JP5213770B2 - Disk loading device and disk device - Google Patents

Description

  The present invention relates to a disk loading apparatus for directly storing or ejecting an optical disk as an information recording medium such as a compact disk (CD) or a digital versatile disk (DVD) in a disk device.

  2. Description of the Related Art Conventionally, slot-in type disk devices that directly store or eject optical disks are known. In such a disk device, an optical disk positioning member called a disk stopper is provided to cope with optical disks having different diameters (for example, 12 cm, 8 cm, etc.) (see, for example, Patent Document 1).

  The disk stopper is configured to be able to reciprocate in the insertion / ejection direction of the optical disk. When the optical disk is stored in the disk device, the disk stopper moves to a predetermined position in accordance with the diameter of the optical disk, and stops moving at the predetermined position, thereby positioning the optical disk in the insertion / ejection direction. . After the positioning of the optical disk is completed, the disk stopper is separated from the optical disk so as not to prevent the rotation of the optical disk.

Japanese Patent No. 2955116 (see paragraphs 0014-0024)

  In the conventional disk apparatus, when the optical disk is stored, the optical disk contacts the disk stopper and moves integrally. However, when the optical disk is ejected, the disk stopper starts moving with a delay from the movement of the optical disk. May return to the outer edge of the optical disk vigorously before returning to the initial position. Therefore, if the storing operation and the ejecting operation of the optical disk are repeated, a concave collision mark is generated on the outer edge of the optical disk, and the optical disk is damaged. In addition, since a concave collision mark is also generated on the disk stopper side, the concave collision mark becomes larger as the number of repetitions of the storing operation and the discharging operation is increased, and the stop position of the optical disk may deviate from the original manufacturing position. As a result, a malfunction may occur, for example, the clamping operation of pressing the optical disk on the turntable cannot be performed normally.

  The present invention has been made to solve the above-described problems, and prevents the collision between the optical disk and the disk stopper when the optical disk is ejected, thereby generating the outer edge of the optical disk or the collision mark of the disk stopper. The purpose is to prevent.

The disc loading apparatus according to the present invention is capable of moving a plurality of types of optical discs having different diameters in the insertion / ejection direction by abutting the outer edge of the transported optical disc and the conveyance mechanism capable of conveying in the insertion / ejection direction with respect to the disc device A disc stopper, a rotatable stopper arm that restricts the disc stopper to a predetermined position according to the diameter of the optical disc, and an outer edge of the optical disc to be conveyed, and the stopper arm at a position according to the diameter of the optical disc. A rotatable disk selector that restricts the rotation, and a biasing member that biases the disk stopper or the stopper arm toward the respective initial positions. When the optical disk is inserted, the disk selector is rotated by contacting the outer edge of the optical disk to release the restriction of the rotation of the stopper arm. Further, the disk stopper is moved by contacting the outer edge of the optical disk, thereby moving the stopper arm. Is rotated, and the rotation is restricted by the disk selector at that position. When the optical disk is ejected, the optical disk is ejected at least to a position where the outer edge of the optical disk is in the ejecting direction from the position where the outer edge of the optical disk starts contact with the disk stopper when inserted, and the outer edge of the optical disk and the disk stopper do not contact In addition, the disk selector releases the restriction of the stopper arm rotation and enables the stopper arm and the disk stopper to return to the initial positions.

  According to the present invention, when the optical disk is ejected, the optical disk is transported at least to the vicinity of the position where the outer edge of the optical disk starts contacting with the disk stopper when inserted, and then the stopper arm and the disk stopper are returned to the initial positions. Therefore, it is possible to prevent the disk stopper from colliding with the outer edge of the optical disk during the ejection operation. As a result, it is possible to prevent the occurrence of collision marks at the outer edge of the optical disk or at the disk stopper.

It is a perspective view of the disc apparatus provided with the disc loading apparatus in Embodiment 1 of this invention, and is a figure which shows the state in the middle of the optical disk being accommodated, or ejected. BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a perspective view of a disk device provided with a disk loading device in Embodiment 1 of the present invention, and shows a state in which an optical disk is stored. It is the perspective view which looked at the cover chassis in Embodiment 1 of this invention, and the component attached to this cover chassis from the downward direction. It is a disassembled perspective view which shows the clamper arm in Embodiment 1 of this invention, and the component attached to this clamper arm. It is a top view which shows the structure of the stopper arm in Embodiment 1 of this invention. 1 is an exploded perspective view of a disk device including a disk loading device according to Embodiment 1 of the present invention. FIG. 7 is an exploded perspective view of the disk device including the disk loading device according to the first embodiment of the present invention when viewed from a direction different from FIG. 6. It is a perspective view which shows the disc accommodation operation | movement of the disc loading apparatus in Embodiment 1 of this invention, and is a figure which shows the state immediately after the start of the optical disc accommodation operation | movement. It is a top view which shows the disk storage operation | movement of the disk loading apparatus in Embodiment 1 of this invention, and is a figure which shows the state immediately after the start of the optical disk storage operation. It is a perspective view which shows the disk accommodation operation | movement of the disk loading apparatus in Embodiment 1 of this invention, and is a figure which shows the state which the outer edge of the optical disk contact | abutted to the contact pin of the disk stopper. It is a top view which shows the disk accommodation operation | movement of the disk loading apparatus in Embodiment 1 of this invention, and is a figure which shows the state which the outer edge of the optical disk contact | abutted to the contact pin of the disk stopper. It is a perspective view which shows the disk accommodation operation | movement of the disk loading apparatus in Embodiment 1 of this invention, and is a figure which shows the state which the disk selector engaged with the 2nd groove part of the stopper arm. It is a perspective view which shows the disk accommodation operation | movement of the disk loading apparatus in Embodiment 1 of this invention, and is a figure which shows the state which the disk selector engaged with the 2nd groove part of the stopper arm. It is a perspective view which shows the disk accommodation operation | movement of the disk loading apparatus in Embodiment 1 of this invention, and is a figure which shows the state which a slider trigger moves to -Y direction with a disk selector, and starts a movement integrally with a slider. . It is a top view which shows the disk accommodation operation | movement of the disk loading apparatus in Embodiment 1 of this invention, and is a figure which shows the state which a slider trigger moves to -Y direction with a disk selector, and starts a movement integrally with a slider. . It is a perspective view which shows the disk accommodation operation | movement of the disk loading apparatus in Embodiment 1 of this invention, and is a figure which shows the state which the slider moved to the terminal of the movement range of -Y direction. It is a top view which shows the disk accommodation operation | movement of the disk loading apparatus in Embodiment 1 of this invention, and is a figure which shows the state which the slider moved to the terminal of the movement range of -Y direction. It is a perspective view which shows the disc discharge operation | movement of the disc loading apparatus in Embodiment 1 of this invention, and the state immediately after a slider returns to an initial position, the clamp of an optical disc is cancelled | released, and an optical disc starts discharge | emission with a conveyance roller. FIG. It is a top view which shows the disc discharge operation | movement of the disc loading apparatus in Embodiment 1 of this invention, and the state immediately after a slider returns to an initial position, the clamp of an optical disc is cancelled | released, and an optical disc starts discharge | emission with a conveyance roller. FIG. It is a perspective view which shows the disc discharge operation | movement of the disc loading apparatus in Embodiment 1 of this invention, and is a figure which shows the state which the slider trigger and the disc selector returned to the initial position. It is a top view which shows the disc discharge operation | movement of the disc loading apparatus in Embodiment 1 of this invention, and is a figure which shows the state which the slider trigger and the disc selector returned to the initial position. FIG. 3 is a perspective view showing a disk ejection operation of the disk loading device according to the first embodiment of the present invention, and shows a state where the restriction of the rotation of the stopper arm by the disk selector is released and the disk stopper can be returned to the initial position. is there. It is a top view which shows the disk discharge | emission operation | movement of the disk loading apparatus in Embodiment 1 of this invention, and is a figure which shows the state from which rotation restrictions of the stopper arm by a disk selector are cancelled | released, and a disk stopper can return to an initial position. is there. It is a top view which shows the structure of the stopper arm in the disc loading apparatus of a comparative example. It is a top view which shows the structure of the stopper arm in Embodiment 2 of this invention.

