JPH0792974B2 - Disc player - Google Patents

Description

The present invention relates to a disc player, and more particularly to a disc player having a so-called changer function capable of selectively reproducing a plurality of discs, in which a tray and a carriage are integrated or The present invention relates to a control drive mechanism for relatively moving forward.

<Prior Art> A so-called changer type compact disc player capable of accommodating a plurality of discs and reproducing any disc therein has become widespread. Generally, a changer type compact disc player stores a plurality of discs in a stocker that is detachable from a disc reproducing device, and mounts the stocker in the disc reproducing device to selectively reproduce an arbitrary disc. Is configured to be able to.

<Problems to be Solved by the Invention> However, in this conventional changer type disc player, when it is desired to reproduce a disc that is not stored in the stocker, the stocker is once removed from the player and the desired disc is placed in the portion of the stocker where the disc is not mounted. , Or if the disc is fully loaded in the stocker, 1 disc is stored in the stocker.
After pulling out one piece and storing the desired disk in this part,
It is necessary to attach the stocker to the player again,
There was a drawback in its operability.

<Means for Solving the Problems> As a new disc player capable of solving this drawback, the present applicant has mounted a plurality of carriages on which discs can be mounted and one of the plurality of carriages. A tray that can be placed and can take a loading position that is stored in the player body and an eject position that is pulled out from the player body, a stocker that can store the plurality of carriages, the tray, and the tray that is placed on the tray. The carriage can be reciprocated between the loading position and the eject position, and the carriage can be reciprocated between the loading position on the tray in the loading position and the storage position stored in the stocker. A drive mechanism for enabling the carriage mounted on the tray at the loading position at the mounting position A disk player having a disk reproducing means for reproducing the above disk has been proposed (Japanese Patent Application No. 1-219071). The present invention relates to an improvement in a disc player having such a basic configuration, and particularly proposes a drive mechanism that can integrally or relatively move a tray and a carriage forward.

That is, according to the present invention, in the disc player having the above-mentioned basic structure, the disc is provided so as to be movable in the reciprocating direction of the tray and the carriage by the drive source, and
The drive mechanism includes a shuttle including a first engaging portion that is engageable with the engaged portion and a second engaging portion that is engageable with the second engaged portion of the carriage. In the first movement section, the tray is moved between the loading position and the eject position by the engagement of the first engaging portion and the first engaged portion, and the first portion of the shuttle is moved. In the second movement section, the carriage is configured to move between the mounting position and the storage position by the engagement of the second engaging portion and the second engaged portion. To do.

<Operation> At the time of loading the tray, the tray is loaded into the player through the engagement of the first engaging portion of the shuttle and the first engaged portion of the tray as the shuttle moves in the first movement section. Placed in position. When the tray reaches the loading position, these engagements are released, and only the carriage on the tray is moved between the second engagement portion of the shuttle and the second engaged portion of the carriage by the subsequent movement in the second movement section of the shuttle. It is moved through the engagement and stored in the stocker.

<Example> Hereinafter, the present invention will be described in detail based on illustrated examples. In this embodiment, a tray that can be pulled out / stored with respect to the player main body is provided with a carriage on which a disc can be placed and which can be moved in the pulling out / storing direction with respect to the tray. This is a stocker type disc player in which a plurality of carriages (seven in the illustrated example) can be stored and a stocker capable of moving up and down is arranged. With this configuration, a so-called changer function is realized which enables one of a plurality of carriages accommodated in the stocker to reproduce a disc mounted thereon, and a normal single disc CD. As with the player, the tray can be used to load / unload the disc. Regarding the basic configuration of such a stocker type disc player, the applicant's prior application, Japanese Patent Application No. 1-219071.
It is described in the issue.

Referring to FIGS. 1a to 1d and 2a and 2b, a shaft 9 extending along the pulling-out / accommodating direction of the tray 30 is fixed to the side plate 2 of the chassis 1 forming the player main body.
30 is a shaft 9 on a guide member 31 fixed to one side thereof.
Is pierced so that the chassis 1 is supported so as to be able to move forward and backward in the drawing / storing direction. On the other hand, the other end of the tray 30 is fixed with a guide rail 22 extending along the pulling out / storing direction, and the guide rail 22 is fixed to the chassis 1 by a guide piece 14 fixed on the bottom plate 4 of the chassis 1. It is guided so that it can be moved forward and backward in the pull-out / storage direction. Therefore, the tray 30 projects forward from the chassis 1 (player main body) and can be placed on the eject position (second disc).
A) and b) and the loading position where the disc can be played inside the chassis 1 (player main body) (see FIG. 1).
It can be moved forward and backward between b and c) in the withdrawal / storage direction. Referring particularly to FIGS. 8a to 8c, a first arm 15 extending along the pulling / accommodating direction and having a tip on the pulling direction side is integrally formed on the pulling direction side at the upper end of the guide piece 14. On the other hand, on the other hand, the second arm 16 is formed integrally on the storage direction side, the length of which is longer than that of the first arm 15 by a predetermined dimension, and the second arm 16 having a tip on the storage direction side.
The lower end 23 of the guide rail 22 is attached to the tip of each arm.
Upper guide rollers 17 and 18 positioned so as to be in sliding contact with the upper surface side of the bearing are rotatably supported. Further, lower guide rollers 20, 21 positioned so as to be in sliding contact with the lower surface of the lower end portion 23 of the guide rail 22 are rotatably supported by the guide piece 14 at positions substantially below the upper guide rollers 17, 18, and further downward. The guide piece 14 in the upper position of the guide rollers 20, 21 has a flange that can abut against the upper surface side of the lower end portion 23.
27 and 28 are integrally formed. Upper guide roller 17,
The distance between 18 and the lower guide rollers 20, 21 is set to be slightly smaller than the thickness of the guide rail 22 in the normal state of the guide piece 14, while the lower guide rollers 20, 21 and the flange 2
The distance from 7, 28 is set to be slightly larger than the thickness of the guide rail 22. As a result, the lower end portion 23 of the guide rail 22 is pressed and nipped between the upper and lower guide rollers due to the bending of the first and second arms 15 and 16 (Fig. 8d), and the lower guide rollers 20 and 21 are provided. And the flanges 27 and 28 are loosely fitted.

