JP3660975B2 - Mechanism for preventing disc misalignment in multi-disc players - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a multi-disc player that stores a plurality of discs and selects and plays back an arbitrary disc.
[0002]
[Prior art]
2. Description of the Related Art Conventionally, a so-called multi-disc player that stores a plurality of discs and selects and reproduces an arbitrary disc from the discs is known. Conventionally, as such a multi-disc player, there has been a magazine-type multi-disc player in which a magazine containing a plurality of discs is mounted on an apparatus main body, and a disc in the magazine is selected and reproduced.
[0003]
In addition, there has been a so-called carousel type multi-disc player in which a plurality of discs are placed on a rotatable table and the table is rotated to select and reproduce the disc.
[0004]
Furthermore, when a disc is stored in a tray on the stocker in the apparatus and an arbitrary disc is played back, the selected disc is transferred to the playback unit together with the tray for playback, and the disc in the stocker is replaced. There is a bank type multi-disc player in which a tray and a disc are placed on a slide table and discharged out of the apparatus.
[0005]
Some bank-type multi-disc players described above are provided with a disc misalignment prevention mechanism for preventing misalignment of the disc in the stocker by a disc guide. In addition, there is a type in which a door is provided at a disk insertion slot in order to prevent dust and dust from entering the apparatus and improve the aesthetic appearance.
[0006]
[Problems to be solved by the invention]
The above-described magazine type multi-disc player has a problem in that the manufacturing cost of the magazine increases and the manufacturing cost increases. Further, when replacing one disk, the magazine has to be taken out from the apparatus, and there is a disadvantage that operability is poor.
[0007]
Further, the carousel type multi-disc player has a problem that the number of discs accommodated is limited to about five because the discs are accommodated side by side on a plane. Further, there is a problem that the apparatus becomes large and a space for projecting the table is required in front of the apparatus.
[0008]
The bank-type multi-disc player requires parts such as a stocker, a tray, and a slide table, and has a problem that the manufacturing cost increases because the number of parts increases.
[0009]
In the disc displacement prevention mechanism, the disc guide must be retracted to a position that does not hinder the disc movement when the disc is transferred to the outside of the apparatus or to the playback unit. There is a problem that the source is different, the mechanism for taking the drive timing is complicated, and the manufacturing cost is high.
[0010]
SUMMARY OF THE INVENTION An object of the present invention is to provide a disc displacement prevention mechanism with a simple mechanism and low manufacturing cost in a multi-disc player that accommodates discs so as to be stacked in the vertical direction.
[0011]
[Means for Solving the Problems]
According to the disk position shift prevention mechanism of the present invention, the disks placed on the disk tray are stored in the first position in the apparatus so as to overlap in the vertical direction, and the disk tray is stored in the first position and the second position outside the apparatus. In a multi-disc player that exchanges discs by horizontally transferring the disc tray and horizontally transfers the disc tray from a first position to a third position opposite to the second position to reproduce the disc. A first transfer means for horizontally transferring a tray between a first position and a second position; a second transfer means for horizontally transferring the disk tray between a first position and a third position; and the disk tray. A door for opening and closing the door, a drive mechanism for the door, a disk guide for preventing displacement of the disk, and a drive mechanism for the disk tray, wherein the disk tray is moved from the first position to the second position. Before moving to the third position, the disk guide driving mechanism is driven by a member that interlocks with both the door driving mechanism and the second transfer means so that the disk guide is retracted to a position that does not interfere with the disk. It is composed. With such a configuration, it is possible to synchronize the operation timings of the disk guide drive mechanism, the disk transfer mechanism, and the door opening / closing mechanism with a simple mechanism.
[0012]
DETAILED DESCRIPTION OF THE INVENTION
A multi-disc player according to an embodiment of the present invention will be described with reference to the drawings. First, the outline of the operation of the multi-disc player according to the embodiment will be described with reference to FIG. As shown in detail in FIG. 4, the disk trays 2, 2,... In FIG. 1 are provided with a recess for placing a disk on the upper surface, and are supported so as to be movable in the horizontal direction. The disk tray 2 is transported between a disk storage position that is a first position, a second position outside the apparatus, and a third position that is a disk reproduction position. In FIG. 1, the first position, the second position, and the third position are indicated by a solid line, a dotted line, and a chain line, respectively.