  Embodiments of a disk loading apparatus according to the present invention will be described below with reference to the drawings.

Embodiment 1 FIG.
1 and 2 are perspective views showing a disk loading apparatus employing a roller-type slot-in mechanism according to Embodiment 1 of the present invention. FIG. 1 shows a state where the optical disk is being stored or the ejection operation is completed, and FIG. 2 shows a state where the optical disk is stored.

  In the following description, the direction parallel to the insertion / ejection direction of the optical disc is defined as the Y direction, the insertion direction (storage direction) of the optical disc is defined as the + Y direction, and the ejection direction is defined as the -Y direction. A direction orthogonal to the Y direction in a plane parallel to the main surface of the optical disk is defined as an X direction, and a right side facing the + Y direction is defined as a + X direction, and a left side is defined as a -X direction. Also, the direction orthogonal to the main surface of the optical disk is defined as the Z direction, the label surface side of the optical disk is defined as the + Z direction, and the opposite side (recording / reproducing surface side) is defined as the -Z direction.

<Overall configuration of disk loading device>
As shown in FIG. 1 and FIG. 2, the disk device 1 has a base body 10 composed of a main chassis 11 and a cover chassis 9 that is an upper lid thereof. On one side surface (end surface in the −Y direction) of the base body 10, a slot-like disk inlet / outlet SL for storing and discharging the optical disk 200 is formed.

  The disk entrance / exit SL is a rectangular opening having a long side in the X direction and a short side in the Z direction. The disk entrance / exit SL includes a U-shaped opening 11 h (FIG. 2) provided in the main chassis 11, and an end face (bending end face) 9 h obtained by bending an end of a plate-like member constituting the cover chassis 9. The surroundings are defined by On the back surface of the cover chassis 9, a disc guide 20 (FIG. 3) that contacts the outer edge of the optical disc 200 to be inserted and holds the optical disc 200 with a later-described transport roller 23 is arranged inside the disc entrance / exit SL. It is installed.

<Configuration for optical disc diameter discrimination and positioning>
A configuration for discriminating and positioning the diameter of the optical disc 200 will be further described with reference to FIGS. FIG. 3 is a perspective view of the cover chassis 9 and each component attached to the cover chassis 9 as viewed from the back side of the cover chassis 9. Components necessary for discriminating and positioning the diameter of the optical disc 200 are almost attached to the cover chassis 9.

  As shown in FIGS. 1 and 2, a disk selector 8 for determining the diameter of the inserted optical disk 200 is disposed on the upper surface (+ Z side surface) of the cover chassis 9. The disc selector 8 has a long shape extending in the Y direction, and has a boss portion 8c as a rotation shaft at a substantially central portion. The boss portion 8 c is engaged with a long hole portion 9 c (FIG. 3) formed in the cover chassis 9 and extending in the Y direction. Thus, the disk selector 8 is supported so as to be rotatable about the boss portion 8c. The boss 8c is movable in the Y direction within the elongated hole 9c, whereby the disc selector 8 is supported so as to be movable a predetermined distance (for example, about 4 mm) in the Y direction.

  At the end in the −Y direction of the disk selector 8, a contact pin 8 a that can contact the outer edge of the optical disk 200 is erected in the −Z direction. At the end in the + Y direction of the disk selector 8, an engagement pin 8b that selectively engages with grooves 16b and 16c of a stopper arm 16 described later is erected in the -Z direction. The disc selector 8 is rotated counterclockwise in a top view by a spring 103 provided on the cover chassis 9, in other words, a direction in which the contact pin 8a contacts the optical disc 200 (that is, the engagement pin 8b is described later). The stopper arm 16 is biased so as to rotate in a direction in which the stopper arm 16 engages with the grooves 16b and 16c. The disk selector 8 is also biased in the + Y direction by a spring 104 described later. Due to the urging force of the spring 104, the position in the + Y direction is the initial position in the movement range of the disk selector 8 in the Y direction.

  As shown in FIG. 3, a clamper arm 12 is attached to the −Z side of the cover chassis 9. The clamper arm 12 is rotatably supported by rotation shafts 9a and 9b in the X direction provided in the cover chassis 9 in the vicinity of the end portion in the + Y direction. Further, the clamper arm 12 is urged by a spring 101 (FIG. 1) provided in the cover chassis 9 in a direction in which an end portion in the −Y direction rotates in the + Z direction. A cam pin 12d is erected on the side of the clamper arm 12 in the -X direction, and this cam pin 12d is engaged with a cam portion 18b of a slider 18 described later. Due to the engagement between the cam pin 12d and the cam portion 18b, the clamper arm 12 rotates about the rotation shafts 9a and 9b. The clamper arm 12 is in a posture parallel to the horizontal plane (XY plane) when the storage operation of the optical disc 200 is completed, and is controlled to a posture inclined with respect to the horizontal plane in other states.

  FIG. 4 is an exploded perspective view showing the clamper arm 12 and each component attached to the clamper arm 12. The clamper arm 12 holds an upper clamper 13, a lower clamper 14, a disk stopper 15 and a stopper arm 16.

  The upper clamper 13 and the lower clamper 14 are disposed in the vicinity of the tip end portion of the clamper arm 12 in the −Y direction, and hold the optical disc 200 in a pressure-bonded manner with a turntable 52 (FIG. 7) described later. A magnet (not shown) is held between the upper clamper 13 and the lower clamper 14. A guide groove 12b extending in the Y direction is formed substantially at the center of the clamper arm 12 in the X direction.