Therefore, rattling of the tray 30 is prevented by the above-mentioned pressure contact pinching action, and in the direction A (Fig. 8e) in the drawing, the upper surface side of the lower end portion 23 of the guide rail 22 abuts on the flange 27, while being shown in the figure. In the B direction (Fig. 8e), the range is restricted until it comes into contact with the flange 28.

Further, in this embodiment, as described above, the first arm 15 is formed shorter than the second arm 16 by a predetermined dimension, and the clamping force of the guide rail 22 by the upper and lower guide rollers is set to the first arm 15 side ( By making the setting stronger on the pull-out direction side), the backlash of the tray 30 can be removed more effectively.

That is, the backlash of the tray 30 is particularly problematic at the eject position, and therefore it is necessary to positively remove the backlash at the eject position. FIG. 8e shows the positional relationship between the guide rail 22 and the guide piece 14 at the eject position of the tray 30. In this state, for example, the operator may move the tray 30 to the front end (the guide rail 22 in the pull-out direction side). When the end portion 22a) of the guide rail 22 is grasped by hand and displaced in the direction A in the drawing, the guide rail 22 is rotated in the direction A around the contact portion P ₁ between the lower end portion 23 and the lower guide roller 21, and conversely. When displaced in the direction B shown in the drawing, the lower end portion 23 and the lower guide roller
It is rotated in the B direction around the contact portion P ₂ with 20. Therefore, at the time of rotation in the direction A, the contact portion P _{1 serving} as a rotation fulcrum.
From the contact point P ₂ to the end 22a as the point of action is larger than the distance from the contact portion P ₂ to the end 22a when rotating in the B direction.
In order to regulate the displacement of 30 and to make the rigidity to the backlash equal in both directions, it is necessary to make the regulation force when rotating in the A direction stronger than in the B direction. On the other hand, when the guide rail 22 is rotated in the direction A shown in the figure, the pressure contact force of the upper roller 17 mainly due to the bending of the first arm 15 acts as a displacement regulating force, and conversely, the guide rail 22 is rotated in the direction B shown in the figure. At times, the pressure contact force of the upper roller 18, which is mainly due to the bending of the second arm 16, acts as a displacement regulating force.

Therefore, in this embodiment, the first arm 15 and the second arm 15
By configuring the arm 16 of the above as described above and setting the pressure contact force of the guide rail 22 on the side of the first arm 15 to be stronger than that on the side of the second arm 16, not only the rigidity of the tray 30 against rattling can be sufficiently increased. Instead, it is possible to make them equal in the directions A and B in the drawing.

In the embodiment described above, the first arm 15 and the second arm 16 are configured as described above in order to make the rigidity of the tray 30 equal regardless of its directionality (direction A and B in the drawing). The pressure contact pinching force of the guide rail 22 as the entire guide piece 14 is set to be relatively large. For this reason, it is conceivable that the load applied to the tray drive system, which will be described later, becomes relatively large when the tray 30 moves due to the guide rails 22 being guided by the guide pieces 14. Therefore, when the load on the tray drive system is preferentially reduced, the length of the first arm 15 is made equal to that of the second arm 16 and the pressure contact pinching force is set to be relatively small. Good. Even in this case, the guide piece 14 prevents the backlash of the tray 30. Thus, in the tray 30, the guide rail 22 has the guide piece 14
While being pressed and sandwiched between the upper guide rollers 17 and 18 and the lower guide rollers 20 and 21, they can be moved with respect to the chassis 1 in the drawing / storing direction.

The tray 30 is movable in the pull-out / retracting direction between the loading position and the eject position as described above, and the carriage 40 is always placed during the movement between the loading position and the eject position. . On the other hand, the carriage 40 is provided so as to move forward with respect to the tray 30 so as to move together with the tray 30 and further move further away from the tray 30 at the loading position and stored further in the stocker 90. As a driving means for the tray 30 and the carriage 40, a shuttle 50 that moves in the pulling / accommodating direction of the tray 30 by a wire 60 is used.

With particular reference to FIGS. 9a-9c below, the wire 60 is
It is wound between a drive pulley 61 and a driven pulley 62 on the side plate 2 side of the chassis 1. The drive pulley 61 is rotatably driven at an arbitrary speed by a motor 63 that is axially supported by the side plate 2 and is connected to a drive circuit 631 via a gear device 64. Shuttle 50
Are fixed to both ends of the wire 60. On the outer side surface of the shuttle 50, the lower end of the guide rail 24 fixedly attached to the inner side surface of the side plate 2 over substantially the entire length thereof is bent inward in the pulling out / storing direction of the tray 30. A groove 52 for receiving the horizontal rail 25 extending along the groove is formed, and the shuttle 50 is configured to be horizontally moved as the wire 60 is driven to rotate. The horizontal rail 25 extends horizontally along the inner surface of the side plate 2 over substantially the entire length thereof (Fig. 9b).

A tray lock arm 70 is pivotally supported by a pivot pin 56 penetrating the upright portion 54 of the shuttle 50, and a carriage lock arm 80 is fixed to the upright portion 54. The tray lock arm 70 is formed with a locking groove 72 capable of locking the lock pin 32 protruding outward from the side surface of the tray 30, and
A guide pin 74 is formed to be engaged with the guide groove 26 formed on the upper inner surface side of the guide rail 24. The guide groove 26 extends along the inner side surface of the side plate 2 over substantially the entire length thereof,
A first horizontal portion 26a that extends horizontally in the drawer / storing direction of the tray 30 in front of it, and a second horizontal portion 26c that extends a level that is slightly lower than the first horizontal portion 26a behind it horizontally. It is constituted by a bent portion 26b connecting the first and second horizontal portions (9th portion).
Figure b).