The disk tray 2 is transferred between the first position and the second position by meshing between the top gear 4 and the rack 2 b of the disk tray 2. As shown in FIG. 4, the top gear 4 has a trigger protrusion, and is moved to a position where the top gear 4 meshes with the rack 2 b of an arbitrary disc tray 2 by moving up and down. A first transfer means is formed by the top gear 4 and its driving mechanism, and a first selection means is formed by the lifting mechanism of the top gear 4.
[0013]
The traverse unit 34 includes a turntable 34a rotated by a disk motor and an optical pickup, and is raised and lowered so as to be positioned at a position corresponding to each height of the disk trays 2, 2,. The loading hook 46 is moved up and down by the lifting mechanism of the traverse unit 34 and engages with the recess 2 c of the disc tray 2 corresponding to the position of the traverse unit 34. The loading hook 46 is further driven in the horizontal direction to transfer the engaged disc tray 2 between the first position and the third position.
[0014]
The traverse unit 34 is slightly lifted at the positioned position, and the disk on the disk tray 2 is lifted and clamped by the turntable 34a to be in a reproduction state. The traverse unit 34 constitutes a reproducing means, and the horizontal driving means of the loading hook 46 constitutes a second transfer means. Further, the lifting mechanism of the traverse unit 34 constitutes second selection means.
[0015]
Next, the configuration of each of the above-described means and clamping means will be described with reference to FIGS. The directions of XYZ shown in the figures are common in each figure. The X direction is the forward direction, that is, the direction in which the disc tray 2 protrudes from the housing. In addition, the same reference numerals are assigned to the center lines connected in each figure. When the same member is drawn in two places, the reference numeral of one member is shown in parentheses.
[0016]
A main chassis 1 shown in FIG. 2 supports the entire apparatus. The disc trays 2, 2... Shown in FIG. 4 are supported by the rail left 1a, 1a... And the rail right 1b shown in FIG. The rail left 1a, 1a... And the rail right 1b are fastened to the main chassis 1 together with the upper surface guide 1c. The position in the protruding direction from the housing is regulated by a stopper 2 a provided on the disk tray 2. The leaf spring member 3 shown in FIG. 4 is fixed to the main chassis 1 and stabilizes the disc tray 2 at a predetermined position.
[0017]
The top gear 4 shown in FIG. 4 meshes with a rack 2b provided on the inner surface of the disc tray 2, and transfers the disc tray 2 between the first position and the second position. The shaft 4a of the top gear 4 is inserted through the hole of the bracket plate 1f shown in FIG. 4, and the top gear 4 is supported by the bracket plate 1f so as to be movable up and down.
[0018]
The bracket plate 1f is fastened to the main chassis 1 below the rail left 1a, 1a... And the rail right 1b. The shaft 4a of the top gear 4 is inserted through the compression coil spring 5 and the engaging member 6, and the bottom gear 7 is fastened to the lower end. The top gear 4 is urged downward by a compression coil spring 5.
[0019]
The shafts 6a and 6a of the engaging member 6 are positioned above the select arm 8, and the top gear 4 is moved up and down as the select arm 8 rotates. The select arm 8 is rotatably supported by bearings 1e and 1e provided on the main chassis 1. The shaft 8 a of the select arm 8 abuts on a stepped cam surface provided on the lower surface of the main cam 9 that is rotatably supported by the main chassis 1. That is, the top gear 4 is moved up and down by the rotation of the main cam 9. The main cam 9 is supported by the main chassis 1 so as to be rotatable below the bracket plate 1f.
[0020]
The number of steps of the stepped cam surface is the number of accommodated disk trays 2 +2 and the top gear 4 is engaged with the rack 2 b of each disk tray 2, the position disengaged downward from the disk tray 2, and the upper side from the disk tray 2. (The position at which the shaft 4a is inserted through the holes 2d of all the disk trays 2 and the position when shipped).
