JP3941754B2 - Playback device - Google Patents

Description

  The present invention relates to a disk recording and / or reproducing apparatus capable of driving a disk transport mechanism and a mechanical chassis lifting mechanism with a single motor.

  The disk recording and / or reproducing apparatus includes a disk transport mechanism that transports a disk and a mechanical chassis lifting mechanism that lifts and lowers a mechanical chassis on which a disk table and an optical pickup are mounted.

Then, after the disk is transported onto the disk table by the disk transport mechanism, the mechanical chassis is lifted and lowered by the mechanical chassis lifting mechanism, and the disk is chucked on the disk table mounted on the mechanical chassis. It has become. The disk transport mechanism and the mechanical chassis elevating mechanism are each driven by separate motors (see, for example, Patent Document 1).
JP 2003-151193 A

  By the way, in the above prior art, since the disk transport mechanism and the mechanical chassis lifting mechanism are driven by separate motors, there is a problem that the number of parts increases and the cost increases.

  SUMMARY OF THE INVENTION An object of the present invention is to solve the above-mentioned conventional problems and to provide a disk recording and / or reproducing apparatus capable of driving a disk transport mechanism and a mechanical chassis lifting mechanism with a single motor.

According to a first aspect of the present invention, there is provided a reproducing apparatus including a motor, a pinion gear that is rotated by a driving force of the motor and is fixed at a predetermined position, a rack having a first gear that can mesh with the pinion gear, and the rack. A gear switching member that is slidable together and formed with a cam groove for switching the oscillating gear , and a boss-like protrusion that engages with the cam groove for switching the oscillating gear. a swing gear support member which rotates in response to the sliding position of the provided in the swing gear support member is rotated by the driving force from said motor, first in response to rotation of the swing gear support member And a swinging gear that moves between a first position that meshes with the second gear, a second position that is spaced apart from the second gear, and a driving force of the motor via the second gear . Conveyor roller that conveys the disk , With is provided in the gear switching member, and a mechanical chassis elevating mechanism to release the disc chucking and chucking in accordance with the sliding of the gear-switching member,
The rocking gear switching cam groove extends continuously in a sliding direction of the gear switching member to hold the rocking gear in a first position and one end of the first groove part. An inclined second groove for moving the rocking gear from the first position to the second position, and one end of the second groove extending continuously in the sliding direction of the gear switching member. And a third groove for holding the moving gear in the second position.

The invention of claim 2 is the playback apparatus of claim 1,
Before the disk is inserted from the disk inlet / outlet, the rack and the pinion gear are not meshed, and when the disk is inserted from the disk inlet / outlet in the previous period, the motor is turned on and the disk is transported into the housing. Then, the operation unit presses the rack, and the rack is pressed to mesh with the pinion gear.

Since the reproducing apparatus according to the first aspect switches the gear between the meshed state and the released state, the transport amount of the disk can be controlled and the transport can be stopped at a predetermined position. Also, the slide of the gear switching member is changed to a rotational motion. The first groove portion and the third groove portion have a width of play, and the oscillating gear is moved when the boss-like protrusion passes through the second groove portion. The conveyance can be stopped when the disk is inserted to the back of the casing. Prevents disk and equipment damage. The disc can be transported to a fixed position. Since the mechanism is simple, the cost can be reduced. Furthermore, the disk can be chucked and released by the same motor as the transport. Therefore, cost reduction, weight reduction, and free space increase can be achieved.

  The reproducing apparatus according to the second aspect can engage the rack and the pinion gear so as to start the conveyance when the disc is inserted and stop the conveyance at an appropriate timing.