Before describing the carriage lock arm 80, the construction of the carriage 40 itself and the construction of the tray 30 in a portion related to the carriage 40 will be described with reference to FIGS. 12a to 12c and 1a to 1d. However, to explain, a disk mounting portion 41 for mounting a disk is formed on the upper surface of the carriage, and projections 42a to 42d for restricting the position of the disk mounted on the disk mounting portion are formed. . On the other hand, when the carriage 40 is placed on the tray 30, the top plate 301 of the tray 30 facing the disc placing portion 41 has an opening 302 having substantially the same shape as the disc placing portion 41. Further, on the lower surface side of the top plate 301 facing the protrusions 42a to 42d, a protrusion is formed when the carriage 40 moves forward with respect to the tray 30.
Concave grooves 303a to 303d that allow the movement of 42a to 42d are formed to extend along the tray 30 withdrawing / accommodating direction. On the underside of the carriage, a pair of ridge rails 43a, 43b;
d is formed to extend along the pull-out / accommodation direction, and when a plurality of carriages are stacked, concave grooves 431; 432 formed between the pair of protruding rails 43a and 43b; 43c and 43d on the lower surface of the upper carriage, respectively. Projections 42a and 42b; 42c and 42d on the upper surface of the lower carriage are received therein. Near the front end of the upper surface of the carriage 40, a lock spring with a downward bias attached near the front end on the lower surface side of the tray 30 top plate 301.
A pair of recesses 49a, 4 into which 39a, 39b (FIGS. 9A to 9C) can be engaged.
9b is formed. Further, on the upper surface of the bottom plate 304 of the tray 30, there is formed a pair of projecting rails 35a and 35b which are slidably fitted into the concave grooves 431 and 432 formed on the lower surface of the carriage 40 (FIGS. 9A to 9C). 9 c).

The carriage 40 in this example has a 12 cm disc mounting portion 41a and a slightly lower level than the disc mounting portion 41 so that two types of discs of different sizes currently on the market can be mounted. It is composed of an 8 cm disc mounting portion 41b. A through hole 48 is formed in the 8 cm disk mounting portion 41b, and a through hole 308 is formed in the bottom plate 304 facing the same. Reference numerals 44 and 306 are openings formed in the carriage 40 and the tray bottom plate 304, respectively, in order to allow the optical reading mechanism for reproduction to access the disc placed on the disc placing portion 41. A concave portion 45 into which the front end portion 82 of the carriage lock arm 80 can be engaged is cut out near the front end on one side of the carriage 40. The front and rear ends of the carriage 40 are tapered in order to facilitate storage in a stocker 90 described later. Further, a notch 46 that can be engaged with a spring 92 described later is formed in the vicinity of the rear end of the carriage 40.

Referring again to FIGS. 9a to 9c, the carriage lock arm 80 will be described. The carriage lock arm 80 is an elongated plate-like member extending over substantially the entire length of the tray 30, and the front end thereof. The front end portion 82 which can be engaged with the concave portion 45 at the front end of the carriage 40 is formed by standing up from above and further bending inward. Here, the dimension of the tip end portion 82 in the pulling out / accommodating direction is set smaller than the dimension of the recessed portion 45 in the same direction, and both are configured so that they can be engaged / disengaged. At the loading position of the tray 30 shown in FIG. 9C, one end portion 82a of the leading end portion 82 on the pull-out direction side is engaged with the pull-out direction side wall portion 45a of the recess 45. Further, at the front end of the carriage lock arm 80, a guide pin 84 that can be engaged with the guide groove 34 that is formed on the inner side surface of the tray 30 and extends along the pulling / accommodating direction is formed to project inward.

The tray 30 on which the carriage 40 is now placed is shown in FIGS.
The loading position shown in Figures c and 9a-9c,
That is, the tray 30 is housed in the player body and the carriage is
It is assumed that recording / playback is possible with respect to the disc above 40. From this loading position, the carriage 40
The tray 30 may be used to replace a disc mounted on it with another disc or to mount a new disc to be played on a carriage 40 on which no disc is mounted.
2a and 2a together with the carriage 40 mounted on it
When attempting to move to the eject position shown in FIG. B, the shuttle 50 is advanced in the direction of the drive pulley 61 by driving the wire 60 to rotate counterclockwise in the drawing. shuttle
While the shuttle 50 is moved horizontally to the frontmost position (eject position) by the engagement of the groove 52 of the guide rail 50 and the horizontal rail 25 of the guide rail 24, the tray 30 remains in the state in which the carriage 40 is placed. The lock pin 32 and the locking groove 72 of the tray lock arm 70 are engaged with each other to move in the same direction. As described above with reference to FIGS. 8a to 8e, the movement of the tray 30 is performed in a strict horizontal direction by pressing and sandwiching the guide rail 22 between the guide rollers 17, 20; 18, 21 on one side thereof. You are promised to move and the rattling is effectively prevented. During movement of the tray 30 from the loading position to the eject position, the guide pin 74 protruding from the tray lock arm 70 is always in the first horizontal portion of the guide groove 26.
Since the tray lock arm 70 is fitted in the tray 26a, the illustrated rotation angle of the tray lock arm 70 is maintained, so that the lock pin 32 does not separate from the locking groove 72 and the driving force associated with the movement of the shuttle 50 is effectively used. Can be transmitted to. The carriage 40 moves integrally with the tray 30 because the lock springs 39a and 39b are engaged in the recesses 49a and 49b. At this time, the carriage lock arm 80 is also moved integrally with the tray 30 and the carriage 40 by the shuttle 50. However, the carriage lock arm 80 is in the pull-out direction side of the tip end portion 82 of the carriage lock arm 80 during movement and at the stop position (eject position). Side edge
82a is kept engaged with the wall portion 45a of the recess 45.

Since the movement of the tray 30 from the eject position to the loading position is performed only in the opposite direction in the same manner as described above, the description thereof will be omitted. As shown in FIGS. 1a and 2b, a switch SW4 for detecting the arrival of the tray 30 at the loading position is provided at a position on the chassis 1 corresponding to the end of the tray 30 on the storage direction side. It is provided. The output of the switch SW4 is connected to the control circuit 6 (FIG. 19) described later.

When the disk on the carriage 40 placed on the tray 30 in the loading position is to be stored in the empty space in the stocker 90, the shuttle 50 is moved from the intermediate position (loading position) shown in FIG. Move horizontally in the direction of. When the shuttle 50 is moved slightly from the position shown in FIG. 9B in the storage direction, the guide pin 74 located at the end of the first horizontal portion 26a in the guide groove 26 is bent at the bent portion 2.
Then, the tray lock arm 70 rotates about the pin 56 in the counterclockwise direction in the drawing. As a result, as shown in FIG. 14a, the lock pin 32 is locked in the locking groove.
The tray 30 is released, and the tray 30 is unlocked.
Therefore, even if the shuttle 50 moves from the intermediate position in FIG. 9b to the right in the drawing, the tray 30 remains in the loading position, and the carriage lock arm 80 is moved together with the shuttle 50.
Through the engagement between the front end 82 of the
B), and only the carriage 40 is further moved to the right in the drawing against the biasing force of the carriage regulating springs 39a and 39b. That is, by the movement of the shuttle 50 in the storage direction when the guide pin 74 passes through the bent portion 26b of the guide groove 26, first, the side end 82b of the tip end portion 82 on the storage direction side is the wall portion of the recess 45 on the storage direction side. The lock springs 39a, 39b are disengaged from the recesses 49a, 49b by being engaged with 45b and then moving the carriage 40 in the storage direction. This allows the carriage 40
Is free to move to tray 30 and shuttle
As the 50 moves in the storage direction, it moves in the same direction. After that, when the shuttle 50 is moved to the rearmost position (storage position) shown in FIGS. 3A and 3B, the carriage 40
Are stored in an empty space in the stocker 90 (the lowest stage in the illustrated example). While the shuttle 50 is moving as described above, the carriage
The recessed grooves 431, 432 are guided by the ridge rails 35a, 35b provided on the tray 30, so that the 40 is moved while being held in a strict horizontal state and stored in the stocker 90.

