JP5035274B2 - Disc changer device - Google Patents

Description

  The present invention stores a plurality of optical discs (hereinafter referred to as discs) as information recording media such as CDs (compact discs) and DVDs (digital versatile discs), and discs selected from the plurality of discs. The present invention relates to a disk changer device that transports and records and / or reproduces information on a selected disk.

  2. Description of the Related Art Conventionally, as this type of disk changer apparatus, there is known an apparatus that uses a plurality of trays to store a disk in a casing that is an outer shell of the apparatus and to transport the disk. In this disk changer apparatus, the plurality of trays are stacked in the apparatus thickness direction perpendicular to the main surface of the disk, and are configured to be movable in the apparatus depth direction parallel to the main surface of the disk. The disk changer device includes a standby position in which a plurality of trays are stored in the housing, a disk recording / playback position where information can be recorded on or reproduced from a disk placed on the selected tray, and a tray. The tray can be transported in the horizontal direction between the disc replacement position that allows the disc to be placed on the tray and to be taken out of the tray.

  When the tray is transported between the recording / playback position and the standby position, the recording / playback transitions between a state in which the disc is placed on the tray and a state in which the disc is clamped on the turntable so that recording / playback is possible. Two types of operations are performed: a lifting and lowering operation of the apparatus and a transporting operation for driving the tray in the horizontal direction. For this reason, when the tray is transported between the recording / reproducing position and the standby position, a switching mechanism for continuously performing two kinds of operations is necessary.

As an example of a method for constructing this drive switching mechanism, a tray drive pin is provided on a slide plate which is a part for raising and lowering a recording / reproducing apparatus, and the tray drive pin engages with a guide groove on the back surface of the tray so There is a way to communicate. The above-described method is used for many products as a known technique because of its ease of construction.
JP 2008-047380 A

  However, in the drive switching configuration as described above, when the tray drive pin engaged with the guide groove on the back surface of the tray is removed, it cannot be returned to the normal position, that is, the apparatus is broken. There is a problem that it ends up.

  Therefore, an object of the present invention is to solve the above problem, and even if the tray drive pin that engages with the guide groove on the back surface of the tray is detached from the guide groove, the drive force in the apparatus is normal. It is an object of the present invention to provide a disk changer device that can return to a state.

  In order to achieve the above object, the present invention is configured as follows.

According to the first aspect of the present invention, a standby position for storing a plurality of trays, and a disk recording / reproducing position capable of recording or reproducing with respect to a disk placed on a tray selected from the plurality of trays, A first motor that generates a driving force for transporting the trays between them, and a tray drive gear unit capable of individually transporting the respective trays in a state in which the trays can be transported simultaneously, the standby position, and the trays A disk changer device having a second motor for generating a driving force for transporting the tray to and from a disk replacement position where the upper disk can be replaced;
The tray has a rack portion that receives the driving force of the first motor on a side portion, a guide groove on the back surface, and the disk changer device includes a tray driving pin that engages with the guide groove. A drive switching component that receives the driving force of the second motor, and a drive lever that rotates by the driving force of the second motor,
When the drive lever is disposed at a predetermined position by the second motor, a disc changer device is provided that abuts against the drive switching component and applies a drive force in a certain direction.

According to the second aspect of the present invention, the cam gear that is rotationally driven by the driving force of the second motor, the slider arm that engages with the cam gear and rotates in conjunction with the rotation of the previous cam gear, and the drive switching A trigger link lever supported rotatably at a position where it can contact the part,
The trigger link lever has a cam surface, the slider arm has a drive pin that contacts the cam surface, and the drive pin pushes the cam surface by the rotation of the slider arm, and the trigger link The disc changer device according to claim 1, wherein a lever is rotated so as to apply a driving force in a certain direction by contacting the drive switching component.

According to the third aspect of the present invention, the slide plate that receives the driving force of the first motor, the load plate that engages with the slide plate and has a movable range other than the driving direction of the slide plate, and the load plate A load lever having the tray driving pin that rotates around a pin provided on the tray and engages with the cam groove on the back surface of the tray;
3. The disk changer device according to claim 1, wherein the drive switching part is constituted by the three parts, and the tray driving pin can operate in a planar manner.

  According to the disk changer device of the present invention, even when the tray drive pin is detached from the cam groove on the back surface of the tray and the corresponding component is disconnected from the drive of the first motor, the drive of the second motor is performed. The urging force can be applied to the corresponding part. As a result, even if the tray driving pin is disengaged from the cam groove on the back surface of the tray, the corresponding component can be returned to the drivable region again by the urging force, so that the disk changer device can return to the normal state.

  Before continuing the description of the present invention, the same parts are denoted by the same reference numerals in the accompanying drawings.

  The best mode for carrying out the present invention will be described below with reference to the drawings.

<Embodiment>
A disk changer device according to an embodiment of the present invention will be described. FIG. 1 is a perspective view of a disk changer device according to an embodiment of the present invention. FIG. 2 is a plan view showing a state in which the tray is located at the disk recording / playback position, the standby position, and the disk replacement position in the disk changer apparatus according to the embodiment of the present invention. 3 is an exploded perspective view of the disk changer device, FIG. 4 is a partially enlarged view of the disk recording / reproducing section of FIG. 3, and FIG. 5 is a partially enlarged view of the standby section of FIG. FIG. 6 is a plan view showing a state in which the upper cover and the tray are removed in the disk changer device according to the embodiment of the present invention. Here, for the sake of convenience, the upper side of FIG. 1 will be described as the upper side of the disk changer device 1 and the lower side of FIG. 1 will be described as the lower side of the disk changer device 1, but the present invention is not limited to this. Absent. For example, the disk changer device 1 may be disposed at an angle of 90 °.

  1 and 3, the disk changer device 1 includes a device main body (also referred to as a mechanical base) 2 that supports each component, and an upper cover 3 that covers the upper side of the device main body 2. The apparatus main body 2 and the upper cover 3 constitute a casing 4 that is an outer shell of the apparatus. Further, the disk changer device 1 has a plurality of (here, five as an example) trays 5 (5a to 5b) on which the large diameter disk Da or the small diameter disk Db can be placed on the large diameter step portion 5Ta or the small diameter step portion 5Tb, respectively. It has. Hereinafter, the large-diameter and small-diameter disks 6a and 6b are collectively referred to as a disk 6.

  The plurality of trays 5 are stacked in the apparatus thickness direction Z that is substantially perpendicular to the main surface of the disk 6, and can be moved in the apparatus depth direction (also referred to as a tray conveyance direction) X parallel to the main surface of the disk 6. It is configured. As shown in FIG. 2, the disk changer device 1 includes a standby position A <b> 2 for storing a plurality of trays 5 in a housing 4, and a disk placed on one tray selected from the plurality of trays 5. A disc recording / reproducing position (hereinafter referred to as a recording / reproducing position) A1 at which information signals can be recorded and / or reproduced with respect to 6 Is configured to be able to transport the tray 5 in the apparatus depth direction X with a disk exchange position (hereinafter referred to as an exchange position) A3 protruding outside the housing 4.

  The internal structure of the disc changer device 1 can be roughly divided into two sections: a disc recording / reproducing section (hereinafter referred to as recording / reproducing section) B1 and a standby section B2.

  First, components and operations arranged in the recording / reproducing section B1 will be described with reference to FIGS.

  As shown in FIG. 4, in the recording / reproducing section B1, an example of a traverse unit in which an optical pickup 7 for recording and / or reproducing information signals with respect to the disk 6 and a turntable 8 for rotating the disk 6 are mounted. A traverse base 9 is arranged. The optical pickup 7 includes a pair of guide shafts 9a parallel to each other in the apparatus depth direction X provided in the traverse base 9 in bearing holes 7a and 7a and a bearing groove 7b (see FIG. 7A) provided therein. When 9a is slidably fitted, it is configured to be movable along the guide shafts 9a and 9a. Thereby, the optical pickup 7 is configured to be movable in the radial direction of the disk placed on the turntable 8.

  The traverse base 9 includes a first motor 10 that generates a driving force, and a first traverse gear 11 that engages an input gear 11a with a driving shaft 10a of the first motor 10 so that the driving force of the first motor 10 can be transmitted. And a second traverse gear 12 in which the input gear 12a meshes with the output gear 11b of the first traverse gear 11. As shown in FIGS. 7A and 7B, the output gear 12b of the second traverse gear 12 is disposed so as to be able to mesh with the upper input rack 13c and the lower input rack 13d of the feed rack 13. The feed rack 13 is configured by superposing two substantially plate-like members 13a and 13b having different lengths. An upper input rack 13c is formed on a side surface of the upper plate-like member 13a, and the lower plate-like member 13b A lower input rack 13d is formed on the side surface. The lower plate-shaped member 13b is integrally attached to the optical pickup 7. For this reason, when the first motor 10 is driven forward / reversely in a state where it is engaged with the output gear 11b of the second traverse gear 11 and the lower guide groove 13d, the optical pickup 7 moves in the disk radial direction together with the feed rack 13. It has become. Further, when the output gear 11b of the second traverse gear 11 and the lower input rack 13d are disengaged, the movement of the lower plate member 13b and the optical pickup 7 is stopped. On the other hand, the upper plate member 13a engages with the lower plate member 13b so as to be slidable along the lower plate member 13b. Since the upper input rack 13c is longer than the lower input rack 13d, the output gear 11b of the second traverse gear 11 and the upper input rack even when the lower plate-like member 13b and the optical pickup 7 stop moving as described above. 13c is in a meshed state. Therefore, when the first motor 10 is further driven from this state, the upper plate member 13a slides on the lower plate member 13b and further moves in the disk radial direction (lower left direction in FIG. 7A).

  In the present embodiment, the first and second traverse gears 11 and 12 and the feed rack 13 constitute a pickup moving unit that can move the optical pickup 7 in the disk radial direction.

  In addition, a loading gear 14 </ b> A is disposed on the traverse base 9 so that the input gear 14 a meshes with the input gear 12 a of the second traverse gear 12. The output gear 14b of the loading gear 14A meshes with the relay gear 14B. A hole is provided in the center of the relay gear 14B. As shown in FIG. 8B, a pin 15a provided at one end of the swing arm 15 is fitted in the center hole of the relay gear 14B. The swing arm 15 is attached to the traverse base 9 so as to be able to rotate about the shaft 15b. Further, the swing arm 15 is biased by a torsion spring (not shown) in the direction of rotating counterclockwise in FIGS. 8A and 8B (the direction away from the upper plate member 13a) about the shaft 15b. As shown in FIG. 8A, the swing arm 15 is provided with a guide hole 15c that is bent in an L shape, and an engagement pin 16a provided on the swing lock 16 is engaged with the guide hole 15c. Yes. At the other end of the swing lock 16, an inclined surface 16b that is inclined with respect to the moving direction of the feed rack 13 (disk radial direction) is formed.