  The disk stopper 15 has an elongated shape that is long in the X direction, and a boss portion 15c that protrudes in the + Z direction and a guide portion 15d that is a protrusion adjacent to the + Y side are provided at the approximate center in the X direction. Is provided. The disc stopper 15 is guided so as to be movable in the Y direction by engaging the boss portion 15 c and the guide portion 15 d with the guide groove 12 b of the clamper arm 12. The disk stopper 15 has a pair of contact pins 15a (FIG. 3) that can contact the outer edge of the optical disk 200 at both ends in the longitudinal direction (X direction). A pair of contact pins 15b and 15b (FIG. 3) capable of contacting the outer edge of the optical disc 200 are provided on the inner side in the direction. The pair of inner contact pins 15b and 15b are in contact with the optical disc 200 in a normal state. On the other hand, the pair of outer abutment pins 15a faces the optical disc 200 toward the pair of abutment pins 15b and 15b on the inner side when the small-diameter optical disc 200 is inserted by being offset with respect to the disc inlet / outlet SL. It is a guide.

  As shown in FIG. 3, the stopper arm 16 regulates the stop position of the optical disk 200 together with the disk stopper 15, has a long shape, and has a circular hole 16g at a substantially central portion in the longitudinal direction. ing. The stopper arm 16 is rotatably held when the support pin 12a erected on the clamper arm 12 is engaged with the hole 16g. The stopper arm 16 has an elongated hole (groove) -shaped engaging portion 16a in the vicinity of one end in the longitudinal direction, and the engaging portion 16a moves the boss portion 15c of the disk stopper 15 (the guide groove 12b in the + Z direction). Is engaged). When the disk stopper 15 moves in the Y direction along the guide groove 12b, the rectilinear movement is centered on the hole 16g (support pin 12a) of the stopper arm 16 due to the engagement between the boss 15c and the engaging portion 16a. Is converted to rotation.

  FIG. 5 is a plan view showing the shape of the stopper arm 16. A hole 160 is formed at the end of the stopper arm 16 opposite to the side where the engaging portion 16a is formed. The first groove portion 16b and the second groove portion 16c that can be engaged with the engagement pin 8b of the disk selector 8 described above are respectively provided near the end portion in the −Y direction and near the end portion in the + Y direction of the hole portion 160. Is formed. Further, between the first groove portion 16b and the second groove portion 16c, the second groove portion 16b is connected to the second groove portion 16c with respect to the arc R coaxial with the rotation center C of the stopper arm 16 (center of the hole portion 16g). The first inclined surface 16d extending in a direction in which the distance from the rotation center C decreases toward the groove portion 16c, and the rotation center C extending from the terminal portion of the first inclined surface 16d to the second groove portion 16c. And a second slope 16e extending in a direction in which the distance from the surface increases. The first inclined surface 16d and the second inclined surface 16e are formed continuously in a substantially V shape. Here, the first inclined surface 16d is formed in a curved shape, so that the rotation load of the stopper arm 16 until the engaging pin 8b of the disk selector 8 reaches the second inclined surface 16e is made uniform. The effect which performs is obtained.

  When a small-diameter optical disk 200 having a diameter (outer diameter) of 8 cm is inserted into the first groove 16b of the stopper arm 16, the engaging pin 8b of the disk selector 8 is engaged. Further, when a large-diameter optical disk 200 having a diameter of 12 cm is inserted into the second groove 16c of the stopper arm 16, the engaging pin 8b of the disk selector 8 is engaged. This selection is performed by rotating the contact pin 8a of the disk selector 8 in contact with the outer edge of the optical disk 200 as will be described later.

  The reason why the engaging pin 8b of the disc selector 8 is engaged with the first groove portion 16b or the second groove portion 16c of the stopper arm 16 as described above is that the optical disc 200 having a different diameter is placed at a predetermined position corresponding to each diameter. This is because the disk selector 8 is moved in the −Y direction to shift to the clamping operation. When the engaging pin 8b of the disc selector 8 is engaged with the first groove portion 16b or the second groove portion 16c of the stopper arm 16, and the stopper arm 16 moves in the -Y direction, the boss 8c described above becomes a long hole. By moving within the section 9c (FIG. 3), the disk selector 8 moves by a predetermined distance in the -Y direction.

  As shown in FIG. 1, the stopper arm 16 is attached to a predetermined rotation direction (clockwise in top view) around the hole 16g by a spring (biasing member) 102 provided on the clamper arm 12. It is energized. This rotation direction is a direction in which the disk stopper 15 moves in the −Y direction (by engagement between the engaging portion 16a and the boss portion 15c shown in FIG. 4). A cushion plate 17 is formed on the clamper arm 12 so as to be in contact with the upper clamper 13 when the disk stopper 15 moves in the -Y direction. When the contact surface 15e (FIG. 4) formed on the disk stopper 15 contacts the cushion plate 17, the initial position of the disk stopper 15 is determined.

  As shown in FIG. 3, the disc guide 20 guides the optical disc 200 by pressing and holding the optical disc 200 with a conveyance roller 23 described later. This disc guide 200 has inclined surfaces 20a, 20c, 20e and inclined surfaces 20b, 20d, 20f on both sides (+ X side and -X side) with the center in the X direction interposed therebetween. The inclined surfaces 20a, 20c, and 20e and the inclined surfaces 20b, 20d, and 20f are formed symmetrically with respect to the center in the X direction. More specifically, the inclined surfaces 20a, 20c, and 20e and the inclined surfaces 20b, 20d, and 20f have an inclination such that the protruding amount in the −Z direction increases as the distance from the center in the X direction increases. Due to this inclination, the outer edge of the optical disk 200 is in contact (sliding) with the inclined surfaces 20a to 20f when the optical disk 200 is transported, and the main surface of the optical disk 200 and the disk guide 20 are not in contact with each other. This prevents the main surface of the optical disc 200 from being scratched when the optical disc 200 is transported.

<Configuration for transporting optical disk and clamping operation>
Next, a configuration for transporting and clamping the optical disc 200 will be described with reference to FIGS. 6, 7, 8 </ b> A, 8 </ b> B, 9 </ b> A, and 9 </ b> B. FIG. 6 is an exploded perspective view of the disk device 1 as viewed from the left front. FIG. 7 is an exploded perspective view of the disk device 1 as viewed from the right front. 8A and 8B are a perspective view and a plan view showing a state immediately after the optical disk 200 is started to be stored.

  As shown in FIG. 8A, in the main chassis 11, a roller arm 21 is attached in the vicinity of the disk doorway SL. The roller arm 21 is long in the X direction, and is rotatably attached to the main chassis 11 with a pair of support pins 21a provided at both ends in the longitudinal direction as pivot axes in the X direction. A pair of bearings 22 made of plastic are attached to both ends in the longitudinal direction of the tip of the rotation side of the roller arm 21. A shaft 60 whose axial direction is the X direction is rotatably attached to the bearing 22, and a pair of conveying rollers 23 made of, for example, rubber rollers are attached to the shaft 60 side by side in the axial direction. .