  Next, the best mode of the present invention is described as follows: (1) schematic configuration of the entire disc recording and / or reproducing apparatus, (2) configuration of a housing, a mechanical chassis, a disc chucking mechanism, and (3) a mechanical chassis locking mechanism, (4) Configuration of disc insertion guide mechanism, (5) Configuration of switch mechanism, (6) Configuration of disc centering member, (7) Configuration of disc transport mechanism, (8) Configuration of gear switching mechanism, (9) Mechanical chassis The structure of the elevating mechanism, (10) the structure of the conveying roller contacting / separating mechanism, (11) the structure of the disk overlap insertion preventing mechanism, and (12) the action will be described in this order.

(1) Schematic Configuration of Entire Disc Recording and / or Reproducing Device When the disc recording and / or reproducing device 1 inserts a disc from a disc inlet / outlet 3 provided in the housing 2, the disc is placed inside the disc inlet / outlet 3. It is guided by the arranged disk insertion guide mechanism 31 (see FIG. 7 and FIG. 8) and inserted into the housing 2.

  When the disk is inserted to a predetermined position, the motor 92 of the disk transport mechanism 91 (see FIGS. 19 and 20) is switched on by the switch mechanism 61 (see FIGS. 10 to 12). It is conveyed almost directly above the disk table 12 and positioned by a disk centering member 81 (see FIGS. 13 and 14).

  After the disk is positioned substantially directly above the disk table 12, the gear switching mechanism 131 (see FIGS. 21 to 25) is operated, and the mechanical chassis elevating mechanism 151 (see FIGS. 26 and 27) is operated by the motor 92 of the disk transport mechanism 91. ), The disk table 12 mounted on the mechanical chassis 11 is moved to the disk side, and the disk is chucked on the disk table 12. After chucking the disk on the disk table 12, the transport rollers 32 and 33 are separated from the disk by the transport roller contact / separation mechanism 161 (see FIGS. 22 to 25 and 28), and the disk is restrained by the transport rollers 32 and 33. The disk is opened to make the disk free of rotation, and the disk entrance / exit 3 is blocked by a disk duplication / insertion prevention mechanism 171 (see FIGS. 29 and 30) to make it impossible to insert another disk. Then, recording and / or reproduction is performed.

  When the eject button is pushed after the recording and / or reproduction is finished, the motor 92 is reversed, the disc entrance / exit 3 is blocked by the disc duplication / insertion prevention mechanism 171, the disc is ejected from the disc entrance 3, and the mechanical chassis is locked. It is locked by a mechanism 191 (see FIGS. 35 and 36).

(2) Configuration of Case, Mechanical Chassis, and Disk Chucking Mechanism As shown in FIGS. 1 and 2, the case 2 includes a base plate 4 and a top panel 5. A disk doorway 3 is provided between the front panel 5 and the surface panel 5. The disk entrance / exit 3 is formed in a size that allows insertion of both an 8 cm disk 6 and a 12 cm disk 7. A mechanical chassis 11 is attached to the base plate 4.

  As shown in FIGS. 3 and 4, the mechanical chassis 11 includes a disk table (turn table) 12, an optical pickup 13, and the like. The mechanical chassis 11 is rotatably attached to the base plate 4 by a shaft 14, and the disk table 12 is moved up and down between a disk chucking release position (see FIG. 3) and a disk chucking position (see FIG. 4). It is supposed to let you.

  When the mechanical chassis 11 moves to the disc chucking release position, it is fixed (locked) to the base plate 4 side by a mechanical chassis lock mechanism 191 (see FIGS. 35 and 36) described below. .

  As shown in FIGS. 3 and 4, the top panel 5 is provided with a disk chucking mechanism 21. The disk chucking mechanism 21 includes a chucking member 22 and a chucking member support arm 23 that supports the chucking member 22.

  As shown in FIGS. 5 and 6 in an enlarged manner, the chucking member 22 is formed in a substantially disc shape by a synthetic resin in which a magnetic metal plate such as iron is inserted. The chucking member support arm 23 has a bifurcated plate support portion 24 and supports the chucking member 22 by inserting the rate support portion 24 into a recess 25 provided on the outer peripheral surface of the chucking member 22. It is supposed to be. The chucking member support arm 23 is attached to the top panel 5 by a shaft 26 so as to be able to turn up and down. The chucking member support arm 23 is given a clockwise turning force about the shaft 26 by pushing down the one end portion 23a side by the arm operation member 27, and the chucking member support arm 23 is attached to the top panel 5. It is raised up at a predetermined inclination angle. (See FIG. 5).