  As described above, when the upper plate member 13a is further moved in the disk radial direction (downward in FIGS. 8A and 8B), the swing lock 16 is moved to the upper plate member 13a as shown in FIGS. 9A and 9B. The inclined surface 16b comes into contact with the provided contact pin 13e. At this time, since the upper plate member 13a is guided so as to move in one direction (disk radial direction), the swing lock 16 is pushed by the contact pin 13e and moves. At this time, the movement direction of the swing lock 16 moves along the shape of the guide hole 15c because the engagement pin 16a is engaged with the guide hole 15c. As a result, as shown in FIGS. 10A and 10B, the swing lock 16 moves and is pushed by the swing lock 16, and the swing arm 15 approaches the upper plate member 13a against the biasing force of the torsion spring. At the same time, it moves in the same direction as the movement direction of the upper plate member 13a (downward direction in FIGS. 10A and 10B). By this movement, the relay gear 14B moves like the swing arm 15, the relay gear 14B meshes with the play pinion 18, and the driving force of the first motor 10 is changed to the first and second traverse gears 11, 12, loading. It is transmitted to the play pinion 18 via the gear 13 and the relay gear 14B. The play pinion 18 is rotatably supported at one corner of a substantially rectangular lifting base 19 described later.

  The four corners of the traverse base 9 are provided with holes for attaching a vibration isolating rubber, and a vibration isolating rubber having a through hole at the center is attached to the hole. The center holes of two anti-vibration rubbers close to the turntable of these anti-vibration rubbers are fitted into the seat surface with shaft of the traverse base holding case 17, and the other two anti-vibration rubbers are placed on the seat surface with holes. Positioned by a fixing pin.

  Similarly to the traverse base 9, the traverse holding case 17 is provided with two bosses 17 c and 17 c that protrude in directions away from each other at the ends of a pair of side surfaces facing each other. Further, two bosses 17d, 17d are provided in parallel to each other on the side surface of the traverse holding case 17 on the side close to the turntable 8. The traverse holding case 17 can be rotated about a straight line connecting the projections 17c and 17c by inserting the two bosses 17c and 17c into holding holes (not shown) provided in the elevating base 19. Is held by the lifting base 19. On the other hand, the bosses 17d and 17d of the traverse holding case 17 are slidably engaged with two cam grooves 20a and 20a provided in the traverse slide plate 20, respectively.

  The traverse slide plate 20 is attached to the lifting section 19 on the standby section B2 side so as to be slidable in the apparatus width direction Y and the apparatus width direction Y orthogonal to the apparatus thickness direction Z. The two cam grooves 20a, 20a of the traverse plate 20 have inclined portions that incline downward in the apparatus thickness direction Z as they approach the play pinion 18 in the apparatus width direction Y. When the traverse slide plate 20 slides and moves away from the play pinion 18 in the apparatus width direction Y, the bosses 17c and 17c of the traverse holding case 17 move from the upper side to the lower side in the apparatus thickness direction Z along the cam grooves 20a and 20a. Slide. As a result, the entire traverse holding case 17 rotates downward about the straight line connecting the bosses 17c, 17c. On the contrary, when the traverse slide plate 20 slides in the apparatus width direction Y so as to approach the play pinion 18, the bosses 17c and 17c of the traverse holding case 17 are located below the apparatus thickness direction Z along the cam grooves 20a and 20a. Slide upward from As a result, the entire traverse holding case 17 rotates upward about the straight line connecting the bosses 17c, 17c. The turntable 8 is raised by the upward rotation of the traverse holding case 17, and the disk 6 is sandwiched between the resin clamper 21 disposed above the turntable 8 and the raised turntable 8. Is possible.

  In the present embodiment, the position where the turntable 8 is lifted so that the disk 6 can be clamped with the clamper 21 is referred to as a clamp position. A position where the turntable 8 is lowered so as to be separated from the clamper 21 is referred to as a retreat position.

  The clamper 21 is attached to a substantially rectangular plate-like metal clamp plate 25 using a resin-made fixing plate 23 and a metal back yoke 24 so as to allow slight movement in the apparatus thickness direction Z. Yes. A magnet 22 is disposed between the clamper 21 and the clamp plate 25, and the clamper 21 is biased toward the clamp plate 25 by the magnetic force of the magnet 22. That is, against the magnetic force of the magnet 22, when an external force is applied to the back yoke 24 in the downward direction, the clamper 21 moves slightly downward with respect to the clamp plate 25. When no external force is applied, the clamper 21 is positioned so as to approach the clamp plate 25. By attaching the clamper 21 in this manner, the disc 6 can be prevented from being damaged. Both ends of the clamp plate 25 are bent, and the clamp plate 25 is fixed to the elevating base 19 at the bent portion. Therefore, the clamp plate 25 is configured to be movable up and down integrally with the lifting base 19.

  Two tray stoppers 30 and 30 such as wire springs are attached to the side of the clamp plate 25 on the standby section B2 side. Each of the two tray stoppers 30 and 30 has one end attached to the clamp plate 25 and the other end slidably engaged with an engagement hole (not shown) provided in the upper cover 3. . When the clamp plate 25 is separated from the upper cover 3, each tray stopper 30, 30 slides in the engagement hole of the upper cover 3 and rises so as to increase the inclination angle with respect to the upper surface of the clamp plate 25. On the other hand, when the clamp plate 25 approaches the upper cover 3, each tray stopper 30, 30 slides in the engagement hole of the upper cover 3 and falls so that the inclination angle with respect to the upper surface of the clamp plate 25 becomes small. By attaching the tray stoppers 30 and 30 in this way, it is possible to restrict the tray on the upper stage from the selected tray located at the recording / reproducing position A1 from moving to the recording / reproducing position A1. Specifically, for example, when the selected tray is the third tray 5c, the tray stoppers 30 and 30 abut against the side surface of the first tray 5a, and the clamp plate 25 is the second tray 5b. The first and second trays 5a and 5b can be regulated so as not to move to the recording / reproducing position A1. In this case, the fourth tray 5d and the fifth tray 5e are restricted by the side walls of the elevating base 19 so as not to move to the recording / reproducing position A1.

  Further, as shown in FIGS. 11 and 12, the traverse slide plate 20 has an introduction groove 20b that inclines so as to approach the play pinion 18 in the apparatus width direction Y toward the standby section B2 side in the apparatus depth direction X. Is provided. On the other hand, as shown in FIGS. 7A and 7B, the upper plate-like member 13a of the feed rack 13 can be slidably engaged with the introduction groove 20b at the front end portion on the standby section B2 side in the apparatus depth direction X. A pin 13f is provided. As shown in FIG. 13, when the upper plate member 13a moves further to the standby section B2 side in the apparatus depth direction X than the lower plate member 13b, the pin 13f moves along the introduction groove 20b. At this time, since the moving direction of the upper plate member 13a is fixed in one direction, the pin 13f pushes the side wall of the introduction groove 20b and the traverse slide plate 20 is moved in the apparatus width direction Y as shown in FIG. Slide and move away from the two-on 18. By this sliding movement, the rack 20 c provided at the tip of the traverse slide plate 20 meshes with the play pinion 18. When the driving force of the first motor 10 is transmitted to the play pinion 18 in this state, the play pinion 18 can further slide the traverse slide plate 20 in the apparatus width direction Y (left side in FIG. 13). Become. By this further sliding movement, the bosses 17c, 17c of the traverse holding case 17 slide on the cam grooves 20a, 20a of the traverse slide plate 20, and the traverse holding case 17 rotates downward to move to the retracted position. When the traverse holding case 17 moves to the retracted position, the pin 13f that moves together with the traverse holding case 17 is engaged and locked with a locking claw 19a provided on the lifting base 19, as shown in FIG. . Thereby, the movement of the feed rack 13 in the disk radial direction is restricted.

  In the present embodiment, the first and second traverse gears 11, 12, the feed rack 13, the loading gear 14A, the relay gear 14B, the play pinion 18, and the traverse slide plate 20 A disc clamp unit is configured that can move the traverse base 9 to the retracted position.

  A sub slide plate 26 is attached between the traverse slide plate 20 and the side surface of the elevating base 19 on the standby section B2 side so as to be slidable in the apparatus width direction Y. As shown in FIGS. 11 and 12, the sub-slide plate 26 on the side away from the play pinion 18 in the apparatus width direction Y and on the recording / reproducing section B1 side has an apparatus depth direction X and an apparatus width direction Y. Parallel, substantially plate-like protruding claws 26a are provided. A load plate 27 and a load lever 28 are provided so as to sandwich the protruding claw 26a. As shown in FIGS. 11 and 12, the load plate 27 is provided with a boss 27 a that protrudes upward in the apparatus thickness direction Z. The boss 27a is inserted into a hole 28a provided in the load lever 28, and rotatably supports the load lever 28. In addition, as shown in FIG. 16A, the load plate 27 is provided with two engaging pins 27b and 27c that protrude downward in the apparatus thickness direction Z, respectively. The engaging pins 27b and 27c are slidably engaged with engaging grooves 19b and 19c formed in the lifting base 19 in parallel with the load plate 27 and in a substantially L shape. The engaging grooves 19b and 19c are arranged so as to be shifted from each other in the apparatus depth direction X and the apparatus width direction Y. Thus, when the engagement pins 27b and 27c of the load plate 27 slide on the engagement grooves 19b and 19c, the load plate 27 moves in parallel without rotating in the surface direction.

  In addition, an engagement pin 26 b that protrudes upward and downward in the apparatus thickness direction Z is provided at the tip of the protrusion 26 a of the sub-slide plate 26. The engaging pin 26b protruding below the protruding portion 26a is slidably engaged with an engaging groove 27d formed in the load plate 27 in a substantially L shape. Accordingly, when the sub slide plate 26 slides away from the play pinion 18, the side wall of the engagement groove 27d of the load plate 27 is pushed by the engagement pin 26b of the protruding portion 26a, and FIGS. As shown, the engagement pins 27 b and 27 c of the load plate 27 slide along the engagement grooves 19 b and 19 c of the elevating base 19. That is, the load plate 27 is configured to slide in a direction away from the play pinion 18, similarly to the sub-slide plate 26.

  The engagement groove 27d of the load plate 27 has first to fourth groove portions 27e to 27h having different inclination angles as shown in FIG. 16A. The first groove 27e is formed so as to incline toward the recording / reproducing section B1 in the apparatus depth direction X as the distance from the play pinion 18 increases in the apparatus width direction Y. The first groove portion 27e is arranged in the apparatus width direction Y so that the engaging pin 26b of the protruding portion 26a does not slide on the first groove portion 27e when the sub-slide plate 26 slides in a direction away from the play pinion 18. On the other hand, it is steep. The second groove portion 27f is inclined in the same manner as the first groove portion 27e, but is inclined more gently than the first groove portion 27e. The third groove portion 27g is formed so as to be inclined toward the standby section B2 side in the apparatus depth direction X as the distance from the play pinion 18 increases in the apparatus width direction Y. The fourth groove portion 27h is formed in parallel with the device width direction Y.

  On the other hand, the engaging pin 26b protruding above the protruding portion 26a is slidably engaged with an engaging groove 28b formed in the load lever 28 in a substantially L shape. When the sub slide plate 26 slides away from the play pinion 18, the side wall of the groove 28d of the load lever 28 is pushed by the engagement pin 26b of the protrusion 26a, and the load lever 28 is the same as the load plate 27. In addition, it is configured to slide in a direction away from the play pinion 18.

