42 from the one side cam surface 41. As shown in FIG. 9, the cam surfaces 42 on both sides are inclined surfaces that rotate the right front guide arm 29 counterclockwise about the rotation shaft 30 to move the support member 29 a to the retracted position.

  The large-diameter disk restricting portion 43c-1 is engaged with the second pin 29d with play in order to push the large-diameter disk D1 toward the centering position by the right front guide arm 29.

  One of the large-diameter disk D1 and the small-diameter disk D2 is inserted into the disk device 1. First, the loading / unloading of the large-diameter disk D1 will be described, and then the loading / unloading of the small-diameter disk D2 will be described.

  As shown in FIG. 10, before the large-diameter disk D1 is inserted, the driven pin 25b is received by the receiving portion 65b of the rack slider 65, as indicated by a virtual line. As a result, the left front guide arm 25 is stopped at a position rotated outward by a predetermined amount from the position most rotated in the central direction. At this position, the large-diameter disk D1 is pressed against the support member 25a, and the small-diameter disk D2 can pass through the support member 25a.

  The disk support arm 19 stops at a standby position that is retracted by a predetermined amount toward the chucking head 13 from the advance position at the time of completion of the disk ejection, so that the peripheral edge can be securely held by the holder 21 even for the small-diameter disk D2. I have to. In the loading arm 22, the loading roller 22a enters the insertion path of the large-diameter disk D1. The centering arm 27 is stopped at a position in front of the support portion 27a toward the retracted position away from the peripheral edges of the disks D1 and D2. The elevating frame 8 is in the lowest position.

  When the large-diameter disk D1 is inserted from the slot 3a, the front peripheral edge of the large-diameter disk D1 contacts the holder 21 of the disk support arm 19 and the support member 29a of the right front guide arm 29. At this time, since the large-diameter disk D1 presses the support member 25a of the left front guide arm 25, the left front guide arm 25 rotates outward from the position indicated by the phantom line, and the driven pin 25b is separated from the receiving portion 65b. In FIG. 10 and subsequent figures, the shape of the support member 29a of the right front guide arm 29 is simplified to prevent the drawing from becoming complicated.

  As shown in FIG. 11, when the large-diameter disk D1 is further inserted, the disk support arm 19, the left front guide arm 25, and the right front guide arm 29 are pressed by the large-diameter disk D1 and rotate outward. When the right front guide arm 29 is pushed by the large-diameter disk D1, the right front guide arm 29 rotates counterclockwise about the rotating shaft 30 as a fulcrum. As a result, the second pin 29d rotates on a locus that enters the large-diameter disk restricting portion 43c-1. When the disk support arm 19 is pushed by the large-diameter disk D1 and rotates together with the gear disk 59 counterclockwise by a predetermined angle with the rotary shaft 59b as a fulcrum, the switch 60 is turned on by the gear disk 59 and the loading motor 38 is turned on. To drive. The driving of the loading motor 38 is transmitted to the rack gear 43a of the loading slider 43, and the loading slider 43 advances.

  When the loading slider 43 moves forward, the link lever 24 is pulled, so that the loading arm 22 rotates clockwise with the rotating shaft 22b as a fulcrum, and the loading roller 22a at the tip contacts the right rear periphery of the large-diameter disk D1. Thus, both sides of the large-diameter disk D1 are sandwiched between the loading roller 22a and the support member 25a of the left front guide arm 25.

  When the link arm 54 is pulled by the rotation of the gear disk 59, the first link lever 45 rotates about the rotation shaft 44, and the driven pin 45a moves backward. As the first link lever 45 rotates, the third link lever 51, whose rotation is restricted by the link wire 52, rotates about the rotating shaft 50 by the action of the spring 53. As a result, the centering arm 27 rotates in the center direction, and the left front peripheral edge of the large-diameter disc D1 is supported by the support portion 27a at the tip. At this time, since the link lever 24 is pulled by the advancement of the loading slider 43, the loading arm 22 is rotated in the center direction by the action of the cam groove 43d and the guide slit 70, and the loading roller 22a at the tip is moved to the large-diameter disk D1. Abuts against the right rear edge.