[0021]
The main cam 9 is rotationally driven by a motor 10, a pulley 11, a belt 12, a worm gear 14 and a helical gear 16 shown in FIG. The shaft 15 that supports the motor 10 and the helical gear 16 is supported by the main chassis 1 and the bracket plate 1f, and the shaft 13 that supports the worm gear 14 is supported by the bracket plate 1f.
[0022]
The belt 12 is hung between a pulley 11 fixed to the rotating shaft of the motor 10 and a pulley portion of the worm gear 14. It meshes with the formed gear. These rotational drive mechanisms of the main cam 9 constitute second drive means.
[0023]
The rotation position of the main cam 9 is detected by a micro switch S2 that is actuated by a projection of the main cam 9 and detects a home position, and an optical sensor P1 that detects a slit provided in an annular rib of the main cam 9. Controlled by signal. The microswitch S2 and the optical sensor P1 are attached to the printed circuit board 57 shown in FIG. 2, and the printed circuit board 57 is fastened to the bottom surface of the main chassis 1.
[0024]
The top gear 4 is phase-aligned with the motor 18, pulley 19, belt 20, geared pulley 22, sun gear 24, planetary gear 26, internal gear 27 and final gear 29 and final gear 29 shown in FIG. Are rotated by the bottom gear 7 engaged with each other. The shaft 18 supporting the motor 18, the geared pulley 22, the sun gear 24, and the internal gear 27 is supported by the main chassis 1, and the final gear 29 is supported by the shaft provided in the main chassis 1. Yes.
[0025]
The belt 20 is hung between a pulley 19 fixed to a rotating shaft of a motor 18 and a pulley 22 with a gear. The pulley 22 with a gear meshes with a large gear of a sun gear 24 and a small gear of the sun gear 24 is a carrier gear. 25 is meshed with planetary gears 26 and 26 that are rotatably supported by 25. The planetary gears 26 and 26 are also meshed with the internal teeth of the internal gear 27, the external teeth of the internal gear 27 are meshed with the final gear 29 shown in FIG. 4, and the final gear 29 is meshed with the bottom gear 7.
[0026]
The carrier gear 25 meshes with the idler gear 28, and the idler gear 28 meshes with the rack 31 a of the lift slider 31. The idler gear 28 is rotatably supported by the main chassis 1, and the lift slider 31 is slidably supported by the main chassis 1. The sun gear 24, the carrier gear 25, the planetary gear 26, and the internal gear 27 constitute a planetary gear mechanism. When the rotation of one of the carrier gear 25 and the internal gear 27 is restricted, the other is rotated by the sun gear 24. Is done.
[0027]
The power transmission system to the motor 18 and the planetary gear, the planetary gear mechanism, the gear and the rack meshing with it constitute the first drive means. Switching of the power transmission of the planetary gear mechanism is performed by a switching lever 30 shown in FIG. The switching lever 30 is rotatably supported by the main chassis 1, and a shaft 30 a erected on the switching lever 30 is engaged with a cam groove provided on the lower surface of the main cam 9.
[0028]
One end 30 b of the switching lever 30 can be locked with the final gear 29, and the other end 30 c of the switching lever 30 can be locked with the linear cam 31 c of the lift slider 31. The planetary gear mechanism drives either the final gear 29 or the lift slider 31 according to the rotational position of the main cam 9.
[0029]
The lift slider 31 moves up and down the traverse unit 34 and the holder 32 shown in FIG. The holder 32 rotatably supports the shafts 33a and 33a of the frame 33. Ends in the −X direction of the traverse unit 34 are supported by bosses 32 b and 32 b of the holder 32 via insulators 35 and 35.
[0030]
Ends in the + X direction of the traverse unit 34 are supported by bosses 33c and 33c of the frame 33 via insulators 36 and 36 and coil springs 37 and 37. Since the traverse unit 34 is supported via an insulator, vibrations of the holder 32 and the frame 33 are not transmitted.