  The engaging groove 28b of the load lever 28 has first to third groove portions 28d to 28f having different inclination angles. As shown in FIG. 16A, the angle formed by the first groove portion 28d and the second groove portion 28e of the load lever 28 is narrower than the angle formed by the first groove portion 27e and the third groove portion 27g of the load plate 27. The angle formed by the second groove portion 28e and the third groove portion 28f of the load lever 28 is the same as the angle formed by the third groove portion 27g and the fourth groove portion 27h of the load plate 27.

  Further, a tray drive pin 28c is provided at the front end of the load lever 28 on the standby section B2 side. When the sub-slide plate 26 is positioned closest to the play pinion 18 side, the tray drive pin 28c is, as shown in FIG. 17A, the end portion of the guide groove 5f formed on the back surface of the tray 5 positioned at the recording / reproducing position A1. 5g is engaged with the tray 5. The guide groove 5f includes a first inclined portion 5h, a straight portion 5i, and a second inclined portion 5j in addition to the end portion 5g. One end of the first inclined portion 5h is connected to the end portion 5g, and the other end is inclined to the recording / reproducing section B2 side (upper side in FIG. 17A) as the play pinion 18 is separated. One end portion of the straight line portion 5 i is connected to the inclined portion 5 h and extends in parallel with the apparatus depth direction X. One end of the second inclined portion 5j is connected to the other end of the linear portion 5i, and the other end is inclined toward the recording / reproducing section B2 (upper side in FIG. 17A) as the play pinion 18 is separated. The other end of the second inclined portion 5j is released without stopping.

  As described above, when the load lever 28 slides away from the play pinion 18, the tray drive pin 28c is first moved toward the first inclined portion 5h along the side wall of the end portion 5g as shown in FIG. 17A. Guided near the entrance. In this state, when the load lever 28 is further moved, as shown in FIG. 17B, the tray driving pin 28c slides on the first inclined portion 5h and moves to the vicinity of the entrance of the linear portion 5i. At this time, the play pinion 18 meshes with the rack 5k provided on the side surface of the side of the tray 5 in parallel with the apparatus depth direction Y. When the driving force of the first motor 10 is transmitted to the play pinion 18 in this state, the tray 5 moves to the standby section B2 side in the apparatus depth direction X (downward in FIG. 17A), and the tray driving pin 28c is linear. Slide part 5i. At this time, as shown in FIG. 17C, the rack 26c (see FIG. 11) and the play pinion 18 provided at the end of the sub-slide plate 26 on the side opposite to the protruding claw 26a formation side do not mesh with each other. It has become.

  When the tray 5 further moves to the standby section B2 side from the state of FIG. 17C, as shown in FIG. 17D, the tray driving pin 28c moves to the vicinity of the entrance of the second inclined portion 5j. In this state, when the tray 5 further moves to the standby section B2 side, the tray drive pin 28c slides on the second inclined portion 5j as shown in FIG. 17E. At this time, the tray drive pin 28c is pushed by the side wall of the second inclined portion 5j, and the load lever 28 further moves to the side away from the play pinion 18 in the apparatus width direction Y as shown in FIG. 16C. At this time, the sub slide plate 26 connected to the load lever 28 via the load plate 27 also moves to the side away from the play pinion 18 in the apparatus width direction Y. As a result, the play pinion 18 and the rack 5k of the tray 5 are disengaged, and the play pinion 18 and the rack 26c of the sub slide plate 26 are engaged. In this state, when the driving force of the first motor 10 is transmitted to the play pinion 18, the sub slide plate 26 is pushed to the side away from the play pinion 18 in the apparatus width direction Y. As a result, as shown in FIG. 17E, the load lever 28 moves to the standby section B2 side in the apparatus depth direction X (lower side in FIG. 17E) by being pushed by the engagement pin 26b of the sub slide plate 26. Along with this movement, the tray 5 is pushed by the tray drive pin 26c of the load lever 26, and the tray 5 moves to the standby section B2 side (lower side in FIG. 17E) in the apparatus depth direction X. As a result, the tray 5 is positioned at the standby position A2.

  When the sub slide plate 26 is further moved away from the play pinion 18 from the state of FIG. 17E, the engaging pin 26 b comes into contact with the second groove portion 27 f of the load plate 27 as shown in FIG. 16D. Thereafter, the load lever 28 rotates in the clockwise direction of FIG. 16D around the vicinity of the engaging pin 26b. Accordingly, as shown in FIG. 16E, the third groove portion 27g and the fourth groove portion 27h of the load plate 27 and the second groove portion 28e and the third groove portion 28f of the load lever 28 coincide with each other. When the sub slide plate 26 is further moved away from the play pinion 18 in this state, the load pin 27 and the load lever 28 are pushed toward the recording / reproducing section B1 in the apparatus depth direction X by being pushed by the engaging pin 26b. Moving. When the engagement pin 26b moves to the fourth groove 27h of the load plate 27 and the third groove 28f of the load lever 28, the movement of the load plate 27 and the load lever 28 in the apparatus depth direction X is restricted. Thereby, as shown in FIGS. 16F and 17F, the engagement between the tray driving pin 28 c and the guide groove 5 f of the tray 5 is released. Thereby, the movement of the tray 5 from the recording / reproducing position A1 to the standby position A2 is completed. The movement from the standby position A2 to the recording / reproducing position A1 can be performed by driving the first motor 10 in the reverse direction. In this case, each component described above operates in the opposite manner to the above.

  A switch slider 29 is attached to the sub slide plate 26 so as to be movable integrally with the sub slide plate 26. The switch slider 29 is provided with a guide groove (not shown) in the apparatus thickness direction, and a pin 91a of the switch rod 91 shown in FIG. 4 is slidably engaged with the guide groove. At the timing when the switch slider 29 moves together with the sub slide plate 26 and the engaging pin 26b enters the third groove 28f of the load lever 28, the switch rod 29 is connected to a switch (not shown) provided on the lifting base 19. It arrange | positions so that it may contact and may turn on the said switch. When the switch is turned on, a control unit (not shown) provided in the apparatus stops driving the first motor 10. When the traverse base 9 moves up and down, the pin 91a of the switch rod 91 moves up and down in a guide groove (not shown) of the switch slider 29. As a result, the switch rod 91 moves integrally with the traverse base 9.

  According to the embodiment of the present invention, since the load plate 27 and the load lever 28 are configured as described above, when the tray 5 is moved to the standby position A2, the tray driving pin 28c is moved to the recording / reproducing section B1 side. It can be moved and engaged with the guide groove 5 f of the tray 5. On the other hand, after the tray 5 is moved to the standby position A2, the tray driving pin 28c can be retracted to the recording / reproducing section B1 side so that the guide groove 5f of the tray 5 and the tray driving pin 28c are not engaged. . As a result, the length in the apparatus depth direction X can be shortened by retracting the tray drive pin 28c, and the apparatus can be downsized. In contrast, in the configuration in which the tray drive pin 28c is not retracted, the tray 5 is further moved to the standby section B2 side in the apparatus depth direction X in order to disengage the guide groove 5f of the tray 5 from the tray drive pin 28c. Therefore, it is impossible to reduce the size of the apparatus.

  In the present embodiment, the first and second traverse gears 11 and 12, the feed rack 13, the loading gear 14A, the relay gear 14B, the play pinion 18, the traverse slide plate 20, and the sub slide plate 26 are used. The load plate 27 and the load lever 28 constitute a first tray drive unit that can reciprocate the tray 5 between the standby position A2 and the recording / reproducing position A1.

  Next, components and operations arranged in the standby section B2 will be described with reference to FIGS.

  As shown in FIG. 5, in the standby section B2, the elevating base 19 is moved up and down in the apparatus thickness direction Z, and a second driving force for conveying the tray 5 between the standby position A2 and the replacement position A3 is generated. A motor 31 is attached to the apparatus main body 2.

  A motor pulley 32 is attached to the drive shaft 31a of the second motor 31 as shown in FIGS. 18A and 18B. A pulley gear 34 is disposed at a position slightly away from the motor pulley 32, and a ring-shaped belt 33 is suspended between the two so that the driving force of the second motor 31 is transmitted to the pulley gear 34. An input gear 35a of the relay gear 35 is engaged with an output gear (not shown) of the pulley gear 34. The input gear 36 a of the switching gear 36 is engaged with the output gear 35 b of the relay gear 35.

  As shown in FIG. 19, the switching gear 36 is attached to one end of a switching lever 37 that is an example of a power transmission unit. At the other end of the switching lever 37, two bosses 37a and 37a projecting away from each other are provided. The switching lever 37 has two bosses 37a and 37a rotatably held by two holding portions 2a and 2a provided in the apparatus main body 2, so that a straight line connecting the two bosses 37a and 37a is used as an axis. It is configured to be rotatable. As the switching lever 37 rotates, the switching gear 36 can move up and down. That is, the switching gear 36 is positioned as shown in FIGS. 18A, 18B, and 19 when the switching lever 37 is rotated downward, and when the switching lever 37 is rotated upward, FIG. 20B and as shown in FIG.

  Further, as shown in FIG. 19, a protruding claw 37 b is provided on one end side of the switching lever 37. When the switching lever 37 is positioned on the lower side, the projecting claw 37b is configured to shield the sensor 2c on the substrate 2b attached to the apparatus main body 2. When the switching lever 37 is rotated upward, the protruding claw 37b is separated from the sensor 2c as shown in FIG. By detecting whether or not the protruding claw 37b shields the sensor 2c, it is possible to know whether the switching lever 37 is positioned on the upper side or the lower side.

  Further, as shown in FIG. 19, a cam groove 37 c having one inclined step portion is provided on the other end portion side of the switching lever 37. An engagement pin 38a provided on the switching arm 38 is slidably engaged with the cam groove 37c. The engaging pin 38 a is provided so as to protrude from one end of the elongated plate-like main body portion of the switching arm 38. Further, a projecting pin 38b that protrudes in the opposite direction to the engaging pin 38a is provided at the other end of the main body portion of the switching arm 38. As shown in FIG. 19, the projecting pin 38b penetrates a cam groove 19d formed in an L shape on the side of the lifting base 19 on the standby section B2 side, and as shown in FIGS. 18A and 18B, the sub-slide The plate 26 engages with a cam groove 26d formed in a substantially L shape. The cam groove 19 d of the elevating base 19 has a thickness direction straight part 19 e parallel to the apparatus thickness direction Z and a width direction straight part 19 e parallel to the apparatus width direction Y. The cam groove 26d of the sub-slide plate 26 has a straight portion 26e parallel to the apparatus width direction Y and an inclined portion 26f that is inclined downward toward the rack 26c side.

  The sub-slide plate 26 is provided with a projecting pin 26g, and the projecting pin 26g is slidably engaged with a guide groove 19g formed on the side surface of the elevating base 19, as shown in FIG. Match. Thus, the sub ride plate 26 is guided so as to move in parallel with the apparatus width direction Y. 18A, 18B, 20A, and 20B, the lifting base 19 is not shown.

  As described above, the switching arm 38 engaged with the cam groove 19d of the elevating base 19 and the cam groove 26d of the sub slide plate 26 moves as shown in FIGS. 22A to 22G. Hereinafter, the operation of the switching arm 38 will be described with reference to FIGS. 22A to 22G. Here, for convenience of explanation, the cam groove 37c of the switching lever 37 is assumed to be linear.