  As the loading slider 43 advances, the second pin 29d provided on the right front guide arm 29 enters the large-diameter disk restricting portion 43c-1, and the right front guide arm 29 is rotated by the large-diameter disk restricting portion 43c-1. Rotate counterclockwise around the fulcrum.

  As the loading slider 43 moves forward, the cam groove 43b pushes up the driven pin 45a of the first link lever 45 and rotates the first link lever 45 with the rotating shaft 44 as a fulcrum. As a result, the gear disk 59 is rotated via the link arm 54, and therefore the disk support arm 19 rotates counterclockwise about the rotation shaft 59b. That is, the holder 21 that supports the front periphery of the large-diameter disk D1 moves in conjunction with the loading of the large-diameter disk D1.

  On the other hand, the support member 25a of the left front guide arm 25 supports the left rear periphery of the large-diameter disk D1, and the driven pin 25b is in a state of being separated from the retracting cam portion 65e.

  Due to the movement of the loading slider 43, the second pin 29d further enters the restricting portion 43c-1 for the large-diameter disk. The restricting portion 43c-1 is engaged with the second pin 29d with play. Due to this play, the right front guide arm 29 rotates counterclockwise around the rotation shaft 30, and the support member 29 a presses the periphery of the large-diameter disk D 1 toward the chucking head 13.

  As shown in FIG. 12, as the loading slider 43 advances, the centering arm 27 rotates in the clockwise direction about the rotation shaft 28 toward the retracted position. When the rack slider 65 moves backward (moves in the direction opposite to the insertion direction) in conjunction with the forward movement of the loading slider 43, the projection 65h contacts the support portion 27a, and the centering arm 27 is slightly rotated counterclockwise. The Thereby, the support of the large-diameter disk D1 by the support portion 27a is continued. When the support portion 27a is in contact with the protrusion 65h, the centering arm 27 is prevented from rotating to the retracted position, so that the left front peripheral edge of the large-diameter disk D1 can be reliably supported and positioned at the centering position. it can. Further, since the protrusion 65h has an inclined surface where the support portion 27a abuts, the centering arm 27 can be easily rotated.

  On the other hand, the front left guide arm 25 rotates clockwise with the rotary shaft 26 as a fulcrum toward the retracted position because the driven pin 25b contacts the retracting cam portion 65e before the large-diameter disk D1 reaches the centering position. . The large-diameter disk D1 is centered by the front peripheral edge of the large-diameter disk D1 coming into contact with the support portion 35a of the right rear guide arm 35.

  The large-diameter disk D1 is positioned at a centering position in which the center hole D1a coincides with the center of the chucking head 13 by the support by the right front guide arm 29 and the centering arm 27 in a direction orthogonal to the insertion direction. In the insertion direction, the disc 21 is positioned at the centering position by the holder 21 of the disk support arm 19 and the loading roller 22a of the loading arm 22.

  Even after the large-diameter disk D1 is centered, the loading slider 43 moves. As a result of this movement, the elevating frame 8 rises to the highest position, and the large-diameter disk D1 is mounted on the chucking head 13. Thereafter, the elevating frame 8 is slightly lowered to position the large-diameter disk D1 at the reproduction / recording position.

  As shown in FIG. 13, by the movement of the loading slider 43 and the rack slider 65 after completion of chucking of the large-diameter disk D1, the end of the large-diameter disk restricting portion 43c-1 (on the opposite side to the insertion direction). The end portion) abuts against the second pin 29d, and the end portion of the restricting portion 43c-1 urges the right front guide arm 29 counterclockwise against the torsion spring 31. As a result, the right front guide arm 29 rotates to the retracted position outside the rotation area of the large-diameter disk D1. Further, the other disk support arm 19, loading arm 22 and right rear guide arm 35 also rotate to the retracted position. The centering arm 27 can be rotated to the retracted position because the protrusion 65h is removed from the back of the support portion 27a by the movement of the rack slider 65 after the chucking is completed, and is rotated to the retracted position by the movement of the loading slider 43.