  The roller arm 21 is also biased by a spring (not shown) in a direction in which the transport roller 23 presses the optical disc 200 between the disc guide 20. In the vicinity of the shaft 60, a contact pin 21b extending in the −X direction from the end portion of the roller arm 21 on the −X side is provided. The contact pin 21b is in contact with a slider 18 described later. By the contact between the slider 18 and the contact pin 21b, the roller arm 21 rotates about the support pin 21a, and the optical disk 200 is pressed and released from the conveyance roller 23.

  Each of the pair of transport rollers 23 has a length that substantially halves the distance between the pair of bearings 22. Each conveyance roller 23 has an annular (doughnut-shaped) cross section, and has a substantially cylindrical shape in which the outer diameter decreases with increasing distance from each bearing 22 (as approaching the longitudinal center of the shaft 60). The inner diameter of the transport roller 23 is slightly larger than the outer diameter of the shaft 60, but rotates integrally with the shaft 60.

  A roller gear 24 composed of a spur gear is attached to one end of the shaft 60 in the axial direction (X direction) by press-fitting. The roller gear 24 rotates by engaging with a second gear 29 described later, and the shaft 60 and the conveying roller 23 rotate together with the roller gear 24. As a result, in a state where the optical disk is pressed and held between the transport roller 23 and the disk guide 20, the transport roller 23 rotates to transport the optical disk 200 in the insertion direction or the ejection direction.

  A slider 18 is attached in the vicinity of the side wall in the −X direction of the main chassis 11. The slider 18 has a long shape that is long in the Y direction, and is supported so as to be able to reciprocate a predetermined distance (about 15 mm) in the Y direction. On the end surface in the −Y direction of the slider 18, an inclined surface 18 a that abuts on the abutting pin 21 b of the roller arm 21 and urges in the −Z direction is formed. A stepped cam portion (cam groove) 18 b that engages with the cam pin 12 d of the clamper arm 12 is formed in the vicinity of the end surface of the slider 18 in the + Y direction. The slider 18 has a long hole near the end in the -Y direction, and a rack 18c is formed in a part of the long hole along the Y direction.

  The slider 18 is biased in the + Y direction by a spring (not shown). When the slider 18 is positioned on the most + Y side of the operating range, the clamper arm 12 is maintained in a posture inclined with respect to the horizontal plane by the engagement of the cam pin 12d and the cam portion 18b. As a result, a gap is secured between the lower clamper 14 held at the rotating tip of the clamper arm 12 and the optical disc 200 being conveyed. On the other hand, when the slider 18 is positioned on the most −Y side of the moving range, the clamper arm 12 is maintained in a posture parallel to the horizontal plane by the engagement of the cam pin 12d and the cam portion 18b. In this state, the clamper 13 and the lower clamper 14 mounted on the clamper arm 12 press the optical disc 200 onto a turntable 52 described later by a magnet (not shown) held between them.

  As shown in FIG. 7, a slider trigger 19 which is a long member in the Y direction is attached to the slider 18 so as to be able to reciprocate a predetermined distance (for example, about 4 mm) in the Y direction. The slider trigger 19 has a rack 19a that is long in the Y direction on the -Y side. When the slider trigger 19 is at the end of the relative movement range with respect to the slider 18 in the −Y direction, the rack 19 a of the slider trigger 19 has the same phase as the rack 18 c of the slider 18. Further, a protrusion 19b protruding in the + X direction is formed in the vicinity of the + Y direction end of the slider trigger 19 (in the vicinity of the end opposite to the rack 19a). As shown in FIG. 8A, the protrusion 19b is in contact with the side end surface of the L-shaped bent portion 8d formed in the disk selector 8. Similarly, as shown in FIG. 8B, a spring 104 is stretched between a hook portion 19 c formed in the vicinity of the projection portion 19 b of the slide trigger 19 and a hook portion 8 e formed in the disk selector 8. The trigger 19 and the disk selector 8 are configured to be able to move integrally in a predetermined distance (for example, about 4 mm) in the Y direction. In addition, the springs 101-104 are abbreviate | omitted as needed in other drawings.

  The initial position of the slider trigger 19 is determined by the initial position of the disk selector 8. This initial position is the position on the most + Y side in a moving range of about 4 mm in which the slider trigger 19 can move relative to the slider 18. Therefore, the slider trigger 19 cannot move in the + Y direction from the initial position. On the other hand, the slider trigger 19 can move in the −Y direction from the initial position. When the slider trigger 19 moves about 4 mm integrally with the disk selector 8, the slider trigger 19 moves about 15 mm integrally with the slider 18 thereafter.

<Configuration of drive mechanism>
Next, the configuration of the drive mechanism will be described. As shown in FIG. 6, in the main chassis 11, a motor base 25 equipped with a drive mechanism is attached in the vicinity of the roller gear 24. A motor 26 that is a drive source and a gear train are attached to the motor base 25. A worm gear 27 is integrally attached to the rotating shaft of the motor 26. The worm gear 27 is engaged with a first gear 28 attached to a rotation shaft (provided integrally with the motor base 25) parallel to the rotation shaft of the transport roller 23. The first gear 28 has a helical gear and a spur gear in its axial direction, and the helical gear portion is engaged with the worm gear 26. On the other hand, the spur gear portion of the first gear 26 is engaged with the large gear portion of the second gear 29 attached to the rotation shaft parallel to the rotation shaft of the first gear 28.

  The second gear 29 is configured to have a small gear portion and a large gear portion in the axial direction thereof, and each includes a spur gear. The small gear portion of the second gear 29 engages with the rack 18c of the slider 18 and the rack 19a of the slider trigger 19 when they are within a predetermined movement range. The large gear portion of the second gear 29 is always engaged with the spur gear portion of the first gear 28, and is also engaged with the roller gear 24 when the roller gear 24 is within a predetermined movement range. In other words, when the transport roller 23 transports the optical disk 200, the large gear portion of the second gear 29 and the roller gear 24 are engaged. However, when the transport of the optical disk 200 is completed and the operation shifts to the clamping operation, the roller Since the arm 21 is urged and rotated by the inclined surface 18 a of the slider 18, the engagement between the large gear portion of the second gear 29 and the roller gear 24 is released.

<Configuration of traverse unit>
Next, the configuration of the traverse unit 51 including the optical pickup 53 that records a signal on the optical disc 200 or reproduces the signal of the optical disc 200 will be described with reference to FIGS. 6 and 7. The traverse unit 51 is attached to the main chassis 11 with screws. In the traverse unit 51, a turntable 52 for placing and rotating the optical disk 200, a spindle motor 53 for rotationally driving the turntable 52, and a signal recorded on the optical disk 200 using a laser, or a signal of the optical disk 200 Is held. The optical pickup 53 is moved in the radial direction of the optical disc 200 by the optical pickup driving mechanism 51a.