  FIG. 22A shows the state of the switching arm 38 when the sub-slide plate 26 is positioned on the rightmost side (play pinion 18 side) (that is, the switching arm 38 when the tray 5 is positioned at the recording / reproducing position A1). State). 22B to 22D show the state of the switching arm 38 when the sub ride plate 26 is moved stepwise to the left (load plate 27 side) from the state shown in FIG. 22A (ie, selected at the recording / reproducing position A1). The state of the switching arm 38 when the tray is transported to the standby position A2 is shown. 22E to 22G show the state of the switching arm 38 when the sub ride plate 26 is moved stepwise to the right (play pinion 18 side) from the state shown in FIG. 22D (ie, at the standby position A2). The state of the switching arm 38 when a tray selected from a plurality of trays 5 is conveyed to the recording / reproducing position A1 is shown.

  First, as shown in FIG. 22A, when the sub slide plate 26 is located at the rightmost position, the projection pin 38b of the switching arm 38 is located at the straight portion 26e of the sub slide plate 26, and the straight line in the thickness direction of the elevating base 19 is provided. Located in the portion 19e.

  Next, when the sub-slide plate 26 moves further leftward from the state of FIG. 22A, as shown in FIG. 22B, the projecting pin 38b does not move to the left in the figure because it abuts against the side wall of the thickness direction straight line portion 19e. Is pushed down by the inclined portion 26f. At this time, the engaging pin 38 a of the switching lever 38 moves slightly to the left along the cam groove 37 c of the switching lever 37.

  Next, when the sub-slide plate 26 moves further leftward from the state of FIG. 22B, as shown in FIG. 22C, the projecting pin 38b moves further downward by the inclined portion 26f, whereby the thickness direction linear portion 19e and Is removed and moved to the width direction linear portion 19f.

  Next, when the sub-slide plate 26 moves further leftward from the state of FIG. 22C, as shown in FIG. 22D, the projecting pin 38b moves along the width direction linear portion 19f. At this time, since the projecting pin 38b is located at the lower end of the inclined portion 26f, it moves to the left together with the sub-slide plate 26. On the other hand, the engaging pin 38 a of the switching lever 38 moves to the left along the cam groove 37 c of the switching lever 37. By this movement, the engaging pin 38a moves to the left while pushing down the inclined portion of the cam groove 37c of the switching lever 37, as shown in FIG. As a result, the switching lever 37 rotates and the switching gear 36 rises.

  Contrary to the above, when the first motor 10 is reversely driven and the sub-slide plate 26 moves to the right from the state of FIG. 22D, as shown in FIG. Along the sub-slide plate 26 and move to the right. At this time, the engaging pin 38a also moves to the right along the cam groove 37c of the switching lever 37, similarly to the protruding pin 38b. By this movement, the engagement pin 38a moves to the left while pushing up the inclined portion of the cam groove 37c of the switching lever 37, as shown in FIG. As a result, the switching lever 37 is rotated and the switching gear 36 is lowered.

  Next, when the sub-slide plate 26 moves further to the right from the state of FIG. 22E, as shown in FIG. 22F, the projection pin 38b is pushed upward by the inclined portion 26f and moved to the thickness direction linear portion 19e. At this time, the engaging pin 38 a moves slightly to the right along the cam groove 37 c of the switching lever 37. Thereby, the position of the switching arm 38 returns to the state of FIG. 22A.

  According to the embodiment of the present invention, the cam groove 19d of the elevating base 19 and the cam groove 26d of the sub slide plate 26 are configured as described above, so that the amount of movement of the sub slide plate 26 in the apparatus width direction Y is increased. On the other hand, the movement amount of the switching arm 38 can be reduced. Thereby, size reduction of the switching lever 37 etc. can be achieved, and as a result, size reduction of the whole apparatus can be achieved.

  As a comparative example, FIGS. 23A to 23G show an operation when the sub-slide plate 26 does not have the cam groove 26d and the lifting base 19 has a linear cam groove 119d instead of the cam groove 19d. Show. In this case, as shown in FIGS. 23A to 23G, the switching arm 38 moves in accordance with the amount of movement of the sub slide plate 26 in the apparatus width direction Y. Therefore, the switching lever 37 and the like are increased in size, and as a result, the entire apparatus cannot be reduced in size.

  In the present embodiment, the sub slide plate 26 and the switching arm 38 are used to replace any one of the disk clamp unit, the second tray driving unit, and the lifting unit with the first or second motor 10 or 31. The switching part which makes the state which can transmit the driving force of is comprised.

  As described above, the switching gear 36 that moves up and down by the rotation of the switching lever 37 is configured to mesh with the input gear 39a of the elevating drive gear 39 when raised as shown in FIGS. 20A, 20B, and 21. ing. As shown in FIG. 24, the output gear 39b of the lift drive gear 39 meshes with a rack 40a provided on the left slide lift cam 40. The rack 40a is provided in parallel with the apparatus depth direction X. Therefore, when the driving force of the second motor 31 is transmitted to the lifting drive gear 39, the entire left slide lifting rack 40 slides in the apparatus depth direction X as shown in FIG.

  A portion 40b on the recording / reproducing section B1 side (right side in FIG. 24) in the apparatus depth direction X of the left slide lifting rack 40 is formed in a substantially plate shape parallel to the apparatus thickness direction Z. The plate-like portion 40b is held by the apparatus main body 2 so as to be slidable in the apparatus depth direction X along one side surface of the apparatus main body 2. Two cam grooves 40c, 40c are provided in the plate-like portion 40b. Each of the cam grooves 40c, 40c is formed so as to be generally inclined upward toward the standby section B1 side in the apparatus depth direction X. Each of the cam grooves 40c, 40c has five step portions according to the height of each of the five trays 5, and is arranged so as to be shifted in parallel to the apparatus depth direction X. Two engagement pins 19f, 19f provided on one side surface of the elevating base 19 are slidably engaged with the cam grooves 40c, 40c. FIG. 25 shows a state in which the engagement pins 19f and 19f are positioned at the uppermost stage of the cam grooves 40c and 40c.

  At the end of the left slide lifting rack 40 on the standby section B2 side (left side in FIG. 24) in the apparatus depth direction X, a cylindrical engagement pin 40d that protrudes upward in the apparatus thickness direction Z is provided. The engaging pin 40d is engaged with one of the through holes 41a and 41a formed at both ends of the elongated plate-like connecting lever 41. The other through hole 41a of the connecting lever 41 is engaged with a cylindrical engaging pin 42a provided at the end of the right slide lifting rack 42 on the standby section B2 side (left side in FIG. 24) in the apparatus depth direction X. is doing. The through holes 41a and 41a of the connecting lever 41 are formed in a substantially elliptical shape, and the length of the short diameter portion is substantially equal to the diameter of each engagement pin 40d and 42a. The distance at which the respective through holes 41a and 41a are separated from each other is the same as or shorter than the shortest distance between the engagement pins 40d and 42a. On the other hand, the total length of the connecting lever 41 is longer than the shortest distance between the engaging pins 40d and 42a. For this reason, when the left slide lifting rack 40 is slid to the standby section B2 side in the apparatus depth direction X by the driving force of the second motor 31, as shown in FIG. Is slid to the recording / reproducing section B1 side (right side in FIG. 27) in the apparatus depth direction X.

  A portion 42b on the recording / reproducing section B1 side (right side in FIG. 24) in the apparatus depth direction X of the right slide lifting rack 42 is formed in a substantially plate shape parallel to the apparatus thickness direction Z. The plate-like portion 42 b is held by the apparatus main body 2 so as to be slidable in the apparatus depth direction X along one side surface of the apparatus main body 2. The plate-like portion 42b is provided with two cam grooves 42c and 42c, similarly to the plate-like portion 40b of the left slide lifting rack 40. Each of the cam grooves 42c, 42c is formed so as to be substantially inclined downward toward the standby section B1 side in the apparatus depth direction X. Each cam groove 42c, 42c has five steps according to the height of each of the five trays 5, like the cam grooves 40c, 40c of the left slide elevating rack 42, and is mutually connected to the apparatus depth. They are shifted in parallel to the direction X. Two engagement pins 19g and 19g provided on the side surface of the lift base 19 opposite to the formation surface of the engagement pin 19f are slidably engaged with the cam grooves 42c and 42c. The lift base 19 has two engagement pins 19f and 19f and two engagement pins 19g and 19g engaged with the cam grooves 40c, 40c, 42c and 42c, so that the right and left slide lift racks 40 and 42 are engaged. Is held in. FIG. 25 shows a state in which the engagement pins 19g and 19g are located at the uppermost stage of the cam grooves 40c and 40c.

  As described above, when the left and right slide lifting racks 40 and 42 are slid from the state shown in FIG. 24 to the state shown in FIG. 27 by the driving force of the second motor 31, each engagement pin of the lifting base 19 is engaged. As shown in FIGS. 28 and 29, 19f, 19f, 19g, and 19g slide from the uppermost stage to the lowermost stage of the cam grooves 40c, 40c, 42c, and 42c. Thereby, the raising / lowering base 19 can be moved to the height position corresponding to the tray 5e located in the lowest stage. Note that the lift base 19 can be moved to a height position corresponding to the desired tray 5 by adjusting the slide movement amount of the left and right slide lift racks 40, 42.

  In the present embodiment, the motor pulley 32, the belt 33, the pulley gear 34, the relay gear 35, the switching gear 36, the switching lever 37, the sub slide plate 26, the lifting base 19, and the lifting drive gear 39 are provided. A lifting unit capable of moving the traverse base 9 up and down so as to correspond to the height position of the tray located at the recording / reproducing position A2 by the left and right slide lifting racks 40 and 42 and the connecting lever 41. It is configured.

  Further, as shown in FIG. 30, a plurality of protrusions 60 are provided on a portion of the plate-like member 42 b of the right slide lifting rack 42 on the standby section B 2 side in the apparatus depth direction X. The plurality of protrusions 60 are provided at the height corresponding to the first-stage protrusion 61 provided at the height corresponding to the first-stage (topmost) tray 5a and at the height corresponding to the second-stage tray 5b. Provided at the height corresponding to the second-stage protrusion 62, the third-stage protrusion 63 provided at the height corresponding to the third-stage tray 5c, and the fourth-stage tray 5d. The fourth-stage protrusion 64 and the fifth-stage protrusion 65 provided at a height corresponding to the fifth-stage (lowermost) tray 5e.