  When the loading slider 43 completes the forward movement, a limit switch (not shown) is turned on at the rear end. When this limit switch is turned on, the motor control circuit turns off the loading motor 38. Immediately after this, the spindle motor 11 rotates to rotate the large-diameter disk D1, and the sled motor rotates to move the pickup unit 14 in the radial direction of the large-diameter disk D1. The pickup unit 14 records / reproduces the large-diameter disc D1.

  When the large diameter disk D1 is unloaded, the push button 4 is pushed. When the push button 4 is pressed, the spindle motor 11 stops and the sled motor reverses to return the pickup unit 14 to the initial position. Next, the motor control circuit reverses the loading motor 38, retracts the loading slider 43, and starts to carry out the large-diameter disk D1. At the time of unloading, as the loading slider 43 moves backward, each mechanism operates in reverse to the above-described loading. That is, when the loading slider 43 starts to move backward, the elevating frame 8 once rises to the highest position and then lowers to the retreat position. During this time, the large-diameter disk D1 is pushed up by the chucking release pin 71 and detached from the chucking head 13. Until this chucking is released, the disk support arm 19, loading arm 22, and centering arm 27 start to move toward the center and support the periphery of the large-diameter disk D1 (see FIG. 12). ).

  As the rack slider 65 advances (moves in the insertion direction), the support portion 27a comes into contact with the protrusion 65h, and the centering arm 27 is rotated counterclockwise about the rotating shaft 28 as a fulcrum to support the left peripheral edge of the large-diameter disk D1. To do. After the periphery of the large-diameter disk D1 is supported by the arms 19, 22, and 27, the large-diameter disk D1 is unloaded by the force that rotates in the center direction of the disk support arm 19, and the rear end portion is the slot of the front bezel 3. Extrude from 3a to the exposed eject position. When the large-diameter disk D1 is pushed out to the eject position, a limit switch (not shown) is turned on by the tip of the loading slider 43. When this limit switch is turned on, the motor control circuit turns off the loading motor 38 and finishes carrying out. The ejected large-diameter disk D1 is pinched by the operator's finger and pulled out from the slot 3a.

  Next, loading / unloading of the small-diameter disk D2 will be described. When the small-diameter disk D2 is inserted from the slot 3a, the front peripheral edge in the insertion direction of the small-diameter disk D2 is held by the holder 21, as shown in FIG. Here, when the small-diameter disk D2 is inserted to be biased leftward with respect to the slot 3a, the left peripheral edge of the small-diameter disk D2 contacts the support member 25a of the left front guide arm 25 and is pushed back rightward.

  When the small-diameter disk D2 is further inserted, the disk support arm 19 is rotated counterclockwise about the rotation shaft 59b as shown in FIG. In conjunction with the rotation of the disk support arm 19, the rack slider 65 slightly retracts (moves in the direction opposite to the insertion direction), and the support member 29a of the right front guide arm 29 contacts the right peripheral edge of the small-diameter disk D2. As the rack slider 65 moves backward, the driven pin 25b enters between the pressing cam portion 65c and the rotation preventing portion 65g, so the left front guide arm 25 rotates counterclockwise around the rotation shaft 26, and the support member 25a has a small diameter. It contacts the left rear edge of the disk D2. As a result, the small-diameter disk D2 is supported at the three points of the support members 25a and 29a and the holder 21.

  When the switch 60 is turned on by the rotation of the disk support arm 19, the loading motor 38 is driven. The driving of the loading motor 38 is transmitted to the rack gear 43a of the loading slider 43, and the loading slider 43 advances.