  When the pushing down of the one end portion 23a side of the chucking member support arm 23 by the arm operation member 27 is released, the chucking member support arm 23 is rotated counterclockwise by the spring force of the torsion coil spring 28, and the chucking member support arm 23 is stopped. Move to the king position. (See FIG. 6).

(3) Configuration of Mechanical Chassis Locking Mechanism As shown in FIG. 35, the mechanical chassis locking mechanism 191 swings the mechanical chassis 11 toward the base plate 4 side of the housing 2 when the mechanical chassis 11 is in the disc chucking release position. A lock portion 192 for releasing chucking that is impossiblely locked is provided.

  The lock portion 192 at the time of releasing the chucking includes first and second locked portions 193 and 194 provided at a substantially central portion and one side portion of the free end side of the mechanical chassis 11 and the first portion at the time of releasing the chucking. , First and second lock portions 195 and 196 engaged with the second locked portions 193 and 194, respectively.

  The first and second lock portions 195 and 196 are provided on a slide member 182 of a disc overlap insertion prevention mechanism 171 which will be described in detail later. One end portions of the first and second lock portions 195 and 196 are inclined surfaces 197. When the slide member 181 moves to the disk chucking release position, the first and second lock portions 195 and 196 are moved to the disc chucking release position by the inclined surfaces 197. The mechanical chassis 11 is locked at the disc chucking release position by engaging the second locked portions 193 and 194 so as to be pushed down. FIG. 35 shows a state in which the mechanical chassis 11 is viewed from the lower surface side, so that the first and second locked portions 193 and 194 are pushed up by the first and second lock portions 195 and 196. In reality, the first and second locked portions 193 and 194 are pushed down by the first and second lock portions 195 and 196 as shown in FIG.

  When the slide member 181 moves from the disc chucking release position to the disc chucking position, as shown in FIG. 36, the first and second lock portions 195 and 196 and the first and second locked portions 193 are obtained. , 194 is released. When the slide member 181 comes to the disk chucking position, the chucking lock portion 199 including the third lock portion 198 provided on the slide member 181 and the first locked portion 193 is used. Specifically, the mechanical lock 11 is locked at the disk chucking position by engaging the third lock portion 197 so as to push up the first locked portion 193. 36 shows a state in which the mechanical chassis 11 is viewed from the lower surface side, so that it appears that the first locked portion 193 is pushed down by the third lock portion 198. As shown, the first locked portion 193 is pushed up by the third lock portion 198.

( 4 ) Configuration of Disc Insertion Guide Mechanism The disc insertion guide mechanism is for inserting the disc into the housing from the disc entrance with the center portion of the disc aligned with the center portion of the disc entrance.

  As shown in FIG. 7, the disk insertion guide mechanism 31 includes a pair of transport rollers (hereinafter referred to as first and second rollers) 32 and 33 and a pair of first and second rollers 32 and 33 attached thereto. Rotating arms (hereinafter referred to as first and second arms) 34 and 35, and torsion coil springs (hereinafter referred to as first and second springs) for applying rotational force to the first and second arms. 36, 37, and a synchronous drive gear group 38 that moves the first and second arms 34, 35 in a direction that approaches and separates from each other.

  The first arm 34 is formed in a substantially fan shape, and a main portion of the fan is pivotally attached to one end portion of the top panel 5 on the disk doorway 3 side by a first shaft 41. In addition, an arcuate gear 42 is provided on the free end side with the first shaft 41 as the center.