  The second-stage protrusion 62 is composed of two protrusions 62a and 62b arranged at a predetermined interval. Each protrusion 62a, 62b is formed in the same size as the first protrusion 61. The third-stage protrusion 63 is composed of two protrusions 63a and 63b arranged with a predetermined gap. The protrusion 63a located on the recording / reproduction section B1 side in the apparatus depth direction X has a length in which the protrusions 62a and 62b in the second stage are connected to each other with a gap between them. The protrusion 63b located on the standby section B2 side in the apparatus depth direction X is formed in the same size as the first-stage protrusion 61. The fourth protrusion 64 is composed of two protrusions 64a and 64b arranged with a predetermined gap. The protrusion 64a located on the recording / reproducing section B1 side in the apparatus depth direction X has a length in which the protrusions 63a and 63b at the third stage are connected to each other while filling a gap therebetween. The protrusion 64b located on the standby section B2 side in the apparatus depth direction X is formed in the same size as the first-stage protrusion 61. The fifth-stage protrusion 65 includes two protrusions 65a and 65b arranged with a predetermined gap. The protrusion 65a located on the recording / reproducing section B1 side in the apparatus depth direction X has a length in which the protrusions 64a and 64b at the fourth stage are connected to each other with a gap between them being connected. The protrusion 65b located on the standby section B2 side in the apparatus depth direction X is formed in the same size as the first-stage protrusion 61. The first to fifth protrusions 61 to 65 are arranged so that the end portions of the protrusions 61a to 65a on the recording / reproducing section B1 side in the apparatus depth direction X are aligned in the apparatus thickness direction Z. All the protrusions 61a to 65a, 61b to 65b up to the first to fifth stages are formed to have a trapezoidal cross section.

  On the other hand, the switching gear 36 that moves up and down by the rotation of the switching lever 37 as described above is configured to mesh with the cam gear 43 when raised as shown in FIGS. 20A, 20B, and 21. A central hole 43 a is formed in the central portion of the cam gear 43. As shown in FIGS. 5 and 6, a shaft body 44 is inserted into the center hole 43 a of the cam gear 43, and the shaft body 44 is attached to the apparatus main body 2. Therefore, the cam gear 43 is configured to rotate about the shaft body 44 as a central axis. The cam gear 43 is configured to mesh with an input gear (not shown) of the tray relay gear 45. The output shaft 45 a of the tray relay gear 45 is configured to mesh with the shaft gear 76 of the tray drive gear unit 70.

  FIG. 32 is an exploded perspective view of the tray drive gear unit 70. As shown in FIG. 32, the tray drive gear unit 70 includes a first-stage tray drive gear 71, a second-stage tray drive gear 72, and a third-stage tray drive that are inserted into the shaft portion 76a of the shaft gear 76, respectively. A gear 73, a fourth-stage tray driving gear 74, and a fifth-stage tray driving gear 75 are provided. The first stage tray drive gear 71 is fixed around the tip of the shaft portion 76 a of the shaft gear 76 so as to rotate integrally with the shaft gear 76. The second to fifth tray drive gears 72 to 75 are rotatably mounted around the shaft portion 76a. Each of the tray drive gears 71 to 75 is configured to be able to mesh with a rack 5f (see FIG. 1) provided on a side surface of the corresponding tray 5. When the tray drive gears 71 to 75 are rotationally driven with the tray drive gears 71 to 75 meshing with the racks 5f of the corresponding trays 5, the corresponding trays 5 are placed between the standby position A2 and the replacement position A3. It is conveyed by. For example, when the fifth-stage tray driving gear 75 and the rack 5f of the fifth-stage tray 5e are engaged with each other, the driving force of the second motor 31 is transmitted to the tray driving gear 75 in the engaged state. The eye tray 5e is transported between the standby position A2 and the exchange position A3.

  Between the tray driving gears 71 to 75, two plastic rings 77 and 78 are rotatably attached around the shaft portion 76a of the shaft gear 76, respectively. Each plastic ring 77, 78 is provided with stopper ribs 77a, 78a at one place on the outer peripheral portion thereof. Each of the stopper ribs 77a and 78a is configured to have a size capable of coming into contact with each other when the plastic rings 77 and 78 are overlapped with each other.

  FIG. 33 is a perspective view showing a state in which the plastic rings 77 and 78 are attached to the first-stage tray driving gear 71. As shown in FIG. 33, a lower stopper rib 71 b that can come into contact with the stopper rib 77 a of the upper plastic ring 77 is provided below the first-stage tray driving gear 71. For example, when the first-stage tray drive gear 71 rotates in the direction of the arrow 80, the lower stopper rib 71b comes into contact with the stopper rib 77a of the plastic ring 77 as shown in FIG. In this state, when the first tray drive gear 71 further rotates in the direction of arrow 80, the stopper rib 77a is pushed by the lower stopper rib 71b, and the upper plastic ring 77 also rotates in the direction of arrow 80. The stopper rib 77a of the upper plastic ring 77 that rotates in the direction of the arrow 80 then contacts the stopper rib 78a as shown in FIG. When the first tray drive gear 71 further rotates in the direction of the arrow 80 in this state, the lower plastic ring 78 rotates in the direction of the arrow 80 with the stopper ribs 71b, 77a, 78a being in contact with each other. become.

  FIG. 35 is a perspective view showing a state in which the plastic rings 77 and 78 are arranged on the upper part of the second-stage tray driving gear 72. As shown in FIG. 35, an upper stopper rib 72b is provided on the upper portion of the second-stage tray gear 72. As described above, the lower plastic ring 78 rotating in the direction of the arrow 80 abuts on the upper stopper rib 72b as shown in FIG. In this state, when the first tray driving gear 71 further rotates in the direction of the arrow 80, the second tray driving gear 72 also rotates in the direction of the arrow 80.

  FIG. 36 is a perspective view showing a state in which the plastic rings 77 and 78 are disposed below the second-stage tray driving gear 72. As shown in FIG. 36, a lower stopper rib 72b is provided below the tray gear 72 at the second stage. As described above, the lower stopper rib 72 b of the second tray driving gear 72 that rotates in the direction of the arrow 80 abuts against the stopper rib 77 a of the upper plastic ring 77. In this state, when the second tray driving gear 71 further rotates in the direction of arrow 80, the stopper rib 77a is pushed by the lower stopper rib 72b, and the upper plastic ring 77 also rotates in the direction of arrow 80. The stopper rib 77a of the upper plastic ring 77 rotating in the direction of the arrow 80 then contacts the stopper rib 78a as shown in FIG. When the second-stage tray drive gear 72 further rotates in the direction of the arrow 80 in this state, the lower plastic ring 78 rotates in the direction of the arrow 80 with the stopper ribs 72b, 77a, 78a being in contact with each other. become.

  Since the third to fifth tray drive gears 73 to 75 are configured in the same manner as the second tray drive gear 72 and operate in the same manner, the description thereof is omitted. The fifth-stage tray gears 73 to 75 are provided with only upper stopper ribs (not shown).

  As described above, when all of the tray driving gears 71 to 75 and the plastic rings 77 and 78 are rotated in the same direction, the respective stopper ribs finally come into contact with each other. When the tray driving gear unit 70 is further rotated in this state, the tray driving gears 71 to 75 are simultaneously rotated. As a result, the five trays 5 can be simultaneously transported to the replacement position A3.

  In the present embodiment, the motor pulley 32, the belt 33, the pulley gear 34, the relay gear 35, the switching gear 36, the switching lever 37, the sub slide plate 26, the elevating base 19, the cam gear 43, the tray The relay gear 45 and the tray drive gear unit 70 constitute a second tray drive unit that can reciprocate the tray 5 between the standby position A2 and the exchange position A3.

  Further, as shown in FIG. 6, an elongated substantially plate-like slider arm 46 is disposed between the cam gear 43 that transmits the driving force from the second motor 30 to the tray driving gear unit 70 and the apparatus body 2. ing. As shown in FIG. 37, the slider arm 46 is provided with a through hole 46 a in a portion on the end side close to the cam gear 43. The slider arm 46 is attached to the apparatus main body 2 so as to be rotatable about the protruding shaft 2b by inserting the protruding shaft 2d provided in the apparatus main body 2 into the through hole 46a.

  At the end of the slider arm 46 on the cam gear 43 side, as shown in FIG. 37, an engagement pin 46b that protrudes upward in the apparatus thickness direction Z is provided. The engaging pin 46 b is slidably engaged with a guide groove 43 b provided on the lower surface side of the cam gear 43. As shown in FIG. 37, the guide groove 43b has a substantially circular groove portion 43c concentric with the center hole 43a of the cam gear 43, and an inclined portion 43d inclined from the substantially circular groove portion 43c to the side away from the center hole 43a. . When the cam gear 43 rotates in the direction of the arrow 81 with the engagement pin 46b engaged with the substantially circular groove 43c, the slider arm 46 does not rotate. On the other hand, when the cam gear 43 rotates in the direction of the arrow 81 with the engaging pin 46b engaged with the inclined portion 43d, the slider arm 46 rotates in the direction of the arrow 82 about the protruding shaft 2b. As a result, the slider arm 46 moves to the position shown in FIG. When the cam gear 43 is rotated in the direction opposite to the arrow 81, the slider arm 46 rotates in the direction opposite to the arrow 82. That is, the slider arm 46 moves from the position shown in FIG. 38 to the position shown in FIG.

  An engagement pin 46 c that protrudes downward in the apparatus thickness direction Z is provided at the end of the slider arm 46 on the side away from the cam gear 43. As shown in FIG. 37, the engagement pin 46 c is engaged with a guide groove 47 b formed in the plate-like protrusion 47 a of the trigger slider 47. The trigger slider 47 has a substantially rectangular frame-shaped main body 47 c parallel to the apparatus depth direction X and the apparatus thickness direction Z. The protruding portion 47a protrudes in the apparatus width direction Y from the center portion of the lower surface of the frame-shaped main body 47c. The guide groove 47b is formed in parallel with the apparatus width direction Y. Since the engagement pin 46c is engaged with the guide groove 47b, when the slider arm 46 is rotated, the trigger slider 47 is translated in the apparatus depth direction X as shown in FIGS.

  Further, as shown in FIG. 5, the trigger slider 47 has a shaft 47 d extending in the apparatus thickness direction at the center portion in the apparatus depth direction X. As shown in FIG. 31, a trigger lever 48 (48a to 48e), which is an example of five substantially rod-shaped trigger portions, is attached to the shaft 47d. Each trigger lever 48 has a “C” -shaped bearing portion 48f at the center in the extending direction, and is fitted to the trigger slider 47 so as to be rotatable by fitting the bearing portion 48f to the shaft 47d. Yes. Each trigger lever 48 is configured in the same shape and the same size, and only the mounting position is different.

  As shown in FIG. 39 or FIG. 40, the end of each trigger lever 48 on the tray driving gear unit 70 side in the apparatus depth direction X is engaged with any one of the protrusions 60 of the right slide lifting rack 42. A protrusion engaging claw portion 48g that can be engaged, and a tray pushing claw portion 48h that can engage with a step portion 5g formed on the side surface of the tray 5 are provided. Also, tray lock levers 49 (49a to 49e), which are examples of five tray lock portions, are disposed on the tray drive gear unit 70 side (lower side in FIG. 39) of each trigger lever 48 in the apparatus depth direction X. Yes. Each tray lock lever 49 has a "C" -shaped bearing 49f at the center in the extending direction. Each tray lock lever 49 is rotatable to the apparatus main body 2 by fitting a bearing portion 49f to a shaft 2f (see FIG. 5) provided to extend in the apparatus thickness direction Z in the apparatus main body 2. It is attached. Each trigger lock lever 49 is configured in the same shape and the same size, and only the mounting position is different.