  When the loading slider 43 moves forward, the second pin 29d of the right front guide arm 29 enters the cam portion 43c-2 for a small diameter disk. At this time, the right front guide arm 29 rotates clockwise around the rotation shaft 30 by the small diameter disk cam portion 43c-2, and the right peripheral edge of the small diameter disk D2 is supported by the support member 29a. Since the right front guide arm 29 is urged by the torsion spring 31 to rotate counterclockwise about the rotation shaft 30 as described with reference to FIG. 8, the second pin 29 d is separated from the one-side cam surface 41. There is nothing. Accordingly, as described with reference to FIG. 8, the right front guide arm 29 is urged to rotate counterclockwise about the rotation shaft 30, and the second pin 29 d is kept in contact with the one-side cam surface 41.

  When the rack slider 65 moves backward (moves in the direction opposite to the insertion direction) in conjunction with the forward movement of the loading slider 43, the left front guide arm 25 is rotated counterclockwise about the rotation shaft 26 by the pressing cam portion 65c. The support member 25a supports the left rear edge of the small-diameter disc D2 and guides it toward the centering position.

  In conjunction with the advancement of the loading slider 43, the disk support arm 19 rotates outward while supporting the small-diameter disk D2.

  When the loading slider 43 further moves and the loading of the small-diameter disk D2 is continued, the right front guide arm 29 stops rotating. Thereafter, according to the moving amount of the loading slider 43, the disk support arm 19 rotates outward while supporting the small-diameter disk D2, and the left front guide arm 25 and the centering arm 27 rotate in the center direction.

  As shown in FIG. 16, when the loading slider 43 is further moved and the loading of the small-diameter disk D2 is continued, the disk support arm 19 is greatly rotated outwardly in conjunction with the advancement of the loading slider 43, thereby reducing the small-diameter disk. The support of the peripheral edge of D2 is finished, and the gear disk 59 retracts the rack slider 65 by this rotation. When the rack slider 65 moves backward, the driven pin 25b comes out between the pressing cam portion 65c and the rotation preventing portion 65g, and the driven pin 25b is guided by the retracting cam portion 65e. By rotating clockwise around the fulcrum, the support of the peripheral edge of the small-diameter disk D2 is completed. The small-diameter disk D2 is positioned at the centering position in a state in which the periphery is supported at three points: the support portion 27a of the centering arm 27, the support member 29a of the right front guide arm 29, and the support portion 35a of the right rear guide arm 35. .

  Further, the elevating frame 8 starts to rise during positioning at the centering position. Then, as shown in FIG. 17, the chucking head 13 chucks the center hole D2a of the small diameter disk D2. The movement of the loading slider 43 after completion of chucking causes the second pin 29d to enter the double-sided cam surface 42, the right front guide arm 29 moves to the retracted position outside the rotation region, and the other arms 19, 22, 25, 27. , 35 also move to the retracted position. Further, the lifting frame 8 is slightly lowered by the movement of the loading slider 43 after the chucking is completed, and the small-diameter disk D2 is positioned at the reproduction / recording position.

  When the small-diameter disk D2 is positioned at the reproduction / recording position, the loading motor 38 stops because the tip of the loading slider 43 turns on the limit switch. As described above, the spindle motor rotates to enable recording / reproduction of the small-diameter disk D2.

  In order to take out the small-diameter disk D2, the push button 4 is pressed. As with the large-diameter disk D1, the loading motor 38 reverses and the loading slider 43 moves backward. When the loading slider 43 starts to move backward, the elevating frame 8 once rises and then descends to the retracted position. During this time, the small-diameter disk D2 is pushed up by the chucking release pin 71 and the chucking by the chucking head 13 is released.

  Until the chucking of the small-diameter disk D2 is released as described above, as shown in FIG. 16, the arms 35, 27, and 29 rotate in the center direction to support the periphery of the small-diameter disk D2. Become. Subsequently, in the operation of following the reverse order of FIGS. 15 and 14, when the disk support arm 19 rotates clockwise about the rotation shaft 59b, the small-diameter disk D2 is pushed toward the slot 3a. When the small-diameter disk D2 is pushed out to the eject position, the limit switch is turned on by the front end of the loading slider 43 and the loading motor 38 is stopped.