[0031]
The shafts 32 a, 32 a... Erected on the holder 32 are engaged with the stepped guide grooves 31 b, 31 b of the lift slider 31 and the vertical groove of the holder guide 1 d fixed to the main chassis 1. The holder 32 is positioned by the lift slider 31 at a position corresponding to the height of each of the disk trays 2, 2,. The position of the lift slider 31 is detected by levers 42 and 42 and micro switches S5 and S6 driven by the linear cam 31c of the lift slider 31.
[0032]
The clamper bracket 38 shown in FIG. 3 is fastened to the holder 32. The clamper 39, the permanent magnet 40, and the yoke 41 are integrally fitted in the clamper bracket 38 together. When the traverse unit 34 is rotated upward by the frame 33, the turntable 34a lifts the clamper 39 positioned on the disk together with the disk, the clamper 39, the permanent magnet 40 and the yoke 41 are not in contact with the clamper bracket 38. It becomes a state. In this state, the permanent magnet 40 attracts the turntable 34a, and the disk is clamped to the tene table 34a.
[0033]
The frame 33 is rotated by a clamp slider 47 shown in FIG. The clamp slider 47 is slidably supported by the main chassis 1, and a shaft 47 b erected on the clamp slider 47 is engaged with a cam groove provided on the lower surface of the main cam 9.
[0034]
A shaft 33 b erected on the frame 33 is engaged with a cam groove 47 a of the clamp slider 47. The cam groove 47 a branches in three directions, and the clamp slider 47 rotates the frame 33 and the traverse unit 34 at any position of the frame 33 that moves up and down together with the holder 32. The clamp means is constituted by the clamper 39, the permanent magnet 40, the yoke 41, the clamper bracket 38, the frame 33, the clamp slider 47, and its driving mechanism.
[0035]
FIG. 5 shows the positional relationship between the clamp slider 47 and the shaft 33 b erected on the frame 33. FIGS. 5A and 5B show a state in which the frame 33 is in the raised position. At this time, the upper disk tray 2 is sent to the reproduction position, and then the clamp slider 47 is moved horizontally. The disc is clamped. FIGS. 5C and 5D show a state in which the frame 33 is at the intermediate position. At this time, the disk tray 2 at the intermediate position is sent to the reproduction position, and then the clamp slider 47 is moved horizontally. To clamp the disc. FIGS. 5E and 5F show a state in which the frame 33 is in the lowered position. At this time, the lower disk tray 2 is sent to the reproduction position, and then the clamp slider 47 is moved horizontally. The disc is clamped.
[0036]
The disc trays 2, 2,... Are transferred between a first position as a storage position and a third position as a reproduction position by a loading hook 46 shown in FIG. The convex part 46a of the loading hook 46 engages with the concave part 2c of the disc tray 2, 2,..., And the convex part 45a of the loading slider 45 is inserted into the hole 46b of the loading hook 46.
[0037]
The loading hook 46 is engaged with the rail 32 c of the holder 32 and moves up and down together with the holder 32. When the holder 32 moves up and down, the loading hook 46 is in a position to engage with the recess 2c of the disk tray 2 in the first position, and engages with any of the disk trays 2 when the holder 32 is positioned in the vertical direction. .
[0038]
The loading slider 45 is supported by the rail left 1a so as to be slidable in the X direction, and is sent in the X direction by a final gear 43 that meshes with a rack 45b provided on the loading slider 45. The final gear 43 is provided with a trigger gear, and rotates in mesh with a gear provided on the outer periphery of the main cam 9 as the main cam 9 rotates.
[0039]
A cam is formed below the final gear 43, and a torsion coil spring 44 that is in pressure contact with the cam stabilizes the stop position of the final gear 43 and hence the stop position of the disc tray 2 at a predetermined position. Such a lifting mechanism of the loading hook 46 constitutes a second selection means, and a horizontal driving mechanism of the loading hook 46 constitutes a second transfer means.
[0040]
The sliders 48, 49 and 50 shown in FIG. 4 are supported by the bracket plate 1f so as to be slidable in the X direction. The lever 54 is rotatably supported by the bracket plate 1f. Further, the door drive lever 51 is rotatably supported with respect to the main chassis 1, and the gear 51 a of the door drive lever 51 is engaged with the rack 50 a of the slider 50.