  At the end of each tray lock lever 49 on the recording / reproducing section B1 side in the apparatus depth direction X (upper side in FIG. 39), an inclined surface 49g inclined with respect to the apparatus depth direction X and the apparatus width direction Y, and the tray 5 A tray locking claw 49h that can be engaged with a recess 5h formed on the side surface is provided. Further, a portion of each tray lock lever 49 on the tray driving gear unit 70 side in the apparatus depth direction X is an elastic portion 49i bent in an L shape. The tray lock lever 49 is disposed so that the tip end portion of the elastic portion 49 i abuts on a rib (not shown) provided in the apparatus main body 2. Thereby, the tray lock lever 49 is normally located in the state shown in FIG. 39, and when the tray lock lever 49 is rotated in the direction of the arrow 84, the elastic portion 49i is elastically deformed, and the tray lock lever 49 is It is urged to rotate in the direction opposite to the arrow 84.

  With reference to FIGS. 37 to 41, the operation when the first tray 5a is transported to the replacement position A3 when the elevating base 19 is positioned at a height corresponding to the first tray 5a will be described. . 39 shows a state before the trigger lever 48c moves to the tray drive gear unit 70 side in the apparatus depth direction X and rotates around the bearing portion 48f. FIG. 40 shows the state after the rotation. Show. FIG. 41 is a perspective view of the state of FIG. 40 viewed obliquely from above. 39 and 40, a trigger lever 48e corresponding to the fifth tray 5e is shown as the trigger lever 48, and a tray lock lever 49e corresponding to the fifth tray 5e is shown as the tray lock lever 49. ing.

  When the lifting base 19 is located at a height corresponding to the first tray 5a, the right slide lifting rack 42 that moves in the apparatus depth direction X according to the height position of the tray 5a as described above is shown in FIG. Located at the indicated position. Before the fifth-stage trigger lever 48e rotates, the fifth-stage trigger lever 48e is positioned on the recording / reproducing position A1 side (upper side in FIG. 39) of the protrusion 65a. At this time, the first to fourth-stage trigger levers 48a to 48d are also positioned on the recording / reproducing position A1 side (upper side in FIG. 39) of the protrusions 61a to 64a, respectively.

  When the fifth-stage trigger lever 48e is moved to the tray driving gear unit 70 side in the disc depth direction X as described above from the state shown in FIG. 39, the projection engaging claw portion 48g is inclined on the inclined surface of the projection portion 65a. The trigger lever 48e at the fifth stage rotates in the direction of the arrow 83. Thereby, the projection engaging claw portion 48g of the fifth-stage trigger lever 48e rides on the top surface of the projection portion 65a as shown in FIGS. At this time, the first to fourth stage trigger levers 48a to 48d also ride on the top surfaces of the protrusions 61a to 64a. At this time, the tip 48i of the fifth-stage trigger lever 48e pushes the inclined surface 49g of the fifth-stage tray lock lever 49e, and the fifth-stage tray lock lever 49e moves in the direction of the arrow 84 as shown in FIG. Rotate. This disengages the tray locking claw 49h of the fifth tray lock lever 49e from the recess 5h of the fifth tray 5e, allowing the fifth tray 5e to move to the replacement position A3. . At this time, similarly, the 1st to 4th stage trigger levers 48a to 48d also rotate the 1st to 4th stage tray lock levers 49a to 49d in the direction of the arrow 84, thereby 5a to 5d can move to the exchange position A3.

  When the fifth-stage trigger lever 48e moves further to the tray drive gear unit 70 side from the state of FIG. 40, the tray push-out claw section 48h pushes the step section 5g of the fifth-stage tray 5e, and the fifth-stage tray 5e. The fifth-stage tray driving gear 73 of the tray driving gear unit 70 meshes with the rack 5f. At this time, the first to fourth tray drive gears 71 to 74 of the tray drive gear unit 70 mesh with the racks 5f of the first to fourth trays 5a to 5d in the same manner. In this state, when the first to fifth tray driving gears 71 to 75 are rotationally driven, the first to fifth trays 5a to 5e move to the replacement position A3.

  Next, referring to FIGS. 42 to 45, when the elevating base 19 is positioned at a height corresponding to the third tray 5c, the operation when the third tray 5c is transported to the replacement position A3. Will be described. FIG. 42 shows a state before the third-stage trigger lever 48c moves to the tray driving gear unit 70 side in the apparatus depth direction X and rotates around the bearing portion 48f. FIG. The later state is shown. FIG. 44 is a perspective view of the state of FIG. 42 viewed obliquely from above. FIG. 45 is a perspective view showing a state in which the third and lower trays 5c to 5d have moved to the replacement position A3.

  When the lifting base 19 is positioned at a height corresponding to the third tray 5c, the right slide lifting rack 42 that moves in the apparatus depth direction X according to the height position of the tray 5c as described above is shown in FIG. Located at the indicated position. Before the third-stage trigger lever 48c rotates, the third-stage trigger lever 48c is positioned between the protrusion 63a and the protrusion 63b. At this time, the first-stage trigger lever 48a is positioned at a position over the protrusion 61a, and the second-stage trigger lever 48b is positioned at a position beyond the protrusion 62b. The fourth-stage trigger lever 48d is located on the protrusion 64a, and the fifth-stage trigger lever 48e is located on the protrusion 65a.

  42, when the third-stage trigger lever 48c is moved to the tray drive gear unit 70 side in the disc depth direction X as described above, the projection engaging claw portion 48g is inclined on the inclined surface of the projection portion 63b. The trigger lever 48c at the third stage rotates in the direction of the arrow 83. As a result, the protrusion engaging claw portion 48g of the third-stage trigger lever 48c rides on the top surface of the protrusion portion 63b as shown in FIGS. At this time, the fourth-stage trigger lever 48d slides on the top surface of the protrusion 64a, and the fifth-stage trigger lever 48e slides on the top surface of the protrusion 65b. At this time, the tip 48i of the third-stage trigger lever 48c pushes the inclined surface 49g of the third-stage tray lock lever 49c, and the third-stage tray lock lever 49c moves in the direction of the arrow 84 as shown in FIG. Rotate. This disengages the tray locking claw 49h of the third tray lock lever 49c from the recess 5h of the third tray 5c, and the third tray 5c can be moved to the replacement position A3. . At this time, similarly, the fourth and fifth trigger levers 48d and 48e rotate the fourth and fifth tray lock levers 49d and 49e in the direction of the arrow 84, and the fourth and The fifth trays 5d and 5e can be moved to the replacement position A3. On the other hand, the first and second trigger levers 48a and 48b do not rotate in the direction of the arrow 84 because the projection engaging claw 48g slides on the plate-like portion 42b. Therefore, the first and second tray lock levers 49a and 49b do not rotate in the direction of the arrow 84, and the first and second trays 5a and 5b cannot move to the replacement position A3. .

When the third-stage trigger lever 48c further moves to the tray drive gear unit 70 side from the state of FIG. 43, the tray push-out claw section 48h pushes the step section 5g of the third-stage tray 5c, and the third-stage tray 5c. The third-stage tray drive gear 73 of the tray drive gear unit 70 meshes with the rack 5f. At this time, the fourth and fifth tray drive gears 74 and 75 of the tray drive gear unit 70 mesh with the rack 5f of the fourth and fifth trays 5d and 5e in the same manner.
In this state, when the third to fifth tray drive gears 73 to 75 are rotationally driven, the third to fifth trays 5c to 5e move to the replacement position A3 as shown in FIG.

  According to the disk changer device 1 according to the embodiment of the present invention, by having the above-described configuration, the tray corresponding to the height position of the elevating base 19 (in the above example, the third-stage tray 5c). It is possible to prevent the trays located on the upper side (in the above example, the first and second trays 5a and 5b) from being discharged to the replacement position A3. Therefore, it is not necessary to prepare a separate tray for transporting the tray 5, so that the disk on the tray positioned at the recording / reproducing position A1 can be confirmed in a short time without increasing the size of the apparatus.

  Further, according to the disk changer device 1 according to the embodiment of the present invention, all the trays existing below the tray are transported to the replacement position A3 simultaneously with the tray corresponding to the height position of the elevating base 19. I have to. Thereby, since the tray corresponding to the height position of the raising / lowering base 19 can be supported by the tray which exists under the said tray, thickness reduction of a tray can be achieved. Therefore, it is possible to realize a reduction in size and thickness of the device.

  In the above description, all trays existing below the tray are transported to the replacement position A3 simultaneously with the tray corresponding to the height position of the elevating base 19, but the present invention is limited to this. Not a thing. The same effect can be obtained by simultaneously transferring the tray adjacent to the lower side of the tray to the replacement position A3 at the same time as the tray corresponding to the height position of the lift base 19.

  In the above description, the third-stage protrusion 63a is configured to have a length in which the second-stage protrusions 62a and 62b are connected to each other with a gap between them, but the present invention is not limited to this. For example, instead of the third-stage protrusion 63a, two protrusions having the same shape and the same arrangement interval as the second-stage protrusions 62a and 62b may be disposed. Similarly, the fourth and fifth protrusions 64a and 64a may be configured by three or four protrusions. That is, a protrusion having the same shape as the first protrusion 61 a may be arranged in parallel in the apparatus thickness direction Z. In addition, as shown in FIG. 30, it is more preferable to configure the third to fifth protrusions 63a to 65a so that the length in the apparatus depth direction X is longer than the first protrusion 61a. From the configuration, there is an advantage that the number of times that the trigger levers 48c to 48e sliding on the protrusions 63a to 65a move in the apparatus width direction Y (that is, move between adjacent protrusions) can be reduced. . Thereby, the trigger levers 48c to 48e can be prevented from being damaged, and vibrations caused by the trigger levers 48c to 48e moving between the adjacent protrusions can be prevented.

  In the present embodiment, the second motor 31, the motor pulley 32, the belt 33, the pulley gear 34, the relay gear 35, the switching gear 36, the cam gear 43, the slider arm 46, the trigger slider 47, and the trigger The lever 48 and the protrusion 60 engage the selected tray and the tray lock lever corresponding to the tray, and the tray adjacent to the selected tray on the lower side and the tray lock lever corresponding to the tray. An engagement release unit that can release the engagement is configured. In the present embodiment, the second motor 31, the motor pulley 32, the belt 33, the pulley gear 34, the relay gear 35, the switching gear 36, the cam gear 43, the slider arm 46, and the trigger slider 47, A trigger moving unit is configured that can move the trigger lever 48 in the tray conveyance direction.

  Further, as shown in FIG. 31, the disc changer device 1 according to the present embodiment includes an all trigger lever 50 in the vicinity of the distal end portion 48 i of the trigger lever 48. The all trigger lever 50 extends in the apparatus thickness direction Z, and the shaft 2g (see FIG. 6) provided in the apparatus main body 2 is inserted into the bearing hole 50a, so that the all trigger lever 50 can rotate around the bearing hole 50a. It is attached. The all trigger lever 50 includes a claw portion 50b that can contact each of the five trigger levers 48a to 48e. The all trigger lever 50 rotates about the bearing hole 50a, and the claw portion 50b pushes the tip end portion 48i of each trigger lever 48a to 48e, so that all the trigger levers 48a to 48e are simultaneously moved in the direction of the arrow 83. It can be rotated. That is, the all trigger lever 50 can release all the locked states of the trays 5a to 5e by the tray lock levers 49a to 49e regardless of the positional relationship between the trigger levers 48a to 48e and the protrusion 60.