It is a perspective view which shows the disc apparatus and disc of this invention. It is a perspective view of the disk apparatus which removed the top plate. It is a disassembled perspective view which shows the mechanism which drives a disk support arm, a loading arm, a left front guide arm, and a centering arm. It is a disassembled perspective view which shows the mechanism which drives a right front guide arm and a right rear guide arm. It is explanatory drawing which shows the initial state of a right front guide arm and a right rear guide arm. It is explanatory drawing which shows a state when a small diameter disc is inserted. It is explanatory drawing which shows the state before centering a small diameter disc. It is explanatory drawing which shows the state in which a small diameter disc is centered. It is explanatory drawing which shows the state which the right front guide arm and the right rear guide arm moved to the retracted position. It is a top view which shows the conveyance process of a large diameter disc, and has shown the state which a disc contact | wins a disc support arm. It is a top view which shows the conveyance process of a large diameter disc, and has shown the state which the disc pushed the disc support arm and turned on the switch of the loading motor. It is a top view which shows the conveyance process of a large diameter disc, and has shown the state which centered the disc by each arm. It is a top view which shows the conveyance process of a large diameter disc, and has shown the state which moved each arm to the retracted position after centering. It is a top view which shows the conveyance process of a small diameter disc, and has shown the state which a disc contact | wins a disc support arm. It is a top view which shows the conveyance process of a small diameter disc, and has shown the state which the disc pushed the disc support arm and switched on the loading motor. It is a top view which shows the conveyance process of a small diameter disc, and has shown the state which centered the disc with three arms. It is a top view which shows the conveyance process of a small diameter disc, and has shown the state which moved each arm to the retracted position after centering.

Explanation of symbols

29 right front guide arm 29b first pin 29d second pin 31 torsion spring 33 link lever 33a cam portion 43 loading slider 43c double cam portion 43c-2 cam portion for small diameter disc

Claims (1)

In a disk device in which a small diameter disk and a large diameter disk can be loaded through a slot,
A loading slider that is driven by a motor at the time of loading / unloading a small or large diameter disk and linearly moves substantially parallel to the moving direction of the small or large diameter disk;
For small-diameter discs that are rotatably supported on the rotary shaft and inserted from the slot, after the guide position for guiding the periphery of the small-diameter disc at the tip, through the push-in position for pushing the periphery, the small-diameter disc is completed after chucking of the small-diameter disc A guide arm that rotates between a retracted position away from the periphery of the disk;
A driven pin formed on the guide arm between the tip and the rotation shaft;
Formed on the loading slider, having cam wall surfaces on both sides, an inclined first both-side cam groove for pushing the peripheral edge of the small-diameter disk at the tip of the guide arm, and a cam wall surface on one side, A one-side cam groove extending in the moving direction of the loading slider and a slanted second both-side cam groove having a cam wall surface on both sides and moving the tip to a retracted position so as to keep the arm stationary. A cam groove having
When the driven pin is present in the one-side cam groove, a biasing means is provided to bias the guide arm in a direction away from the peripheral edge of the small-diameter disk so that the driven pin does not come out of the one-side cam groove. When,
Equipped with a,
The biasing means includes a ring lever, a torsion spring that biases the link lever, a groove formed in the link lever, and a pin formed in the guide arm and fitted into the groove,
The groove includes a first linear cam that urges the guide arm in a direction to push a peripheral edge of the small-diameter disk via the torsion spring and the link lever until just before centering the small-diameter disk, and just before centering the small-diameter disk. A second linear cam inclined with respect to the first linear cam in order to reverse the biasing direction of the guide arm from
When the driven pin slides into the one-side cam groove, the pin of the guide arm is fitted into the second linear cam, and the urging means is arranged so that the driven pin does not come out of the one-side cam groove. A disk device that biases the guide arm .

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