  A convex portion 52 a having a tapered surface for placing the central hole of the optical disc 200 coaxially with the turntable 52 is formed at the central portion of the turntable 52. A suction plate (not shown) for generating a suction force with a magnet (not shown) held by the upper clamper 13 and the lower clamper 14 is disposed at the tip of the convex portion 52a. When the upper clamper 13 and the lower clamper 14 come close to the turntable 52, the optical disk 200 is pressed and held between the lower clamper 15 and the turntable 52 by this suction force.

<Configuration for optical disc detection>
Next, a configuration for detecting insertion and ejection of the optical disc 200 will be described with reference to FIGS. A photodiode 31a and a phototransistor 31b constituting the disk insertion detecting means 31 are arranged so as to face the lower surface (the surface on the −Z side) of the disk guide 20 and in the vicinity of the −Y side of the transport roller 23. ing. The photodiode 31a and the phototransistor 31b are arranged at regular intervals in the X direction, and the prism 33 reflects the light emitted from the photodiode 31a to the disk guide 20 and emits it toward the phototransistor 31b. Is attached. In a state where the optical disk 200 is not inserted to the position of the transport roller 23, the light emitted from the photodiode 31a is reflected by the prism 33 and enters the phototransistor 31b. On the other hand, in a state where the optical disc 200 is inserted to the position of the transport roller 23, the light emitted from the photodiode 31a is blocked by the optical disc 200 and therefore does not enter the phototransistor 31b. Thereby, it is possible to detect the presence or absence of the optical disc 200 in the section from the insertion port to the transport roller 23.

  Further, a photodiode 32a and a phototransistor 32b constituting the disc ejection detection means 32 are arranged adjacent to the + Y side of the disc insertion detection means 31. The photodiode 32a and the phototransistor 32b are arranged in the vicinity of the + Y side with respect to the transport roller 23 with a certain interval in the X direction. The disk guide 20 is provided with a prism 34 that reflects the light emitted from the photodiode 32a and emits the light toward the phototransistor 32b. When the optical disk 200 is ejected, the light emitted from the photodiode 32a is blocked by the optical disk 200 until the end in the + Y direction of the optical disk 200 reaches the transport roller 23, and therefore does not enter the phototransistor 32b. In contrast, when the end in the + Y direction of the ejected optical disk 200 passes over the transport roller 23, the light emitted from the photodiode 32a is reflected by the prism 34 and enters the phototransistor 32b. Accordingly, it is possible to detect a state immediately before the optical disc 200 is completely ejected by the transport roller 23 (and a state in which the optical disc 200 is held between the transport roller 23 and the disc guide 20).

  The disk insertion detection means 31 and the disk ejection detection means 32 described above are attached to a common substrate 30 disposed below the roller arm 21 (−Z direction). The roller arm 21 is provided with an opening at a position that does not block the optical paths of the disk insertion detection means 31 and the disk ejection detection means 32.

<Optical disc storage operation by disc loading device>
In the disk loading apparatus configured as described above, an operation until a large-diameter optical disk 200 having a diameter of 12 cm is mounted on the turntable 52, a signal is recorded on the optical disk 200, or a signal of the optical disk 200 is reproduced. This will be described with reference to FIGS. 8A to 12B.

  8A and 8B are a perspective view and a plan view showing a state immediately after the start of the storing operation of the optical disc 200. FIG. When the user inserts the optical disk 200 into the disk entrance / exit SL and the insertion of the optical disk 200 is detected by the disk insertion detection means 31 (FIGS. 6 and 7), the control unit (not shown) drives the motor 26 and rotates in a certain direction. Accordingly, the worm gear 27, the first gear 28, and the second gear 29 are always rotated. At this time, the roller gear 24 is engaged with the large gear portion of the second gear 29, and the conveying roller 23 rotates together with the shaft 60. As a result, the optical disk 200 is transported in the + Y direction while being pressed and held between the transport roller 23 and the disk guide 20.

  9A and 9B are a perspective view and a plan view showing a state in which the optical disc 200 is inserted to a position where the outer edge of the optical disc 200 comes into contact with a pair of contact pins 15b (FIG. 3) of the disc stopper 15. When the outer edge of the optical disk 200 conveyed in the + Y direction comes into contact with the contact pin 8a of the disk selector 8, the contact pin 8a is urged in the −X direction by the outer edge of the optical disk 200. Rotates clockwise around the boss 8c as viewed from above. As a result, the engagement pin 8b of the disk selector 8 comes out of the first groove 16b (FIG. 5) of the stopper arm 16, and the engagement between the engagement pin 8b and the first groove 16b is released. As a result, the stopper arm 16 can be rotated counterclockwise when viewed from above, and the disk stopper 15 can be moved in the + Y direction.

  10A and 10B are a perspective view and a plan view showing a state where the engaging pin 8b of the disk selector 8 is engaged with the second groove 16c of the stopper arm 16. FIG. When the motor 26 continues to rotate and the optical disc 200 is further conveyed in the + Y direction and is urged by the optical disc 200 to move the disc stopper 15 in the + Y direction, the disc stopper is engaged by the engagement between the boss portion 15c and the engaging portion 16a. 15, the stopper arm 16 rotates counterclockwise when viewed from above, and the engagement pin 8 b of the disk selector 8 is connected to the second groove 16 c of the stopper arm 16 as shown in FIGS. 10A and 10B. Engage.

  FIGS. 11A and 11B are a perspective view and a plan view showing a state in which the slider trigger 19 moves in the −Y direction together with the disk selector 8 and starts moving integrally with the slider 18. When the optical disk 200 is slightly conveyed in the + Y direction from the state in which the engagement pin 8b of the disk selector 8 is engaged with the second groove 16c of the stopper arm 16, the rotation of the stopper arm 16 causes the rotation of the disk selector 8 to be −. It is converted into a straight movement in the Y direction (by moving the boss 8c in the long hole portion 9c shown in FIG. 3). The disk selector 8 and the slider trigger 19 move together by the action of the spring 104 (FIG. 8B), and move about 4 mm in the −Y direction. When this operation is completed, the disk selector 8 has reached the end of the movement range in the −Y direction, and therefore the disk stopper 15 and the stopper arm 16 cannot operate any more. The optical disc 200 is stopped at a position slightly beyond the turntable 52 in the + Y direction. In this state, the rack 19 a of the slider trigger 19 is engaged with the small gear portion of the second gear 29. Further, since the slider trigger 19 has reached the end in the −Y direction of the range (4 mm) that can move relative to the slider 18, the slider trigger 19 and the slider 18 integrally move in the −Y direction thereafter. Immediately after the movement starts, the rack 18 c of the slider 18 (the same phase as the rack 19 a of the slider trigger 19) is also engaged with the small gear portion of the second gear 29.