  As shown in FIG. 31, the lower end portion of the all trigger lever 50 is provided with a protruding portion 50 c that protrudes inside the device in the device width direction Y. An engagement pin 50d that protrudes upward in the apparatus thickness direction Z is provided at the tip of the protrusion 50c. The engaging pin 50 d is slidably engaged with a cam groove 51 a provided at one end of the trigger link lever 51. The trigger link lever 51 has a shaft portion 51b in a portion slightly closer to the center than the other end portion, and is attached to the apparatus main body 2 so as to be rotatable by the shaft portion 51b. The trigger link lever 51 is urged in the rotational direction of the arrow 85 by a torsion spring (not shown) attached to the shaft portion 51b. As shown in FIG. 46, the other end of the trigger link lever 51 is provided with a claw 51c that can contact a part of the sub-slide plate.

  As shown in FIG. 47, when a part of the sub slide plate 26 and the claw portion 51c of the trigger link lever 51 are not in contact, the engaging pin of the all trigger lever 50 is applied by the biasing force in the direction of the arrow 85 of the torsion spring. Reference numeral 50d denotes an end portion of the cam groove 51a on the side away from the all trigger lever 50, and is engaged with the trigger link lever 51. On the other hand, as shown in FIG. 46, when a part of the sub slide plate 26 and the claw part 51c of the trigger link lever 51 come into contact with each other and a part of the sub slide plate 26 presses the claw part 51c, the trigger link lever 51 Rotates around the shaft 51b in the direction of the arrow 86. Thereby, the engaging pin 50d of the all trigger lever 50 slides in the cam groove 51a. At this time, since the engaging pin 50d passes through the step portion of the cam groove 51a, the engaging pin 50d moves to the replacement position A3 side (lower side in FIG. 46) in the apparatus depth direction X. Thereby, the all trigger lever 50 rotates around the bearing hole 50 a, and the claw portion 50 b pushes the tip end portion i of the trigger lever 48. Thereby, the trigger lever 48 rotates around the bearing portion 48f. Hereinafter, as described above, the rotation of the trigger lever 48 causes the tray lock lever 49 to rotate in the direction of the arrow 84 as shown in FIG. 43, and the tray lock claw portion 49h and the recesses 5h of the trays 5a to 5e And the trays 5a to 5e can be moved to the recording / reproducing position A1 or the exchange position A3.

  The sub-slide plate 26 is positioned at the position shown in FIG. 46 when any one of the five trays 5 is positioned at the recording / reproducing position A1. In this case, it is necessary to prevent other trays from moving to the recording / reproducing position A1. Therefore, in the embodiment of the present invention, the trigger link lever 51, the all trigger lever 50, each trigger lever 48, and each tray lock lever 49 are rotated to lock the movement of other trays.

  Further, the disk changer device 1 according to the present embodiment includes a lift cam lock 52 in the vicinity of the cam gear 43 as shown in FIGS. The elevating cam lock 52 includes an engagement pin 52a that protrudes upward in the apparatus thickness direction Z, and is engaged with the guide groove 43e of the cam gear 43 by the engagement pin 52a as shown in FIG. Further, the lifting cam lock 52 includes a protruding piece 52b that protrudes to the outside of the apparatus in the apparatus width direction Y. The raising / lowering cam lock 52 is restricted in movement in the apparatus depth direction X and the apparatus thickness direction Z by inserting a protruding piece 52b into an insertion hole (not shown) provided in the apparatus body 2, and is moved in the apparatus width direction Y. Is attached to the apparatus main body 2 so that it can move.

  The lift cam lock 52 is provided with five recesses 52c to 52g in which the engagement pins 42a of the right slide lift rack 42 can be engaged. When the elevating base 19 is positioned at a height corresponding to the fifth tray 5e, the engaging pin 42a engages with the recess 52c as shown in FIG. When the elevating base 19 is positioned at a height corresponding to the first tray 5a, the engaging pin 42a engages with the recess 52g as shown in FIG. Further, when the elevating base 19 is positioned at a height corresponding to the second to fourth trays 5b to 5d, the engagement pin 42a engages with the recesses 52d to 52f. When the engaging pin 42a is engaged with any one of the recesses 52c to 52g, the movement of the mechanism that raises and lowers the lifting base 19 including the right slide lifting rack 42 is locked.

  While the right slide lifting rack 42 slides and the height position of the lifting base 19 changes, the engaging pin 52a of the lifting cam lock 52 is provided in the guide groove 43e as shown in FIG. It moves on the step 43f. As a result, the entire lift cam lock 52 is moved in the apparatus width direction Y (left side in FIG. 50), and the engagement pin 42a and the recesses 52c to 52g are disengaged.

  Further, as shown in FIG. 5, the disk changer device 1 according to the present embodiment further includes an open switching lever 53 in the vicinity of the tray drive gear unit 70. The open switching lever 53 includes contact claws 53a that can come into contact with each of the trays 5a to 5e when the trays 5a to 5e move from the replacement position A3 to the standby position A2. When the contact claw 53a contacts any of the trays 5a to 5e, the open switching lever 53 is pushed by any of the trays 5a to 5e and rotates. When the rotation of the open switching lever 53 is detected by the sensor 54a (see FIG. 5) of the mechanical board unit 54 attached to the apparatus main body 2, the controller (not shown) of the apparatus replaces the trays 5a to 5e. The second motor 31 is driven so as to convey from the position A3 to the standby position A2. Thus, for example, when the user presses the first tray 5a located at the replacement position A3 toward the standby position A2, the open switch lever 53 is rotated by the tray 5a and the rotation is detected by the sensor. 54a detects and the 2nd motor 31 drives. Therefore, when the user manually pushes the tray 5a back to the standby position A2 without using the close button of the housing, the first tray 5a is automatically moved from the detection position to the standby position A2. It is conveyed to.

  As shown in FIG. 51, the mechanical board unit 54 is provided with a first sensor 54b and a second sensor 54c. As shown in FIGS. 51 and 52, the first sensor 54b is disposed in the vicinity of the center hole 43a of the cam gear 43 and below a substantially cylindrical rib 43h provided concentrically with the center hole 43a. As shown in FIG. 52, slits 43g and 43g are formed at two locations on the rib 43h. Here, the rotation of the tray lock lever 49 that brings the tray 5 into the locked state or the unlocked state depends on the rotation amount of the cam gear 43 that transmits the driving force to the tray lock lever 49. That is, by detecting the rotation amount of the cam gear 43, it can be detected whether the tray 5 is in the locked state or the unlocked state. Therefore, the first sensor 54 b is configured to detect the amount of rotation of the cam gear 43 by detecting the slits 43 g and 43 g when the cam gear 43 rotates.

  As shown in FIGS. 51 and 52, the second sensor 54c is disposed outside the rib 43h and below a substantially cylindrical rib 43i provided concentrically with the center hole 43a. As shown in FIG. 52, slits 43j,..., 43j are formed in the rib 43i at five locations. Here, the rotation of the tray drive gear unit 70 that conveys the trays 5a to 5e to the replacement position A3 depends on the rotation amount of the cam gear 43 that transmits the drive force to the tray drive gear unit 70. That is, by detecting the rotation amount of the cam gear 43, it is possible to detect which tray 5 is located at the replacement position A3 and which tray 5 is located at the standby position A2. Therefore, the second sensor 54b is configured to detect the amount of rotation of the cam gear 43 by detecting the slits 43j,..., 43j when the cam gear 43 rotates.

  The disc changer device 1 according to the present embodiment further includes a pitch plate 55 as shown in FIG. The pitch plate 55 is attached to the apparatus main body 2 so as to cover various components such as the cam gear 34 positioned below the tray 5.

  Next, a return operation when the tray drive pin 28c of the load lever 28 is disengaged from the guide groove 5f of the tray 5 when the tray 5 is transported from the recording / reproducing position A1 to the standby position A2 will be described.

  As described above with reference to FIG. 17E, when the tray 5 is transported from the reproduction position A1 to the standby position A2, the tray drive pin 28c guided to the linear portion 5i of the guide groove 5f changes when the inclination of the guide groove 5f changes. The normal operation is driven along the inclined portion 5j. However, when the tray drive pin 28c and the tray groove 5f are disengaged, the sub-slide plate 26 remains in a position where the rack portion 26c does not engage with the pre-pinion 18 as shown in FIG. Is completed, it becomes impossible to transition from this state to another state.

  In the state of FIG. 53, even if the first motor 10 continues to be driven, it is not transmitted to the sub-slide plate 26, and therefore no state transition signal is detected even after a certain period of time has elapsed. Thus, it is determined that the disk changer device 1 according to the present embodiment is in an abnormal state as shown in FIG. When this state is detected, the second motor 31 is driven to start the return operation.

At the start of the return operation, the slider arm 46 is disposed at the position shown in FIG. Here, since the slider arm 46 is engaged with the guide groove 43 b of the cam gear 43 by the engagement pin 46 b, the position thereof is governed by the state of the cam gear 43. Further, the sub slide plate 26 is in a position where the drive of the pre-pinion 18 is not transmitted and is in contact with the trigger link lever 51. When the return operation is started, the cam gear 43 is rotated by the driving force of the second motor 31. (Clockwise direction in FIG. 54)
When the return operation starts, the slider arm 46 is rotationally driven to the position shown in FIG. The slider arm 46 is provided with an engaging pin 46d protruding in the apparatus thickness direction Z, and the trigger link lever 51 is provided with a rib 51d protruding in the apparatus thickness direction Z. Therefore, in the slider arm 46 at the position shown in FIG. 55, the engaging pin 46d pushes the rib 51d, and the trigger link lever 51 is rotated. Since the trigger link lever 51 is in contact with the sub slide plate 26, the sub slide plate 26 receives the driving force and is moved to a position where the rack portion 26 c is engaged with the play pinion 18. After the state shown in FIG. 55 is reached, driving of the first motor 10 is started. Since the rack portion 26c of the sub slide plate 26 is moved to the position where it engages with the play pinion 18 by the rotation of the slider arm 46, the driving force of the play pinion 18 is normally transmitted to the sub slide plate 26, and the load The tray drive pin 28 c of the lever 28 moves in a direction to return to the guide groove 5 f of the tray 5.

  Here, an inclined surface is introduced into the guide groove 5f of the tray 5 on an operation trajectory when the removed tray driving pin 28c returns into the groove. The tray drive pin 28c, whose driving has been resumed, is guided by this inclined surface, and returns to the guide groove 5f by elastically deforming the tray 5. With the above operation, even when the tray drive pin 28c of the load lever 28 is disengaged from the guide groove 5f of the tray 5, the tray drive pin 28c can be returned to the normal state only by the drive source in the disc changer device 1. It becomes.

  In addition, this invention is not limited to the said embodiment, It can implement with another various aspect.

  The disc changer device according to the present invention can return the tray drive pin that has come out of the groove of the tray from the irregular position to the regular position using the drive force of the disc changer device itself. Therefore, the configuration of the present invention is effective in improving the quality of a disk loading apparatus that switches the drive by the tray groove.