Further, since the tray lock arm 70 is moved with the guide pin 74 thereof fitted in the second horizontal portion 26c of the guide groove 26, the rotation angle shown in FIGS. Retained.

Thus, the state where the carriage 40 is completely stored in the lowermost stage of the stocker 90 is shown in FIGS. 3a and 3b.
In particular, as is apparent from FIG. 3B, in this state, the tip end portion 82 of the carriage lock arm 80 is inserted into the front end concave portion 45 of the carriage 40, but is held in non-contact with the carriage 40 itself. This is the front end recess as described above.
The respective dimensions (length in the pulling out / storing direction) are determined so that the tip end portion 82 is loosely fitted to the 45, and the carriage 40 is moved to the stocker 90 by the spring 92 provided at the rear side corner portion of the stocker 90. Achieved by being configured to be retracted within 90. That is, when the shuttle 50 approaches the driven pulley 62, the inward bulging portion of the spring 92 is pushed outward by the rear end of the carriage 40, and the portion 47 (FIG. 12c) near the notch 46 is spring-loaded. At the moment when the vehicle gets over the apex of 92 (at which time the shuttle 50 reaches the end position), the spring 92 elastically returns and its inward bulge is engaged in the notch 46 (Fig. 13). By the action of 92, the carriage 40 is further retracted slightly in the storage direction, the engagement between the carriage lock arm tip portion 82 and the carriage recess 45 is released, and the carriage 40 is locked at the storage position in the stocker. The spring 92 is provided with a plurality of stages of inward bulging portions arranged in parallel according to the number of stages of the carriage 40 accommodated in the stocker 90. Since the carriage 40 is held freely with respect to the shuttle 50 in the state of being stored in the stocker 90, a smooth vertical movement is guaranteed.

When moving the carriage 40 stored in the stocker 90 onto the tray 30 in the loading position, the shuttle 50 is moved in the opposite direction. That is, when the wire 60 is driven counterclockwise by the motor 63 and the shuttle 50 is moved in the pulling-out direction from the state shown in FIGS. 3A and 3B, the side end of the carriage lock arm 80 at the tip end portion 82 thereof. 82a is engaged with the wall 45a of the recess 45, and the carriage 40 is moved in the pull-out direction. And FIG. 9a
~ Tray 30 in loading position shown in Figure 9c
When the carriage 40 is moved to the position, the lock springs 39a and 39b are re-engaged in the recesses 49a and 49b of the carriage 40, and the carriage 40 is locked to the tray 30. On the other hand, immediately after the position shown in FIGS. 14a and 14b, the lock pin 32 is housed in the locking groove 72, and the guide pin 74 is guided to the bent portion 26b to show the tray lock arm 70. The tray 30 is rotated clockwise to lock the tray 30 at the rotational angle positions shown in FIGS. 9a to 9c.

In this embodiment, the shuttle 50 is attached to the wire 60 as shown in FIGS. 11a and 11b. Drive pulley 61 of wire 60 formed by first clamper 65a
A first ring-shaped end 66a extending from the first ring-shaped end 66a is locked to a first locking portion 59a formed on the driven pulley 62 side of a locking member 58 fixed inside the shuttle 50, and a second clamper 65b. The second extending from the driven pulley 62 of the formed wire 60
The ring-shaped end 66b of the second locking portion 5
Locked to 9b. Therefore, the wire 60 is locked inside the shuttle 50 by the locking member 53 in a state where it crosses in a substantially X shape, and the first and second ring-shaped ends 66a, 66b and the first and second clampers 65a. 65b and the tension spring 67 are both arranged inside the shuttle 50 and have no portions projecting from both ends thereof. Further, as shown in FIGS. 11c and 11d, in the horizontal rail 25 for guiding the shuttle 50 in the pulling out / storing direction, the locking member 58 has the driving pulley 61 and the driven pulley 62 while the shuttle 50 is moving. Is arranged above both pulleys 61 and 62 so as to pass above. Therefore, as shown in FIGS. 11c and 11d, the shuttle 50 can move to a position substantially directly above the drive pulley 61 and the driven pulley 62. Thus, the travel stroke of the shuttle 50 can be sufficiently taken, and it is not necessary to take up more space than necessary for the arrangement of the shuttle drive mechanism.

The structure of the stocker 90 capable of accommodating a plurality of carriages 40 will be described with reference to FIGS. 10a to 10e. The stocker 90 shown in FIGS. 10a and 10b is in the most raised position, and when the stocker is in this position, the carriage 40 can be stored in the lowermost stage of the stocker or the lowermost stage thereof. The carriage can be pulled out. In the present embodiment, the bottom carriage is used in the single mode like the single disc CD player,
Detection switch SW for detecting the highest lifted position of stocker 90
1 is provided. On the bottom plate 4 of the chassis 1, a gear 94 that is rotationally driven by a stocker drive motor 93 connected to a drive circuit 931 is arranged, and a screw rod 95 that rotates integrally therewith is attached coaxially to the gear 94. Meanwhile, the bottom plate of the stocker 90
A nut 96, which is screwed with the screw rod 95, is attached to 901 so that its shaft is coaxial with the central hole 101 of the disk 100 on the carriage 40 housed in the stocker 90. Screw rod 9
5 is designed to have a slightly smaller diameter so that it can be inserted into the disk center hole 101. The lead of the screw rod 95 is set so as to move the stocker 90 up or down by one step, that is, by one carriage, every approximately half rotation. A spring 98 is wound around the screw rod 95 in a compressed state to constantly urge the stocker 90 upward. Further, the stocker 90 is stably supported on both sides thereof in a horizontal state by the pantograph type supporting mechanism 97.