  The first arm 34 is applied with a counterclockwise turning force by the first spring 36 and is stopped at a position approaching the disk doorway 3. In this state, the first roller 32 attached to the first arm 34 is located at a predetermined distance L1 from the center position CL of the disk entrance 3.

  Similarly to the first arm 34, the second arm 35 is also formed in a substantially fan shape, and the main part of the fan is connected to the other end portion of the top panel 5 on the disk entrance / exit side by the second shaft 43. While being rotatably attached, an arcuate gear 44 is provided on the free end side with the second shaft 43 as the center.

  The second arm 35 is given a clockwise turning force by the second spring 37 and stops at a position close to the disk doorway 3. In this state, the second roller 33 attached to the second arm 35 is located at a predetermined distance L2 from the center position CL of the disk doorway 3, and the first roller 32 and the second roller 33 are located. The interval L1 + L2 is 8 cm or less.

  Further, as shown in FIG. 8, the first roller 32 and the second roller 33 in the state where the first arm 34 is most rotated clockwise and the second arm 35 is most rotated counterclockwise. The distance L3 exceeds 12 cm, and the first roller 32 and the second roller 33 are not in contact with the 12 cm disk 7.

  The synchronous drive gear group 38 includes a first gear 51 that meshes with the fan-shaped gear 42 of the first arm 34, a second gear 52 that meshes with the fan-shaped gear 44 of the second arm 35, and these The third to sixth gears 53 to 56 are interposed between the first and second gears 51 and 52.

  When one of the first and second arms 34 and 35 is rotated, the other arm is also rotated in synchronization with the first and second arms 34 and 35. , They are moved in the direction of approaching and separating from each other.

  As shown in FIG. 9, the first and second rollers 32 and 33 have peripheral surfaces formed substantially in a cross-section, and the peripheral portions of the disks 6 and 7 inserted from the disk inlet / outlet 3. The upper and lower edge portions 8 are sandwiched.

( 5 ) Configuration of the switch mechanism The switch mechanism switches on the motor of the disk transport mechanism when the disk is inserted from the disk entrance to a predetermined position.

  As shown in FIGS. 10 to 12, the switch mechanism 61 includes first and second switches 62 and 63, a switch operation lever 64 that sequentially presses the first and second switches 62 and 63, A rotating cam 65 for operating the switch operating lever 64 and an interlocking gear group 66 for rotating the rotating cam 65 in conjunction with the rotation of the second arm 35 of the disk insertion guide mechanism 31 are provided.

  The interlocking gear group 66 includes an arcuate gear 67 provided on the rotary cam 65, a seventh gear 68 that meshes with the arcuate gear 67, and an eighth gear 69 that meshes with the seventh gear 68. And. The eighth gear 69 meshes with the second gear 52 of the disc insertion guide mechanism 31.

  The rotating cam 65 has a bearing tube portion 70, and a cam mounting shaft (not shown) provided on the top panel 5 is inserted into the bearing tube portion 70 to center the cam mounting shaft. The top panel 5 is rotatably attached.

  The arc-shaped gear 69 is formed in an arc shape with the bearing tube portion 70 as the center. The rotating cam 65 is linked to the first arm 34 via an interlocking gear group 66 composed of an arcuate gear 67 and seventh and eighth gears 68 and 69 and the gear group 38 for synchronous driving. And turn.

  The rotating cam 65 includes first to third cam surfaces 71 to 73 on the substantially opposite side of the fan-shaped gear 69 with the bearing cylinder portion 70 interposed therebetween.

  One end of the switch operating lever 64 is attached to the base plate side so as to be rotatable by a shaft 64a. The switch operating lever 64 is provided with a circular contact portion 64b in contact with the first to third cam surfaces 71 to 73 of the rotary cam 65 at the center, and both sides of the switch operation lever 64 so as to sandwich the contact portion 64b. A first switch operation unit 64c that presses the first switch 62 and a first switch operation unit 64d that presses the second switch 63 are provided in the unit.