The perspective view of the disk changer apparatus concerning embodiment of this invention The top view which shows the state in which the tray is located in a disk recording / reproducing position, a standby position, and a disk exchange position in the disk changer apparatus concerning embodiment of this invention. 1 is an exploded perspective view of a disk changer device according to an embodiment of the present invention. Partial enlarged perspective view of the recording / reproducing section of FIG. Partial enlarged perspective view of the standby section of FIG. The top view which shows the state which removed the upper cover, the clamp plate, and the tray in the disc changer apparatus concerning embodiment of this invention. The perspective view which shows the structure of the moving mechanism of an optical pick-up The perspective view which looked at the moving mechanism of FIG. 7A from another angle. The top view which shows the positional relationship of the upper plate-shaped member of a feed rack, a swing arm, and a swing lock The figure which permeate | transmitted and showed some components of FIG. 8A The top view which shows the state which the upper side plate-shaped member of the feed rack moved from the state of FIG. 8A FIG. 9A shows a part of the part shown in FIG. The top view which shows the state which the upper side plate-shaped member of the feed rack moved from the state of FIG. 9A further The figure which permeate | transmitted and showed some components of FIG. 10A The perspective view which shows the structure of the tray conveyance mechanism which conveys the tray between the recording / reproducing position and a standby position in the disc changer apparatus concerning embodiment of this invention. FIG. 11 is a plan view of the tray transport mechanism shown in FIG. The top view which shows the state before a feed rack and a traverse slide plate engage. The top view which shows the state which the feed rack and the traverse slide plate engaged The top view which shows the state which the pin of the feed rack and the latching claw of the raising / lowering base engaged. The top view which shows the state of the tray conveyance mechanism shown in FIG. 11 when a tray is located in a recording / reproducing position. FIG. 16A is a plan view showing a state following FIG. 16A when the tray is conveyed from the recording / reproducing position to the standby position. The top view which shows the state following FIG. 16B The top view which shows the state following FIG. 16C The top view which shows the state following FIG. 16D The top view which shows the state following FIG. 16E FIG. 11 is a plan view showing the positional relationship between the tray transport mechanism shown in FIG. 11 and the tray when the tray is located at the recording / reproducing position. FIG. 17A is a plan view showing the positional relationship between the tray transport mechanism and the tray subsequent to FIG. 17A when the tray is transported from the recording / reproducing position to the standby position. The top view which shows the state following FIG. 17B The top view which shows the state following FIG. 17C The top view which shows the state following FIG. 17D The top view which shows the state following FIG. 17E The perspective view which shows the state which the switching gear in which driving force is transmitted from a 2nd motor meshed with the cam gear. The perspective view which looked at the state which the switching gear transmitted with a driving force from a 2nd motor meshed | engaged with the cam gear from the angle different from FIG. 18A. A perspective view showing a state where the switching gear is lowered The perspective view which shows the state which the switching gear transmitted with a driving force from a 2nd motor meshed with the raising / lowering drive gear. The perspective view which looked at the state which the switching gear transmitted with a driving force from a 2nd motor meshed with the raising / lowering drive gear from the angle different from FIG. 20A. The perspective view which shows the state which the switching gear raised The side view which shows typically the state of a switching arm when the sub slide plate is located in the play pinion side most in the disc changer apparatus concerning embodiment of this invention. Side view schematically showing the state of the switching arm when the sub-slide plate moves away from the play pinion from the state shown in FIG. 22A. 22B is a side view schematically showing the state of the switching arm when the sub slide plate moves further away from the play pinion from the state shown in FIG. 22B. Side view schematically showing the state of the switching arm when the sub-slide plate moves further away from the play pinion from the state shown in FIG. 22C. The side view which shows typically the state of a switching arm when a sub slide plate moves to the direction approaching a play pinion from the state shown to FIG. 22D. The side view which shows typically the state of the switching arm when a sub slide plate moves to the direction which further approaches a play pinion from the state shown to FIG. 22E. The side view which shows typically the state of the switching arm when a sub slide plate moves to the direction which further approaches a play pinion from the state shown to FIG. 22F. The side view which shows typically the state of a switching arm when a sub slide plate is located in the play pinion side most in the disk changer apparatus as a comparative example. Side view schematically showing the state of the switching arm when the sub slide plate moves away from the play pinion from the state shown in FIG. 23A. FIG. 23B is a side view schematically showing the state of the switching arm when the sub slide plate is moved further away from the play pinion from the state shown in FIG. 23B. Side view schematically showing the state of the switching arm when the sub-slide plate moves further away from the play pinion from the state shown in FIG. 23C. The side view which shows typically the state of the switching arm when a sub slide plate moves to the direction approaching a play pinion from the state shown to FIG. 23D. FIG. 23E is a side view schematically showing the state of the switching arm when the sub-slide plate moves in a direction closer to the play pinion from the state shown in FIG. 23E. The side view which shows typically the state of the switching arm when a sub slide plate moves to the direction which approaches a play pinion further from the state shown to FIG. 23F. The top view which shows the positional relationship of the right-and-left slide lifting rack when a raising / lowering base is located in the height according to the tray of the 1st step. The side view which looked at the composition of Drawing 24 from the left slide lifting rack side The side view which looked at the composition of Drawing 24 from the right slide lifting rack side The top view which shows the positional relationship of the right-and-left slide lifting rack when a raising / lowering base is located in the height position according to the lowermost tray. The side view which looked at the structure of FIG. 27 from the left slide lifting rack side 27 is a side view of the configuration of FIG. 27 viewed from the right slide lifting rack side. The perspective view which looked at the structure of FIG. 24 from diagonally upward The perspective view which shows the structure of the conveyance mechanism which conveys a tray from a standby position to an exchange position. Disassembled perspective view of tray drive gear unit The perspective view which shows the positional relationship of a 1st stage tray drive gear and an upper side and a lower plastic ring. The perspective view which shows the state which rotated the 1st stage tray drive gear and the upper side plastic ring from the state shown in FIG. The perspective view which looked at the composition of the 2nd tray drive gear from the slanting upper part The perspective view which looked at the composition of the 2nd stage tray drive gear from the slanting lower part Plan view showing the mechanism for moving the trigger slider The top view which shows the state which the trigger slider moved from the state shown in FIG. The top view which shows the state which the 5th tray lock lever has locked the 5th tray The top view which shows the state which the lock | rock of the 5th tray lock lever and the 5th tray was released The perspective view which looked at the state shown in FIG. 40 from diagonally upward The top view which shows the state which the 3rd tray lock lever has locked the 3rd tray The top view which shows the state from which the lock | rock of the 3rd tray lock lever and the 3rd tray was released The perspective view which looked at the state shown in FIG. 43 from diagonally upward The perspective view which shows the state which conveyed the tray below the 3rd stage to the exchange position. Plan view showing the mechanism for rotating the trigger lever The top view which shows the state which the trigger lever rotated from the state shown in FIG. The top view which shows the state which the raising / lowering cam lock and the right side slide raising / lowering rack engaged when the raising / lowering base is located in the height corresponding to the tray of the 1st step. The top view which shows the state which the raising / lowering cam lock and the right side slide raising / lowering rack engaged when the raising / lowering base is located in the height corresponding to the tray of the 2nd step. The top view which shows the state from which engagement with the raising / lowering cam lock and the right side slide raising / lowering rack disengaged Top view showing the positional relationship between the cam gear and mechanical board unit Perspective view of cam gear viewed from diagonally below The top view which shows the state which the tray drive pin of the load lever removed from the tray groove | channel when a tray is conveyed from a recording / reproducing position to a standby position The top view which shows the state before the drive of a recovery mechanism in the state which the tray drive pin of the load lever removed from the tray groove | channel The top view which shows the state after the drive of a recovery mechanism in the state which the tray drive pin of the load lever removed from the tray groove | channel

DESCRIPTION OF SYMBOLS 1 Disc changer apparatus 2 Apparatus main body 3 Upper cover 4 Case 5 Tray 6 Disc 7 Optical pick-up 8 Turntable 9 Traverse base 10 1st motor 11 1st traverse gear 11 2nd traverse gear 12 Loading gear 13 Feed rack 14A Loading gear 14B Relay gear 15 Swing arm 16 Swing lock 17 Traverse holding case 18 Play pinion 19 Lifting base 20 Traverse slide plate 21 Clamper 22 Magnet 23 Fixing plate 24 Back yoke 25 Clamp plate 26 Sub slide plate 27 Load plate 28 Load lever 29 Switch slider 30 Tray Stopper 31 Second motor 32 Motor pulley 33 Belt 34 Pulley gear 35 Relay gear 3 Switch gear 37 Switch lever 38 Switch arm 39 Lift drive gear 40 Left slide lift rack 41 Connection lever 42 Right slide lift rack 43 Cam gear 44 Shaft body 45 Tray relay gear 46 Slider arm 47 Trigger slider 48 Trigger lever 49 Tray lock lever 50 All trigger Lever 51 Trigger link lever 52 Elevating cam lock 53 Open switching lever 54 Mechanical board unit 55 Pitch plate 60 Projection part 70 Tray drive gear unit 71-75 Tray drive gear 76 Shaft gear 77, 78 Plastic ring T (T1-T5) Tray A1 Disc Recording / playback position A2 Standby position A3 Disc replacement position B1 Disc recording / playback section B2 Standby section

Claims (3)

For transporting the tray between a standby position for storing a plurality of trays and a disc recording / reproducing position capable of recording or reproducing on a disc placed on a tray selected from the plurality of trays. A first motor for generating a driving force and a tray drive gear unit capable of individually transporting each tray are brought into a state where the tray can be simultaneously transported, and the standby position and a disk replacement position where a disk on the tray can be replaced. A disk changer device having a second motor for generating a driving force for conveying the tray between
The tray rack portion for receiving a driving force of the first motors on the side, has a back surface in the guide groove,
The disk changer device includes a drive switching component that receives a driving force from the first motor having a tray driving pin that engages with the guide groove;
A drive lever that is rotated by the driving force of the second motor;
The disk changer device according to claim 1, wherein when the drive lever is disposed at a predetermined position by the second motor, the drive changer abuts against the drive switching component and applies a driving force in a certain direction. A cam gear rotated by the driving force of the second motor;
A slider arm that engages with the cam gear and rotates in conjunction with rotation of the cam gear;
A trigger link lever that is rotatably supported at a position where it can come into contact with the drive switching component,
The trigger link lever has a cam surface, the slider arm has a drive pin that contacts the cam surface, and the drive pin pushes the cam surface by the rotation of the slider arm, and the trigger link 2. The disk changer device according to claim 1, wherein a lever is rotated so as to apply a driving force in a certain direction by contacting the drive switching component. A slide plate that receives the driving force of the first motor;
A load plate that engages with the slide plate and has a movable range other than the drive direction of the slide plate, and rotates around a pin provided on the load plate, and engages with the guide groove on the back surface of the tray. A load lever having the tray drive pin;
The slide plate and constitutes the drive switching component by the load plate and the load lever, the tray driving pin, characterized in that the can operate in a plane, the disc changer apparatus according to claim 1 or 2 wherein.

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