[0041]
The disk guide 55 is disposed at a position that coincides with the center hole of the disk at the storage position, and is supported by the main chassis 1 so as to be movable up and down so as to sandwich the compression coil spring 56 together with the main chassis 1. The tip of the lever 54 locks the shaft 55 a of the disk guide 55 and is biased upward by the compression coil spring 56. The slider 48 is biased in the + X direction by a tension coil spring 52. The sliders 48 and 49 are biased so as to be attracted to each other by the tension coil spring 53.
[0042]
The protrusion 48b of the slider 48 abuts on the protrusion 54a of the lever 54, and when the slider 48 is driven in the -X direction, the lever 54 is rotated downward to lower the disk guide 55. 7A and 7B show a state where the disk guide 55 is raised, and FIGS. 7C and 7D show a state where the disk guide 55 is lowered.
[0043]
As shown in detail in FIG. 6, the shaft 48 a of the slider 48 abuts on a cam groove 9 a provided on the upper surface of the main cam 9, and the slider 48 is driven in the −X direction by the main cam 9. The cam groove 9a of the main cam 9 does not hinder the movement of the slider 48 in the −X direction.
[0044]
The shaft 49 a of the slider 49 engages with a cam groove 29 a provided on the upper surface of the final gear 29, and the slider 49 is driven in the X direction by the rotation of the final gear 29. When the slider 49 moves in the −X direction, the sliders 48 and 50 also move in the −X direction. That is, the main cam 9 and the final gear 29 can lower the disc guide 55 independently of each other. 6A shows a state when the disc guide 55 is lowered by the main cam 9, and FIG. 6B shows a state when the disc guide 55 is lowered by the final gear 29. FIG. 6C shows a state where neither the main cam 9 nor the final gear 29 is in a position where the disc guide 55 is lowered.
[0045]
When the final gear 29 lowers the disc guide 55, the slider 50 rotates the door drive lever 51 to open a door provided at the entrance / exit of the disc tray (not shown).
[0046]
The disc guide 55 rises when the disc tray is returned to the playback position or the storage position from the outside of the housing, but is placed above the lever 54 when the disc position on the disc tray is displaced and the disc guide 55 is prevented from rising. Further, when the micro switch S4 does not operate, the disc position deviation is detected. A microswitch S3 disposed at a position actuated by the projection of the final gear 29 detects that the disc tray 2 has protruded outside the housing.
[0047]
In addition to the motors and microswitches described above, there are a disk motor attached to the traverse unit 34, an optical pickup feed motor, and a microswitch S1 for detecting the home position of the optical pickup. In the disk motor, a turntable 34a is fixed to a rotating shaft and rotates the disk. The control device controls the rotation of each motor based on signals from each microswitch, optical sensor, and operation panel key.
[0048]
8, 9 and 10 show the operating states of the respective members with respect to the rotation angles of the main cam 9, the final gear 29 and the carrier gear 25, respectively. As shown in FIG. 8 (h), the home position of the main cam 9 is detected by the micro switch S2. As shown in FIG. 8A, loading, that is, transfer from the storage position of the disc tray to the reproduction position is performed while the rotation angle of the main cam 9 is increased. In addition, although the position of the home position of the main cam 9 is set to the rotation angle 0, the main cam 9 is reversely rotated. The same applies to FIGS. As shown in FIG. 8C, the clamping operation is performed at the initial and final stages of the rotation of the main cam 9. However, at the initial stage of rotation, there is no disk on the traverse unit, so the disk is not clamped.
[0049]
8D and 8E show that the disk guide 55 is raised at the initial and final stages of rotation of the main cam 9, and the micro switch SW4 is operating. Since the disc guide 55 is also moved up and down by the final gear 29 as described above, the disc guide 55 may be lowered by the final gear 29 even in the range of UP shown in FIG.
[0050]
8 (f) and 8 (g) show a state in which the top sensor 4 is moved up and down at the initial and final stages of rotation of the main cam 9, and the optical sensor P1 is activated. The numbers 1 to 3 in the figure indicate the number of rising steps of the top gear 4. The first to third stages indicate the corresponding number of stages of the disc tray 2.