  As shown in FIG. 10, before the disk is inserted into the disk doorway 3, the contact portion 64b of the switch operating lever 64 contacts the first cam surface 71, and the first switch 62 and the second switch The switch 63 is kept OFF.

  As shown in FIG. 11, when the disc is inserted from the disc inlet / outlet 3 and the first and second arms 34 and 35 are opened more than a predetermined distance by the disc, the switch is placed on the second cam surface 72. When the contact portion 64b of the operation lever 64 comes into contact, the first switch 62 is turned on by the first switch operation portion 64c, and the second switch 63 is kept off by the second switch operation portion 64d. .

  As shown in FIG. 12, when the first and second arms 34 and 35 are further opened by a predetermined distance or more, the contact portion 64b of the switch operating lever 64 contacts the third cam surface 73, and the The first switch 62 is turned on by the first switch operation unit 64c, and the second switch 63 is turned on by the second switch operation unit 64d.

When the first switch 62 and the second switch 63 are in the OFF state, the switch mechanism 61 stops the motor 92 of the disk transport mechanism 91 described later, and when the first switch 62 is turned on, the motor is turned off. The motor rotation speed (RPM) is controlled by starting and turning on the first switch 62 and the second switch 63.

( 5 ) Configuration of the disc centering member The disc centering member is for positioning the central portion of the disc inserted from the disc entrance on the disc table, and a disc having a different diameter, for example, an 8 cm disc is inserted. gear may have, even when inserting the 12cm disc, illustrating the center portion of the disk as well as to be able to be positioned substantially directly above the disk table, after the after-centering ends with discs of different diameters The switching mechanism can be pressed.

  As shown in FIGS. 13 and 14, the disc centering member 81 has a disc abutting portion 82 on one end side, and an operation portion 83 that presses a rack 134 of a gear switching mechanism 131 described later on the other end side. The disc contact portion 82 and the operation portion 83 are pivotally supported by a shaft 84 so as to be rotatable. Then, when the disc transported by the disc transport mechanism 91 described below abuts on the disc abutting portion 82 and the disc abutting portion 82 is pressed, the disc rotates about the shaft 84 and moves to the center of the disc. When the portion comes almost directly above the disc table 12, the stop is stopped by a stopper 85 provided on the rotary cam 65, and the disc abutment portion 82 positions the disc.

  The disc abutting portion 82 is configured to rotate the disc centering member 81 by a predetermined amount to a position where the disc 6 abuts when the 8 cm disc 6 is conveyed and the 8 cm disc 6 is centered. When the 12 cm disc 7 is transported with the disc contact portion 82A, the disc 7 comes into contact with the second disc contact to rotate the disc centering member 81 by the same amount as the first disc contact portion 82A. And a contact portion 82B.

  The first disk contact part 82A and the second disk contact part 82B correct the difference in diameter between the 8 cm disk 6 and the 12 cm disk 7 by changing the distance from the shaft 84 and the phase in the rotation direction. Then, the rotation amount of the disk centering member 81 until the 8 cm disk 6 and the 12 cm disk 7 are centered is made substantially equal, and the 12 cm disk 7 interferes (contacts) with the first disk contact portion 82A. The 8 cm disk 7 does not interfere with the second disk contact portion 82B.

  The disk centering member 81 is rotatably mounted on the rotating cam 65 by inserting the shaft 84 into a bearing 86 provided on the rotating cam 65. Further, the disc centering member 81 has a long hole 87 formed in an arc shape with the shaft 84 as a center, and the bearing cylinder portion 70 provided in the rotary cam 65 is inserted into the long hole 87. Thus, the shaft 84 can be rotated around the shaft 84 within the range of the long hole 87.