  12A and 12B are a perspective view and a plan view showing a state in which the slider 18 and the slider trigger 19 have moved to the end in the -Y direction. As the motor 26 continues to rotate, the slider 18 and the slider trigger 19 integrally move about 15 mm in the −Y direction due to the engagement between the racks 18 c and 19 a and the small gear portion of the second gear 29. At this time, the inclined surface 18a of the slider 18 abuts on the abutting pin 21b of the roller arm 21 and urges in the −Z direction, so that the roller arm 21 rotates around the support pin 21a and the conveying roller 23 moves to −Z. Move in the direction. Thereby, the pressure-bonding holding of the optical disc 200 by the transport roller 23 is released, and the engagement between the roller gear 24 and the large gear portion of the second gear 29 is also released.

  Further, the engagement between the cam pin 12d of the clamper arm 12 and the cam portion 18b of the slider 18 causes the clamper arm 12 to swing about the rotation shaft 9a (FIG. 3), so that the clamper arm 12 is in a horizontal plane (XY plane). It becomes a parallel posture. As the transport roller 23 moves (lowers) in the −Z direction, the optical disc 200 also descends, is guided by the tapered surface of the convex portion 52a of the turntable 52, and slightly moves in the −Y direction. Is held between the lower clamper 14 and the turntable 52 which are mounted on the press. At this time, the slight movement of the optical disc 200 in the −Y direction secures a gap between the optical disc 200 and the contact pin 15 b of the disc stopper 15, and the optical disc 200 can rotate without contacting the disc stopper 15. become.

  Due to the movement of the slider 18 and the slider trigger 19 in the −Y direction described above, the spring 104 stretched between the slider trigger 19 and the disk selector 8 is largely displaced, and the spring force (biasing force) is the spring 102 and the spring. It greatly exceeds the spring force of 103. As a result, the disk selector 8 is biased in the −Y direction, and the disk stopper 15 is biased in the + Y direction via the stopper arm 16. In other words, the disk stopper 15, the stopper arm 16, and the disk selector 8 are prevented from returning to their initial positions. Therefore, the outer edge of the optical disc 200 and the contact pin 15b of the disc stopper 15 are prevented from coming into contact with each other due to vibration or the like.

  When the slider 18 reaches the end of the moving range in the −Y direction, an end detection unit (not shown) detects this, and a control unit (not shown) stops the rotation of the motor 26 and the optical disc 200 is stored in the disc device 1. The operation is complete. After that, the optical disk 200 is rotated by the spindle motor 53, and the signal recording operation or reproducing operation is started by the optical pickup 54.

<Discharging operation of optical disc by disc device>
Next, the operation of ejecting the optical disk 200 to the outside of the disk device will be described with reference to FIGS. 13A to 15B. 13A and 13B are a perspective view and a plan view showing a state in which the motor 26 rotates in the opposite direction to the storing operation of the optical disc 200 and the slider 18 and the slider trigger 19 are integrally driven by about 15 mm in the + Y direction. is there. 13A and 13B, the rack 19a of the slider trigger 19 is engaged with the small gear portion of the second gear 29, but the rack 18c of the slider 18 and the small gear portion of the second gear 29 are engaged. Is released, and the return of the slider 18 to the initial position is completed. Further, when the slider 18 returns to the initial position, the clamper arm 12 rotates about the rotation shaft 9a (FIG. 3) due to the engagement between the cam portion 18b and the cam pin 12d of the clamper arm 12, and becomes horizontal. It becomes a posture inclined with respect to it. As a result, the lower clamper 14 moves in the + Z direction, and the pressure bonding of the optical disc 200 by the lower clamper 14 and the turntable 52 is released. In addition, since the depression of the pin 21d of the roller arm 21 by the inclined surface 18a of the slider 18 is released, the roller arm 21 rotates upward about the pin 21a, and the transport roller 23 moves in the + Z direction to move the optical disc 200. It is lifted from the turntable 52 and held in pressure contact with the disk guide 20. Further, the roller gear 24 of the shaft 60 of the transport roller 23 is engaged with the large gear portion of the second gear 29. From this time, the conveyance of the optical disk 200 to the outside of the disk device 1 is started.

  14A and 14B are a perspective view and a plan view showing a state in which the slider trigger 19 and the disk selector 8 have returned to their initial positions. When the motor 26 continues to rotate, the optical disk 200 is transported in the −Y direction by the rotation of the transport roller 23. On the other hand, the slider trigger 19 and the disk selector 8 are integrally driven in the + Y direction by about 4 mm by the engagement between the rack 19 a and the small gear portion of the second gear 29. At this point, the engagement between the small gear portion of the second gear 29 and the rack 19a of the slider trigger 19 is released, and the return of the slider trigger 19 to the initial position is completed.

  When the motor 26 continues to rotate, the outer edge of the optical disk 200 contacts the contact pin 8a of the disk selector 8 and urges in the -X direction, and the disk selector 8 rotates in the clockwise direction as viewed from above with the boss 8c as the center. To turn. By the rotation of the disk selector 8, the engagement between the engaging pin 8b of the disk selector 8 and the second groove 16c of the stopper arm 16 is released. However, the disk stopper 15 and the stopper arm 16 are urged toward the initial position by the spring 102, but at this time, they do not return to the initial position as will be described later.

  15A and 15B are a perspective view and a plan view showing a state in which the rotation restriction of the stopper arm 16 by the disk selector 8 is released and the disk stopper 15 can be returned to the initial position. When the optical disk 200 further urges the contact pin 8a of the disk selector 8 in the -X direction and the disk selector 8 further rotates in the clockwise direction when viewed from above, the engagement pin 8b of the disk selector 8 is moved to the stopper arm 16. Reaches the boundary B (vertex portion) between the first slope 16d and the second slope 16e. When the pin 8b of the disk selector 8 exceeds the boundary B and reaches the second inclined surface 16d side, the disk stopper 15 and the stopper arm 16 are in a state where they can be returned to the initial positions.

  In the present embodiment, when the optical disc 200 is ejected to the vicinity of the position where the outer edge of the optical disc 200 starts contact with the contact pin 15b of the disc stopper 15 (or when it is further ejected in the + Y direction). Thus, the engaging pin 8b of the disk selector 8 is configured to reach the boundary B between the first inclined surface 16d and the second inclined surface 16e. In other words, as shown in FIGS. 15A and 15B, in the state immediately before the disk stopper 15 and the stopper arm 16 return to the initial positions, the outer edge of the optical disk 200 is in contact with the contact pin 15b of the disk stopper 15 when inserted. It is transported to the vicinity of the position where the contact starts. Therefore, even if the disk stopper 15 and the stopper arm 16 return to the initial positions from this state, the disk stopper 15 does not contact the optical disk 200. Therefore, the contact pin 15 b of the disk stopper 15 does not collide with the outer edge of the optical disk 200 during the operation of ejecting the optical disk 200 to the outside of the disk device 1.