[0051]
As shown in FIG. 8B, the switching lever 30 transmits the rotation of the motor 18 to the carrier gear 25 at the stage before the lowering of the top gear 4 is completed and the transfer of the disc tray 2 to the reproduction position is started. Switch the power transmission destination.
[0052]
As shown in FIG. 8 (i), opening of the disk tray 2 (transfer to the outside of the housing) is permitted only when the top gear 4 is in a position corresponding to the disk tray 2 of each stage.
[0053]
FIG. 9 shows a state change accompanying the rotation of the final gear 29. The initial rotation and final rotation of the final gear 29 are detected by the micro switch S4 (tray close SW) and the micro switch SW3 (tray open SW), respectively. As the final gear 29 rotates, the disc tray is transferred (opened) out of the housing, but before that, the disc guide 55 is lowered and the door is opened. By rotating the final gear 29 in the reverse direction, the disk tray is transferred into the housing, and then the door is closed and the disk guide 55 is raised.
[0054]
As shown in FIGS. 8 and 9, when the disc tray is transferred to the storage position, the disc guide 55 is raised and the micro switch S4 is activated. At this time, the rise of the disc guide 55 is caused by the position of the disc. If the displacement is hindered, the micro switch S4 does not operate. In that case, the disc tray is opened so that the misalignment can be corrected.
[0055]
FIG. 10 shows a state change accompanying the rotation of the carrier gear 25. As shown in the figure, the traverse unit (TU) is raised and lowered as the carrier gear 25 rotates. The numbers 1 to 3 in the figure indicate the number of rising stages of the traverse unit 34 and the loading hook 46, that is, the corresponding number of stages of the disc tray 2. The raising / lowering position of the traverse unit can be detected based on the signal states of the micro switches SW5 and SW6.
[0056]
Next, the initialization operation of the multi-disc player will be described with reference to FIG. When the power is turned on, in step S1, it is determined whether or not the pickup is at the home position. If the pickup is not at the home position, the pickup is sent to the home position.
[0057]
Next, in step S2, it is determined whether or not the disc tray is closed. If the disc tray is not closed, the motor 18 is driven to close the disc tray. In this case, since the power is turned off with the disc tray open, the top gear 4 is engaged with the opened disc tray.
[0058]
Next, in step S3, it is determined whether or not the main cam 9 is at the home position. If the main cam 9 is not at the home position, the motor 10 is driven to rotate until the main cam 9 reaches the home position.
[0059]
Next, in step S4, it is determined whether or not the traverse unit is at the home position (lowermost position). If the traverse unit is not at the home position, the motor 10 is first driven to detect the position of the main cam 9. The power transmission destination of the motor 18 is switched to the carrier gear 25 as a position where the number becomes -1 (see FIG. 8). Then, the motor 18 is driven to set the traverse unit to the home position. The home position of the traverse unit is detected when the micro switches SW5 and SW6 are turned on.
[0060]
Next, in step S5, the motor 10 is driven and rotated until the main cam 9 reaches the home position. In this way, the initialization operation when the power is turned on is performed.
[0061]
After the initialization operation is completed, it is possible to perform or exchange the disc on the disc tray at any stage specified by the key operation. For example, when the performance of the disk on the second-stage disk tray is instructed by a key operation, the power of the motor 18 is set as a position where the count number of the optical sensor P1 that detects the position of the main cam 9 by driving the motor 10 is -1. The transmission destination is switched to the carrier gear 25. Then, the motor 18 is driven to align the position of the traverse unit with the second-stage disc tray. Next, the motor 10 is driven to transfer the second-stage disc tray to the reproduction position and further clamped to obtain a reproduction state.
[0062]
As shown in FIG. 8, it is possible to select a disc tray that opens when a disc is loaded and clamped. In this state, the rotation of the motor 18 is transmitted to the final gear 29. Accordingly, it is possible to exchange a disc by opening any disc tray during reproduction. It is apparent from FIG. 8 that even when the disc is transferred from the reproduction position to the storage position, the disc can be exchanged by opening an arbitrary disc tray.