In the above configuration, when the gear 94 is rotated counterclockwise in the drawing, the stocker 90 gradually descends against the spring 98 by the screw engagement of the screw rod 95 and the nut 96 that rotate integrally with the gear 94, and with this. The pantograph 97 gradually contracts. A pair of cutouts 116 are formed opposite to each other at the peripheral end of the rotary plate 115 fixed on the gear 94, and the detection element 117 provided on the bottom plate 4 is formed in the cutout 1.
16 is detected approximately every half rotation of the gear 94. In response to the rising of the output signal S117 from the detection element 117, the motor 93 is stopped after applying a negative drive voltage for reversely rotating the motor 93 for a predetermined short time (FIG. 15). By repeating this operation, the stocker 90 is lowered from the highest position (position 0) to the lowest position (position 6) (Fig. 10e). When pulling out the carriage 40 stored in a certain stage of the stocker 90 or storing the carriage 40 in a certain stage, the amount corresponding to the difference between the stage at the position where the stocker 90 can be pulled out / stored and the designated stage. The stocker 90 may be stopped in response to the rising edge of the output signal S117 from the detection element 117. The drive control of the motor 93 for moving the stocker 90 up and down is performed by the control circuit 6 which receives the signals from the detection element 117 and the switch SW1 and outputs the up signal S61 or the down signal S62 according to the detection result. The controlled drive voltage S931 is applied to the motor 93 from the drive circuit 931 (FIG. 19). During the raising / lowering operation of the stocker 90 described above, the screw bar 95
Center hole 1 for disc 100 on carriage 40 housed inside
It is inserted in 01 without contact.

The nut 96 has a small-diameter portion 961 fitted into a hole 902 formed in the bottom plate 901 of the stocker 90, and the bottom plate 901 has large-diameter portions 962 and 963 integrally and vertically formed above and below the small-diameter portion 961.
It is rotatably attached to the bottom plate 901 in a state of sandwiching. Then, the protrusion 965 provided at the tip of the extension portion 964 of the large diameter portion 963 on the lower side is configured to be engageable with any one of the plurality of holes 903 formed concentrically on the stocker bottom plate 901 over a substantially half circumference. (Fig. 10c). Protrusion 9 in any of holes 903
Since the rotation angle of the nut 96 changes depending on whether the nut 65 is engaged, the height position of the stocker 90 can be finely adjusted.

As shown in FIGS. 1a to 1d, the guide member 31 fixed to one end of the tray 30 is formed with an extension portion 310, while the side plate 2 of the chassis 1 is provided with the extension member shown in FIGS. At the eject position of the tray 30 shown in FIG. 2b, the switch SW5 that is turned on by the extension portion 310 is fixed. Further, on the bottom plate 304 of the tray 30, in the state where the carriage 40 is placed, the disk placing portion 41 of the carriage, particularly 8 cm.
A through hole 308 corresponding to the through hole 48 formed in the disk mounting portion 41b is formed. On the other hand, as will be described later, the support plate 170 (FIGS. 4A to 4C) provided on the bottom plate 4 of the chassis 1 has through holes 308 in the tray 30 at the loading position.
Further, the reflection type detection element 110 is fixedly arranged at a position aligned with the through hole 48 of the carriage 40 placed on the tray. Tray 30 and carriage in loading position
When the disc 100 is placed on the 40, the detection element 110
The light emitted from the laser beam passes through the through holes 308 and 48 and reaches the back surface of the disk 100, and the reflected light passes through these through holes and is detected by the detection element, whereby the existence of the disk is confirmed. The presence / absence of the disc thus detected is displayed on the player display (not shown).

The detection element 110 has a function of detecting the presence or absence of a disc in a reproducible state in cooperation with the through holes 308 and 48 as described above, and further, the tray 30 when the tray 30 is pulled out from the loading position to the eject position. It is used as a timing sensor for detecting the intermediate position and decelerating the subsequent drawing movement speed. A reflecting member 37 such as silver paper is attached to the lower surface of the bottom plate 304 at the rear end of the tray 30 on the same straight line as the through hole 308 in the tray pull-out / accommodation direction. As mentioned above, tray lock arm 70
The engagement of the lock groove 72 and the lock pin 32 of the shuttle 50
When the tray 30 is pulled out to a substantially intermediate position between the loading position and the eject position in the tray pull-out movement that is performed in association with the movement of
The position immediately above is reached and the position is detected by the detection element 110. As shown in the timing chart of FIG. 16, after the fall of the detection signal from the detection element 110,
By controlling the drive voltage S631 to be supplied to the motor 63 in a pulsed manner, the subsequent tray withdrawing speed is gradually reduced. When the tray 30 reaches the eject position, the switch SW5 is pushed by the extension portion 310 of the guide member 31 to be turned on, and the motor 63 is stopped in response to this. As shown in FIG. 19, the control of the motor 63 is performed by the control circuit 6 which receives the outputs S110 and S5 from the detection element 110 and the switch SW5, and outputs the up signal S63 corresponding to the detection results.
Alternatively, the down signal S64 is sent to the drive circuit 631, and the drive voltage S631 thus controlled is applied to the motor 63 from the drive circuit 631.

As shown in FIGS. 4a to 4c, a mechanical unit 120 (hereinafter referred to as a mechanical unit 120) on which an optical head 113 for reproducing digital information recorded on a disc, a turntable 111, and the like is mounted, Tray 30 in loading position
Is arranged on the chassis 1 so as to be able to move up and down. On the other hand, a clamper 112 is rotatably arranged above the tray 30 facing the turntable 111 while sandwiching the tray 30. The clamper 112 is rotatably supported by a substantially U-shaped clamp arm 5 whose both ends are fixed between the side plates 2 and 3 of the chassis 1 (FIGS. 1a and 1d). The raising and lowering drive with respect to C is performed by a pair of support plates 170 and 180 provided on the bottom plate 4 of the chassis 1 as shown in FIG.
A pair of slide plates 150 slidably supported in the D direction,
Done through 160. That is, a pair of pins 121 and 122 protruding from both sides of the mechanical unit 120 are formed in the support plate 170; 180 in a vertical direction, and a pair of guide grooves 171, 172; 181, 18 respectively.
2 (not shown) and slide plates 150 and 160
In the respective cam grooves 151,152; 161,162 in
As the slide plate moves, the pins are guided along the cam grooves, so that the mechanical unit 120 is moved in the vertical direction. The state where the mechanical unit 120 stands by at the lowered position (standby position) is shown in FIGS. 4a to 4c, and the state where the disk reproduction is possible at the raised position (mounting position) is the fifth state.
This is shown in Figures a and 5b.