  Here, an operation of returning the disk stopper 15 and the stopper arm 16 to the initial positions in the disk loading apparatus as a comparative example with respect to the present embodiment will be described. FIG. 16 is a plan view showing a stopper arm 216 used in a disk loading apparatus as a comparative example. The disc loading device of the comparative example has the same configuration as the disc loading device of the present embodiment except for the configuration of the stopper arm 216. In the stopper arm 216, a surface 216d between the first groove portion 16b and the second groove portion 16c forms an arc R concentric with the rotation center C of the stopper arm 216 (center of the hole portion 16g). In this case, when the engagement between the engagement pin 8b of the disk selector 8 and the second groove 16c of the stopper arm 16 is released, the disk stopper 15 and the stopper arm 16 can be returned to their initial positions, and the spring 102 ( The initial position is restored by the spring force of FIG. On the other hand, at this time, the optical disk 200 is not transported to the vicinity of the position where the outer edge of the optical disk 200 starts contact with the contact pin 15b of the disk stopper 15 at the time of insertion. As a result, the contact pin 15b of the disk stopper 15 collides with the outer edge of the optical disk 200 during the operation of ejecting the optical disk 200 out of the disk device 1.

  On the other hand, in the present embodiment, as described with reference to FIG. 5, the first groove 16 b to the second groove 16 c between the first groove 16 b and the second groove 16 c of the stopper arm 16. A first slope 16d extending in a direction in which the distance from the rotation center C of the stopper arm 16 (the center of the hole 16g) decreases toward the groove 16c, and a first slope 16d extending from the terminal end of the first slope 16d. A second inclined surface 16e extending in a direction in which the distance from the rotation center increases is formed continuously in a V shape over the two groove portions 16c. Further, the urging force of the spring 103 (FIG. 8A, etc.) that urges the disk selector 8 counterclockwise as viewed from above is applied by the spring 102 (FIG. 8A, etc.) that urges the stopper arm 16 toward the initial position. It is set stronger than the power. Therefore, even if the engaging pin 8b of the disk selector 8 comes out of the second groove portion 16b, the disk stopper 15 is until the engaging pin 8b passes the boundary B between the first inclined surface 16d and the second inclined surface 16e. And the stopper arm 16 cannot be returned to the initial position. Only when the engagement pin 8b of the disk selector 8 passes the boundary B between the first inclined surface 16d and the first inclined surface 16e, the disk stopper 15 and the stopper arm 16 can be returned to the initial positions, and the spring 102 is attached. Return to the initial position by force. Therefore, the stopper arm 16 and the disk stopper 15 do not collide with the outer extension of the disk 200. As the disk stopper 15 and the stopper arm 16 return to the initial positions, the engagement pin 8b of the disk selector 8 engages with the first groove 16b of the stopper arm 16.

  The return operation of the disk stopper 15 and the stopper arm 16 to the initial position is completed when the contact surface 15e of the disk stopper 15 contacts the cushion plate 17 on the clamper arm 12. The cushion plate 17 is made of resin, and the collision sound with the disk stopper 15 is suppressed to a low level.

  After the return operation of the disk stopper 15 and the stopper arm 16 to the initial position is completed, the optical disk 200 is further transported in the −Y direction, and when the ejection of the optical disk 200 is detected by the disk ejection detection means 32, the controller The rotation of 26 is stopped, thereby completing the operation of ejecting the optical disk. This state is almost the same as the state of FIG.

  The storage operation and the discharge operation of the large-diameter optical disc 200 having a diameter of 12 cm have been described above. However, the storage operation and the discharge operation are performed in a similar manner in the case of the small-diameter optical disc 200 having a diameter of 8 cm. However, when the small-diameter optical disk 200 is stored, the outer edge of the optical disk 200 does not contact the contact pin 8a of the disk selector 8. Therefore, the disk selector 8 does not rotate and the engagement pin 8b of the disk selector 8 does not move to the arm stopper. The state engaged with the 16 1st groove parts 16b is maintained. In this state, when the inserted optical disk 200 comes into contact with the disk stopper 15, the disk selector 8 moves in the + Y direction (by moving the boss 8c in the long hole portion 9c shown in FIG. 3). Thus, the transition to the clamping operation of the optical disc 200 is performed via the slider 18 and the slider trigger 19.

  As described above, in the present embodiment, when the large-diameter optical disc 200 is ejected, when the optical disc 200 is ejected at least to the vicinity of the position where the outer edge starts to contact the disc stopper 15 during insertion. Since the stopper arm 16 and the disk stopper 15 can be returned to the initial positions, the stopper arm 16 and the disk stopper 15 do not collide with the outer extension of the disk 200. Thereby, it is possible to prevent the disk stopper 15 from colliding with the outer edge of the optical disk 200 during the ejection operation, and it is possible to prevent occurrence of a collision mark on the outer edge of the optical disk or the disk stopper 15.

  In addition, even if the storing operation and the discharging operation of the optical disc 200 are repeated, no collision mark is generated on the disc stopper 15 side, so that the stop position of the optical disc defined by the disc stopper 15 is accurately maintained for a long period. Can do. Therefore, the life of the disk loading device and the optical disk device can be extended.

  In particular, the distance from the rotation center of the stopper arm 16 decreases from the first groove portion 16b toward the second groove portion 16c between the first groove portion 16b and the second groove portion 16c of the stopper arm 16. A first slope 16d extending in the direction, and a second slope 16e extending in a direction in which the distance from the rotation center increases from the end of the first slope 16d toward the second groove 16c. Is formed continuously in a V shape, and the engaging pin 8b of the disk selector 8 exceeds the boundary B between the first inclined surface 16d and the second inclined surface 16e of the stopper arm 16, so that the stopper arm 16 and the disk stopper Thus, it is possible to prevent the optical disc 200 and the disc stopper 15 from colliding with a simple configuration.

  Further, during the storing operation of the optical disc 200, the disc selector 8 is brought into contact with the outer edge of the optical disc 200 and turned to release the restriction of the rotation of the stopper arm 16, and the disc stopper 15 comes into contact with the outer edge of the optical disc 200. Since the stopper arm 16 is rotated by the movement, and the rotation of the stopper arm 16 is regulated by the disk selector 8 at the rotated position, the stopper arm 16 is configured according to the diameter of the optical disk 200 with a simple configuration. The position of the disk stopper 15 can be switched.

  Further, when the engaging pin 8b of the disc selector 8 is engaged with the first groove portion 16b or the second groove portion 16c of the stopper arm 16, the stopper arm 16 is slightly rotated, so that the disc selector 8 is slightly Therefore, it is possible to move to a clamping operation for moving the optical disk 200 straightly in the Y direction and holding the optical disk 200 with the turntable 52. Therefore, it is possible to realize a configuration in which the optical disk 200 is conveyed and clamped by a common driving source. Can do.