[0063]
【The invention's effect】
According to the disc displacement prevention mechanism of the multi-disc player of the present invention, the operation timings of the disc guide drive mechanism, the disc transfer mechanism, and the door opening / closing mechanism can be matched with a simple mechanism.
[Brief description of the drawings]
FIG. 1 is an operation explanatory diagram of a multi-disc player according to an embodiment of the invention.
FIG. 2 is an exploded perspective view showing a portion of a multi-disc player which is an embodiment of the present invention.
FIG. 3 is an exploded perspective view showing another part of the multi-disc player.
FIG. 4 is an exploded perspective view showing still another part of the multi-disc player.
5 (a), (c) and (e) are schematic partial front views for explaining the operation of the multi-disc player, and FIGS. 5 (b), (d) and (f) are schematic partial views. It is a side view.
FIG. 6 is a schematic partial plan view for explaining the operation of the multi-disc player.
7 (b) and 7 (d) are schematic partial front views for explaining the operation of the multi-disc player, and FIGS. 7 (a) and 7 (c) are schematic partial side views.
FIG. 8 is a time chart showing the operation of the main cam (9) of the multi-disc player.
FIG. 9 is a time chart showing the operation of the final gear (29) of the multi-disc player.
FIG. 10 is a time chart showing the operation of the carrier gear (25) of the multi-disc player.
FIG. 11 is a flowchart showing an initialization operation of the multi-disc player.
[Explanation of symbols]
1 Main chassis, 1a rail left, 1b rail right, 1c top surface guide
1d holder guide, 1e bearing, 1f bracket plate
2 Disc tray, 2a stopper, 2b rack, 2c recess, 2d hole
3 Leaf spring member
4 Top gear, 4a shaft
5 Compression coil spring
6 Engagement member
7 Bottom gear
8 Select arm, 8a axis
9 Main cam, 9a Cam groove
10 Motor
11 pulley
12 belts
13 axes
14 Worm gear
15 axes
16 Helical gear
18 Motor
19 pulley
20 belts
21 axes
22 Pulley with gear
23 axes
24 sun gear
25 Carrier gear
26 Planetary gear
27 Internal gear
28 idler gear
29 Final gear, 29a Cam groove
30 Switching lever
31 lift slider, 31a rack, 31b guide groove, 31c linear cam
32 holder, 32a shaft, 32b boss
33 frame, 33a, 33b shaft, 33c boss
34 traverse unit, 34a turntable
35, 36 Insulator
37 Coil spring
38 Clamper bracket
39 Clamper
40 Permanent magnet
41 York
42 lever
43 Final Gear
44 Torsion coil spring
45 Loading slider, 45a Convex, 45b Rack
46 Loading hook, 46a Convex, 46b Shaft
47 Clamp slider, 47a Cam groove, 47b Shaft
48 Slider, 48a shaft, 48b Protrusion
49 Slider, 49a axis
50 slalider, 50a rack
51 door drive lever, 51a gear
52, 53 Tension coil spring
54 Lever, 54a Protrusion
55 Disc guide, 55a shaft
56 Compression coil spring
57 Printed circuit board
S2, S3, S4, S5, S6 Micro switch
P1 optical sensor

Claims (1)

The discs placed on the disc tray are stored in the first position in the apparatus so as to be stacked in the vertical direction, and the disc tray is horizontally transferred between the first position and the second position outside the apparatus. In a multi-disc player that performs disc replacement and horizontally transfers the disc tray from a first position to a third position opposite to the second position to reproduce the disc, the disc tray is moved to a first position and a second position. A first transfer means for horizontally transferring the disk tray, a second transfer means for horizontally transferring the disk tray between the first position and the third position, a door for opening and closing the entrance / exit of the disk tray, and a drive mechanism therefor And a disc guide for preventing disc displacement and a drive mechanism for the disc guide, and the door drive before the disc tray is moved from the first position to the second position or the third position. Kamao and wherein the disk guide drive mechanism of a member to be interlocked to either the second transport means is driven, the configured disk displacement prevention mechanism to retract the disk guide at a position where it does not interfere with the disc

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