The cam grooves 151 and 152 of the slide plate 150 are formed in opposite directions to the cam grooves 161 and 162 of the slide plate 160. Hereinafter, the cam groove will be described with respect to one slide plate 150. The cam grooves 151 and 152 are the moving directions of the slide plates (C-in the figure).
Slanted portions 151b and 152b inclined with respect to the D direction), first horizontal portions 151a and 152a continuous to the lower ends of the slanted portions 151b and 152b and parallel to the moving direction, and continuous to the upper ends of the slanted portions 151b and 152b, the moving direction A second horizontal portion 151c, 152c parallel to the. The slide plates 150 and 160 are connected to each other by an arm 128 that is rotatable around a pivot pin 127 that is planted on the bottom plate 4.

A rack 155 extending along the CD direction in the drawing is formed at the lower end of one slide plate 150, and a pinion 125 that meshes with the rack 155 is provided on the bottom plate 4. Also, the bottom plate 4
Is provided with a motor 123 connected to a motor drive circuit 1231 and the pinion 125 is connected to the motor 123 via a gear device 124.
Connected to.

Therefore, when the motor 123 is rotated in the predetermined direction and the slide plate 150 is slid in the direction D in the drawing in the lowered position of the mechanical unit 120 shown in FIGS. 4A to 4C, the arm 128 moves counterclockwise. The other slide plate 160 is rotated and translated in the direction C in the figure at the same speed. As a result, in the mechanical unit 120, the pins 121 and 122 of the mechanical unit 120 are both slide plates 150: 160.
Guided by the cam grooves 151, 152; 161, 162 of the above, and moved up in parallel with the bottom plate 4, the raised position (disc clamp position) shown in FIGS. 5a and 5b is obtained.

In the lowered position shown in Fig. 4a, the mechanical unit is
The pins 121 and 122 of the 120 are the first horizontal portions 151 of the cam grooves 151 and 152.
In the raised position shown in FIG. 5a, the locking is carried out at approximately the midpoints of the a and 152a, and at the approximately midway of the second horizontal parts 151c and 152c. A tray lock arm 130 is rotatably supported on a horizontal plane at the upper end of the support plate 170 supporting the slide plate 150 in the direction C in the drawing. The tray lock arm 130 has an operating pin 1 that can come into contact with a notch 158 formed in the upper end of the slide plate 150 on the C direction side in the figure.
38 is provided, and the position of the stopper pin 137 is regulated in a state of being urged counterclockwise in the drawing by the spring 131 and the stopper pin 137 thereof being in contact with the support plate 170. Further, a roller 132 is rotatably installed at the tip of the roller so as to face the lower surface of the tray 30. The roller 132 engages with the rib 38 formed on the lower surface of the tray 30 so that the tray
30 is held in a locked state with respect to the mechanical unit 120 (chassis 1). (FIG. 4c, FIG. 5b) Also, the support plate 17
0 and the bottom plate 4 include a slide plate 150 and a mechanical unit 120.
Switches SW2 and SW3 for detecting the position of are provided.

The switch SW2 is provided on the support plate 170 and is a slide plate 150.
Is attached to a position where it can face the notch 154 formed in the upper surface 153, and pins 121 and 122 are positioned approximately in the middle of the second horizontal portions 151c and 152c of the cam grooves 151 and 152, as shown in FIG. 5a. While the mechanical unit 120 is in the raised position, the slide plate 150 is moved in the direction C in the figure and the mechanical unit 120 is being moved downward, and the mechanical unit 120 opposes the notch 154 to be in the OFF state. Then, as shown in FIG. 4A, the pins 121 and 122 are connected to the first horizontal portion 151 of the cam grooves 151 and 152.
When the mechanical unit 120 is located at a substantially midway portion of the a and 152a and is in the lowered position, the mechanical unit 120 comes into contact with the upper surface 153 of the slide plate 150 to be in the ON state.

On the other hand, the switch SW3 has a slide plate 150 on the bottom plate 4.
The pin is attached at a position facing the notch 157 formed in the lower end extension 156 of the pin, as shown in FIGS. 5a and 5b.
In the state where the mechanical units 120 are in the ascending position with the 121 and 122 positioned substantially in the middle of the second horizontal portions 151c and 152c of the cam grooves 151 and 152, the wall 157a of the cutout 157 on the C direction side in the figure.
It comes into contact with and turns on. In addition, the slide plate 150 is shown in FIG.
When the pins 121 and 122 are moved further from the position shown in FIG. 4c in the direction C, the first horizontal portions 151a and 152a of the cam grooves 151 and 152 are formed.
At the positions shown in FIGS. 6a and 6b where the end portions 151a ', 152a' of the notch 157 are brought into contact with the wall 157b of the notch 157 on the D direction side in the figure, the contact is turned on. And notches at other positions
It turns off in opposition to 157.

As shown in FIG. 19, the output S2 of the switches SW2 and SW3 is
And S3 are connected to the control circuit 6, and the control circuit 6 outputs a control signal to the motor drive circuits 1231 and 631 based on the operation described in detail below.

The operation will be described below with reference to FIG. 17 as well. When the mechanical unit 120 is at the raised position shown in FIGS. Control circuit 6 sets the down signal S66 to the "H" state, and the motor drive circuit 123
The motor 123 is driven by setting the driving voltage S1231 of 1 to a negative output. As a result, the slide plate 150 is moved in the direction C in the drawing and the slide plate 160 is moved in the direction D in the drawing at the same speed. Since the slides 150 and 160 are substantially symmetrical in configuration and operation, only one slide plate 150 will be described below. The slide plates 150 are locked to the second horizontal portions 151c and 152c of the pair of cam grooves 151 and 152 formed in the slide plate 150. The pins 121 and 122 are guided along the inclined portions 151b and 152b of the cam grooves 151 and 152 with the movement of the slide plate 150 in the direction C in the figure, and the mechanical unit 120 is moved downward. In the initial stage of the movement of the slide plate 150 in the direction C in the drawing, the pins 121 and 122 pass through the second horizontal portions 151c and 152c,
Switch SW3 and notch 15
The contact with the wall 157a of 7 is released, and the output S3 of the switch SW3 becomes OF.
It becomes F state. When the pins 121 and 122 reach the first horizontal portions 151a and 152a of the cam grooves 151 and 152, the mechanical unit 120 moves to the fourth position.
It assumes the lowered position shown in Figures a-4c. In this lowered position, the switch SW2 leaves the notch 154 formed in the upper surface 153 of the slide plate 150 and comes into contact with the upper surface 153, so that the output S2 thereof is turned on. Tray in this position
30 is still locked, but slide plate
The notch 158 in 121 is the operating pin 138 of the tray lock arm 130.
Has come close to.