  The first disc contact portion 82A and the second disc contact portion 82B are provided on the substantially opposite side of the elongated hole 87 with the shaft 84 as the center. As described above, the first disc contact portion 82A is in contact with the vicinity of the tip of the 8 cm disc 6 inserted from the disc inlet / outlet 3, and the second disc contact portion 82B is in contact with the first disc contact portion 82A. The tip of a 12 cm disc 7 inserted from the disc inlet / outlet 3 comes into contact.

  The first disk contact portion 82A is formed at a position farther from the shaft 84 than the second disk contact portion 82B. The second disk contact part 82B is formed at a position closer to the shaft 84 than the first disk contact part 82A and at a position where the 8 cm disk 7 does not contact. The difference between the distance from the shaft 84 to the first disc contact portion 82A and the distance from the second disc contact portion 82B is the disc centering member until the centering of the 8 cm disc 6 and the 12 cm disc 7 is completed. The amount of rotation 81 is set to be substantially the same.

  A semi-cylindrical protrusion 88 is provided at one end of the elongated hole 87. At the upper end of the semi-cylindrical protrusion 88, a hook-like tongue piece 89 is provided so as to cover the elongated hole 88, and the operation portion 83 is provided at the tip of the tongue piece 89, The operation unit 83 is configured to press a rack 134 of a gear switching mechanism 131 described later.

  As shown in FIG. 15, when the tip of the 8 cm disk 6 conveyed from the disk entrance / exit by the disk conveyance mechanism 91 described below comes into contact with the first disk contact portion 82A, the disk centering member 81 is It is pushed and rotates counterclockwise around the shaft 84.

  As shown in FIG. 16, when the central portion of the 8 cm disc 6 has moved to a position just above the disc table 12, the disc centering member 81 is prevented from further rotation by the stopper 85, and is The disk 6 is positioned, and the operation unit 83 pushes the rack 134 of the gear switching mechanism 131.

  As shown in FIG. 17, when the second disk abutting portion 82B is pressed near the tip of the 12 cm disk 7 conveyed by the disk conveying mechanism 91, the disk centering member 81 It rotates counterclockwise about the shaft 84.

  As shown in FIG. 18, when the central portion of the 12 cm disc 7 has moved to a position just above the disc table 12, the disc centering member 81 is prevented from further rotation by the stopper 85, and the 12 cm disc 12 The disk 7 is positioned, and the rack 134 of the gear switching mechanism 131 is pressed by the operation portion 83.

( 7 ) Configuration of the disc transport mechanism The disc transport mechanism transports the disc inserted into the disc entrance 3.

  As shown in FIGS. 19 and 20, the disk transport mechanism 91 includes a motor 92 that is turned on and off by the switch mechanism 61, and the rotation of the motor 92 is applied to the first roller 32 and the second roller 33. And a rotation transmitting portion 93 for transmitting.

  The rotation transmission unit 93 includes a base plate side rotation transmission unit 94 (FIG. 19) provided on the base plate 4 and a top panel side rotation transmission unit 95 (FIG. 20) provided on the top panel 5. ing.

As shown in FIG. 19, the rotation transmission portion 94 on the base plate side includes a first pulley 96 provided on the shaft of the motor 92, an endless belt 97 having one end hung on the first pulley 96, A second pulley 98 on which the other end of the endless belt 97 is hung, an eleventh gear 99 provided on the rotation shaft of the second pulley 98, and a twelfth gear meshing with the eleventh gear 99. The gear 100, the thirteenth gear 101 formed integrally with the twelfth gear 100, the fourteenth gear 102 meshed with the thirteenth gear 101, and the fourteenth gear 102 A swing gear 103 as the fifteenth gear, a sixteenth gear 104 (second gear in claim 1) that can mesh with the swing gear 103 as the fifteenth gear, No. 17 meshing with the gear 104 The gear 105, the eighteenth gear 106 meshed with the seventeenth gear 105, the nineteenth gear 107 meshed with the eighteenth gear 106, and the nineteenth gear 107. A twentieth gear 108, a twenty-first gear 109 meshing with the twentieth gear 108, a twenty-second gear 110 meshing with the twenty-first gear 109, and the sixteenth gear And a 23rd gear 111 meshing with 104.