Embodiment 2. FIG.
FIG. 17 is a plan view showing the stopper arm 116 of the disk loading device according to the second embodiment of the present invention. In the stopper arm 116 of the disk loading apparatus according to the second embodiment, the first arm 16b and the second groove 116c are positioned between the first groove 16b and the second groove 116c with respect to the arc R coaxial with the rotation center C of the stopper arm 116. A slope 16d extending in a direction in which the radius decreases from the groove 16b toward the second groove 116c is formed. Further, the depth of the second groove 116c is set such that the outer edge of the optical disc 200 is ejected at least to the vicinity of the position where the outer edge of the optical disc 200 starts contact with the contact pin 15b of the disc stopper 15 at the time of insertion. The depth is set such that the engagement between the groove 116c and the engagement pin 8b is released.

  Therefore, when the engagement between the engagement pin 8b of the disk selector 8 and the first groove portion 16b is released, the outer edge of the optical disk 200 is already in contact with the contact pin 15b of the disk stopper 15 when inserted. It is transported to the vicinity of the starting position. Therefore, even if the disk stopper 15 and the stopper arm 116 return to the initial positions, they do not collide with the outer edge of the optical disk 200. That is, it is possible to prevent the contact pin 15 b of the disk stopper 15 from colliding with the outer edge of the optical disk 200 during the operation of ejecting the optical disk 200 out of the disk device 1. Other configurations and operations are as described in the first embodiment. Further, the storing operation and the discharging operation of the small-diameter optical disc 200 are also as described in the first embodiment.

  According to the second embodiment, as in the first embodiment, when the optical disk 200 is ejected to the vicinity of the position where the outer edge starts to contact the disk stopper 15 during insertion, the stopper arm 16 and the disk Since the stopper 15 can be returned to the initial position, the stopper arm 16 and the disk stopper 15 can be prevented from colliding with the extension of the disk 200. As a result, it is possible to prevent the occurrence of collision marks at the outer edge of the optical disk or at the disk stopper 15.

  The stopper arm 16 described in the first and second embodiments has a common effect of preventing the outer edge of the optical disk 200 and the disk stopper 15 from colliding with each other, but the position immediately before the disk stopper 15 returns to the initial position. Are different from each other. That is, when the arm stopper 16 according to the first embodiment is used, the disk stopper 15 and the stopper arm 16 are somewhat distant from the respective positions at the time of recording / reproducing in a state immediately before the disk stopper 15 and the stopper arm 16 are returned to the initial positions. (In other words, the engaging pin 8b of the disk selector 8 has moved from the second groove 16c of the stopper arm 16 to the boundary B). Therefore, since the distance to the initial position is small and the spring force of the spring 102 is small, the collision speed between the disc stopper 15 and the cushion plate 17 in the return operation can be reduced. Therefore, the use of the stopper arm 16 of the first embodiment can suppress the collision sound generated during the return operation.

  In the first and second embodiments described above, the case where the optical discs 200 having the diameters of 8 cm and 12 cm are used has been described, but it goes without saying that optical discs having other diameters may be used. Further, as the optical disc 200, for example, various optical discs can be used in addition to a compact disc and a digital versatile disc.

  1 disk device, 8 disk selector, 8a contact pin, 8b engagement pin, 8c boss, 12 clamper arm, 15 disk stopper, 15b contact pin, 16 stopper arm, 16b first groove, 16c second groove, 16d first slope, 16e second slope, 18 slider, 19 slider trigger, 20 disc guide, 21 roller arm, 23 transport roller, 26 motor, 53 turntable, 101, 102, 103, 104 spring, 200 optical disc.

Claims (6)

A transport mechanism capable of transporting multiple types of optical disks of different diameters in the insertion / ejection direction with respect to the disk device;
A disc stopper that abuts on the outer edge of the optical disc to be transported and is movable in the insertion / ejection direction;
A rotatable stopper arm for restricting the disk stopper to a predetermined position according to the diameter of the optical disk;
A rotatable disk selector that abuts on the outer edge of the optical disk to be conveyed and regulates the rotation of the stopper arm at a position corresponding to the diameter of the optical disk;
A biasing member that biases the disk stopper or the stopper arm toward the initial position,
When the optical disc is inserted, the disc selector is abutted against the outer edge of the optical disc and pivoted to release the rotation restriction of the stopper arm, and the disc stopper is brought into contact with the outer edge of the optical disc and moved. By doing so, the stopper arm rotates, and the rotation restriction by the disk selector is made at that position,
When the optical disc is ejected, the optical disc is located on the ejection direction side from the position where the outer edge of the optical disc starts to abut against the disc stopper when inserted, and the outer edge of the optical disc and the disc stopper do not abut When the disc selector is ejected at least, the disc selector releases the restriction of rotation of the stopper arm so that the stopper arm and the disc stopper can be returned to their initial positions. The stopper arm has a first groove portion for positioning the small-diameter optical disc and a second groove portion for positioning the large-diameter optical disc,
In a direction in which the distance from the rotation center of the stopper arm decreases between the first groove portion and the second groove portion of the stopper arm from the first groove portion toward the second groove portion. A first slope extending, and a second slope extending in a direction in which the distance from the rotation center of the stopper arm increases from the end of the first slope toward the second groove. Formed continuously,
The disc selector has an engaging portion that selectively engages with the first groove portion or the second groove portion,
When the large-diameter optical disc is ejected, the optical disc is ejected from the position where the outer edge of the optical disc starts to contact the disc stopper when inserted, and the outer edge of the optical disc and the disc stopper contact each other. When the disc selector is ejected at least to a position where it does not contact, the engaging portion of the disc selector reaches the boundary between the first slope and the second slope, thereby restricting the rotation of the stopper arm by the disc selector. 2. The disk loading device according to claim 1, wherein is released, and the stopper arm and the disk stopper can be returned to their initial positions. The stopper arm has a first groove portion for positioning the small-diameter optical disc and a second groove portion for positioning the large-diameter optical disc,
The disc selector has an engaging portion that selectively engages with the first groove portion or the second groove portion,
When the large-diameter optical disc is ejected, the optical disc is ejected from the position where the outer edge of the optical disc starts to contact the disc stopper when inserted, and the outer edge of the optical disc and the disc stopper contact each other. When at least the ejected position reaches the non-contact position , the engagement between the second groove portion and the engaging portion is released, whereby the rotation restriction of the stopper arm by the disc selector is released, and the stopper arm and The disk loading device according to claim 1, wherein the disk stopper can be returned to an initial position. The disc selector can move straight in the insertion / ejection direction,
2. The disk selector moves straight in the insertion / ejection direction by rotating the stopper arm by a predetermined amount in a state where the disk selector restricts the rotation of the stopper arm. 4. The disk loading device according to any one of items 3 to 3.   5. The disk loading apparatus according to claim 4, wherein an operation of a clamper mechanism that holds the optical disk with a turntable is started by the linear movement of the disk selector in the insertion / ejection direction.   A disk device comprising the disk loading device according to any one of claims 1 to 5.

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