The slide plate 150 is further moved in this direction from this position in the direction C of the drawing until the pins 121 and 122 come into contact with the ends 151a 'and 152a' of the first horizontal portions 151a and 152a, and the lock shown in FIGS. 6a and 6b is reached. It is in the release position. Due to the movement during this time, the notch 15
Tray lock arm through engagement between 8 and actuating pin 138
130 is rotated clockwise in the drawing against the biasing force of the spring 131, and the engagement between the roller 132 and the rib 38 is released. Thus, the locked state of the tray 30 with respect to the mechanical unit 120 (chassis 1) is released, and the shuttle 50 can be moved to the eject position as described above. Slide plate
When 150 reaches the unlocked position, the switch SW3 comes into contact with the wall 157b of the cutout 157, and the output S3 thereof is turned on again. When the output S3 of the switch SW3 is in the ON state, the control circuit 6 sets the down signal S66 to the “L” state, and the motor drive circuit 123
The drive voltage S1231 of 1 is set to zero, the motor 123 is stopped, and the slide plate 150 is stopped at the unlock position. Further, when the output S3 of the switch SW3 is in the ON state, the control circuit 6 sets the eject signal S63 in the "H" state and causes the drive voltage S631 of the motor drive circuit 631 to be a negative output. As a result, the pulley drive motor 63 is rotated, and the tray 30 is moved in the eject direction via the shuttle 50.

In the illustrated embodiment, the control circuit 6 controls the output S3 of the switch SW to be in the ON state again, that is, the slide plate 150 reaches the unlocked position for a predetermined time, for example, 100 mse.
After c, the up signal S65 is set to the "H" state, and the motor drive circuit 12
The drive voltage S1231 of 31 is made a positive output, and the slide plate 150
Is moved in the direction D in the figure. The slide plate 150 is shown in Fig. 4a,
Moved to the position shown in Figure 4c, switch SW3 is notched 1
When the output S3 is turned off again by separating from the wall 157b of 57, the control circuit 6 sets the up signal S65 to the "L" state, sets the drive voltage S1231 of the motor drive circuit 1231 to zero, and sets the slide plate 150 to the fourth position. Stop at the position shown in Figure a. Thus, as shown in FIG. 7, the tray lock arm 130 has the stopper pin 137 supported by the support plate 170 by the urging force of the spring 131.
It is rotated counterclockwise in the drawing until it is engaged with, and is held in a standby state so that the ribs 38 of the tray 30 loaded from the eject position are automatically locked by the rollers 132. That is, when the loading switch is pressed at the eject position of the tray 30 shown in FIGS. 2a and 2b, the control circuit 6 sets the loading signal S64 to the "H" state, and the drive voltage S631 of the motor drive circuit 631 is increased. Let it be output. As a result, the pulley drive motor 63 is rotated,
The tray 30 is moved in the loading direction via the shuttle 50. Then, the tray 30 is moved to the loading position shown in FIGS. 1b and 1c, and the switch SW4 is turned off.
In the N state, the control circuit 6 sets the loading signal S64 to the "L" state, sets the drive voltage S631 of the motor drive circuit 631 to zero, and stops the tray 30 at the loading position. When the tray 30 is moved to the position shown in FIG. 7 during the movement of the tray 30 and is further moved in the storing direction, the tray lock arm 130 causes the roller 132 to abut on the rib 38 so that the spring is moved. When the tray 132 is rotated clockwise against the urging force of the 131 and the roller 132 is engaged with the concave portion of the rib 38 in the loading position of the tray 30 shown in FIG. 4c, the tray 30 is automatically moved to the loading position. Locked. Therefore, according to this embodiment, the tray 30 is locked in the loading position at the same time when it reaches the loading position.

Unlike the above-described embodiment, the slide lock 150 is released from the lock on the tray 30 to be in the unlocked state shown in FIGS.
It is also possible to arrange so that the position of is maintained in this state. In this case, as shown in the timing chart of FIG. 18, the control circuit 6 turns on the output S3 of the switch SW3 at the positions shown in FIGS. 6a and 6b in the same manner as the above-described embodiment.
In this state, the down signal S66 is set to "L" and the drive voltage S1231 of the motor drive circuit 1231 is set to zero. However, the down signal is kept until the loading switch is pressed and the tray 30 is moved to the loading position. Keep S66 in "L" state. Then, at the time of loading, the control circuit 6
Turns the output S4 of the switch SW4 to the ON state to stop the tray 30 at the loading position by setting the loading position S64 to the “L” state, sets the up signal S65 to the “H” state, and sets the drive voltage S1231 of the motor drive circuit 1231 to the drive voltage S1231. A positive output is made and the slide plate 150 is moved in the direction D in the figure. When the slide plate 150 is moved to the position shown in FIGS. 4a and 4c, the switch SW3 is separated from the wall 157b of the cutout 157, and the output S3 thereof is turned off again, the control circuit 6 outputs the up signal S65. Set to "L" state and drive voltage S of motor drive circuit 1231
The slide plate 150 is stopped at the position shown in FIG. Therefore, even with this configuration, the tray
The 30 can be locked in the loading position.

<Effect of the Invention> According to the present invention, the reciprocating movement between the loading position and the ejecting position of the tray and the reciprocating movement between the tray mounting position of the carriage and the storage position in the stocker reciprocate a single shuttle. Since it can be achieved by doing so, the structure is simple and the operability is excellent.

[Brief description of drawings]

1a to 1d show the structure of a compact disc player to which a preferred embodiment of the present invention is applied, in which the tray is in the loading position and the mechanical unit is in the standby position. The front view, the side view, the plan view and the sectional view taken along the line aa in FIG. 1c, FIG. 2a and FIG. 2b are the side view and the plan view showing the state in which the tray is in the eject position, FIG. FIG. 3b is a side view and a plan view showing a state where all the carriages are stored in the stocker, and FIGS. 4a to 4c are side views showing the lifting device especially when the mechanical unit is in the standby position. Figure, front view and plan view, Figure 5a and Figure 5b are side and plan views showing the lifting device especially when the mechanical unit is in the operating position, and Figures 6a and 6b are trays. In the locking device against FIG. 7 is a side view and a plan view showing a state in which the lock for the tray is released, FIG. 7 is a plan view showing a state in which the lock device for the tray has returned to the lock standby position, and FIGS. 8a to 8e are tray loading devices. FIG. 2 is an enlarged view of the details of FIG.
Is a sectional view taken along line b-b in FIG. A, FIG. C is a sectional view taken along line c-c in FIG. A, and FIG. D is a sectional view showing a part of FIG. FIG. E is a sectional view similar to FIG. B showing a state where the tray is pulled out to the eject position, and FIGS. 9a to 9c are enlarged partial front views showing details of the drive mechanism of the tray and the carriage by the shuttle, Side view and plan view, FIGS. 10a to 10e show the details of the stocker and its lifting device, and FIGS. A to d show the front view, the side view, and the state in which the stocker is at the highest position. D- in the plan view and FIG.
FIG. 11d is a sectional view similar to FIG. 11d when the stocker is at the lowest position, and FIGS. 11a to 11d are enlarged side views showing shuttle-related parts in the drive mechanism of the tray and the carriage. 12a to 12c are front views showing the structure of the carriage,
FIG. 13 is a side perspective view and a plan view, FIG. 13 is an enlarged partial perspective view showing a state where the carriage is housed in the stocker, and FIGS. 14a and 14b are trays in the shuttle drive mechanism for driving the tray and the carriage. Partial side view and plan view showing the state where the engagement is released and only the carriage is driven. Fig. 15 is a timing chart showing the raising / lowering operation of the stocker. Fig. 16 is a timing showing the ejecting operation from the loading position of the tray. FIG. 17 is a timing chart showing a tray ejecting operation and a loading operation which are performed in conjunction with the mechanical base ascending / descending. FIG. 18 is a timing chart showing a tray ejecting operation and a loading operation in another embodiment. FIG. 3 is a block diagram showing a control system for each drive motor. Explanation of symbols 1 …… Chassis (player main body), 24 …… guide rail, 25 …… projection rail, 26 …… guide groove, 26a …… first
Horizontal part, 26b ... bent part, 26c ... second horizontal part, 30 ... tray, 32 ... lock pin, 34 ... guide groove, 40 ... carriage, 45 ... recess, 50 ... shuttle ,
52 ...... concave groove, 56 ...... pivot pin, 60 ...... wire, 61 ...... drive pulley, 62 ...... driven pulley, 63 ...... motor, 70 ...... tray lock arm, 72 ...... locking groove, 74 …… Guide pin, 80 …… Carriage lock arm, 82 …… Tip,
84 …… Guide pin, 90 …… Stocker, 100 …… Disk

Claims (4)

[Claims] 1. A plurality of carriages on which a disc can be placed, a loading position in which one of the plurality of carriages can be placed and which is accommodated in a player main body, and an eject position which is pulled out from the player main body. And a stocker capable of accommodating the plurality of carriages, the tray and the carriage mounted on the tray are reciprocally movable between the loading position and the eject position, and the carriage is A drive mechanism for enabling reciprocal movement between a loading position placed on the tray in the loading position and a loading position stored in the stocker, and a disk on the carriage in the loading position. And a disc reproducing means for reproducing information on the tray and the carriage by a driving source. A first engaging portion that is movable in the reciprocating direction and that can engage with the first engaged portion of the tray, and a second engaging portion that can engage with the second engaged portion of the carriage. The drive mechanism is provided with a shuttle including: and the tray is moved to the loading position and the tray by the engagement of the first engaging portion and the first engaged portion in the first movement section of the shuttle. The carriage is moved to and from the eject position, and in the second movement section of the shuttle, the carriage is engaged with the second engaging portion and the second engaged portion to move the carriage to the placement position and the storage position. A disc player characterized by being moved to and from. 2. The drive mechanism engages with an engagement releasing means for releasing engagement between the first engaging portion and the first engaged portion in a second movement section of the shuttle. The disc player according to claim 1, further comprising: 3. A plurality of carriages on which a disc can be placed, a loading position in which one of the plurality of carriages can be placed and which is accommodated in the player main body, and an eject position which is pulled out from the player main body. And a stocker capable of accommodating the plurality of carriages, the tray and the carriage mounted on the tray are reciprocally movable between the loading position and the eject position, and the carriage is A drive mechanism for enabling reciprocal movement between a loading position on the tray in the loading position and a loading position in the stocker, and a disk on the carriage in the loading position. And a disc reproducing means for reproducing information from the disk drive, wherein the drive mechanism is (i) a drive source. And the carriage is movable in the reciprocating direction of the carriage, and moves the tray between the loading position and the eject position by moving in the first moving section, and also in the second moving section. And (ii) a shuttle which moves to move the carriage between the mounting position and the storage position by moving the carriage, and (ii) locks a lock pin provided on the tray and pivotally supported by the shuttle. Tray lock arm with possible locking groove,
(Iii) a carriage lock arm that is fixed to the shuttle and has an engagement portion that is engageable with the carriage,
(Iv) In the first movement section of the shuttle, the tray lock arm is controlled to a first rotation angle so that the lock pin can be locked in the locking groove, and the shuttle moves to the first rotation angle. Control means for controlling the tray lock arm to a second rotation angle so that the lock pin can be disengaged from the locking groove when shifting from the first movement section to the second movement section. Disc player characterized by. 4. The first and second straight line portions for receiving the guide pins projecting from the tray lock arm and extending parallel to the forward direction of the shuttle, and the straight lines. A guide groove consisting of a bent portion connecting the portions, wherein the first rotation angle of the tray lock arm is maintained while the guide pin is guided to the first straight portion of the guide groove, While the guide pin is guided to the bent portion of the guide groove, the tray lock arm moves from the first rotation angle to the second rotation angle, and the guide pin moves to the second guide groove.
4. The disc player according to claim 3, wherein the second rotation angle of the tray lock arm is maintained while the tray lock arm is guided to the linear portion of the disc player.