  The twenty-second gear 110 is rotatably attached to the outer periphery of the first shaft 41 that is the rotation center of the first arm 34, and the twenty-third gear 111 is rotated by the second arm 35. It is rotatably attached to the outer periphery of the second shaft 43 that is the center of movement.

The swing gear 103 as the fifteenth gear is attached to a swing gear support member (hereinafter simply referred to as a gear support member) 113 that can swing around a shaft 112. The gear support member 113 includes a boss-like protrusion 114, and the boss-like protrusion 114 is engaged with a cam groove 138 provided in a gear switching member of a gear switching mechanism 131 described later. The gear support member 113 meshes with the state in which the rocking gear 103 as the fifteenth gear meshes with the sixteenth gear 104 by rotating around the shaft 112 by sliding of the gear switching member. It is designed to be displaced to the released state.

As shown in FIG. 20, the rotation transmitting portion 95 on the top panel 5 side is a 24th gear 115 that is rotatably attached to the outer periphery of the first shaft 41 that is the rotation center of the first arm 34. A 25th gear 116 meshed with the 24th gear 115, a 26th gear 117 meshed with the 25th gear 116, and a 25th gear 117 meshed with the 26th gear 117 27 gears 118, a 28th gear 119 rotatably attached to the outer periphery of the second shaft 43, which is the rotation center of the second arm 35, and the 28th gear 119. A 29th gear 120, a 30th gear 121 meshing with the 29th gear 120, and a 31st gear 122 meshing with the 30th gear 121 are provided. As shown in FIG. 5, the rotation transmitting portion 95 on the top panel 5 side has the chucking member support arm 23 of the disk chucking mechanism 21 raised on the top panel 5 at a predetermined inclination angle. When the motor 92 is rotated, the base plate side rotation transmission part 94 and the top panel side rotation transmission part 95 are arranged. The first roller 32 and the second roller 33 rotate to carry the disk.

( 8 ) Configuration of Gear Switching Mechanism The gear switching mechanism lifts and lowers the disk of the disk by chucking and dechucking a mechanical chassis elevating mechanism 151 described below with the motor 92 of the disk transport mechanism 91. In other words, the power of the motor 92 used for driving the disk transport mechanism 91 is switched to driving the mechanical chassis lifting mechanism.

  As shown in FIG. 21, the gear switching mechanism 131 includes a rack 134 that can mesh with a pinion gear 132 that is integral with a fourteenth gear 102 that constitutes a gear group of a rotation transmission unit of the disk transport mechanism 91, and the rack 134. And a gear switching member 135 that is slidably driven.

The rack 134 is a linear gear that is slid by being pressed by the operation portion 83 of the disk centering member 81 when the disk is transported onto the disk table 12 by the disk transport mechanism 91 and meshed with the pinion gear 132. 133 (the first gear in claim 1) .

  The rack 134 and the gear switching member 135 are connected by a long hole 136 and a pin 137. When the rack 134 slides and the pin 137 contacts the end of the long hole 136, the rack 134 and the gear switching member 135 are connected. And slide together.

  The gear switching member 135 includes a first position where the swing gear 103 as a fifteenth gear constituting the gear group of the rotation transmission unit of the disk transport mechanism 91 is engaged with the sixteenth gear 104, and the first gear. There is provided a cam groove 138 for switching the oscillating gear to be moved between the second position where the meshing with the 16 gears 104 is released.

  The rocking gear switching cam groove 138 extends in the sliding direction of the gear switching member 135 to hold the rocking gear 103 in the first position, and one end of the first groove 139. An inclined second groove 140 that moves the swing gear 103 from the first position to the second position continuously to the first portion, and a gear switching member 135 that is continuous to one end of the second groove 140. And a third groove 141 that extends in the sliding direction and holds the rocking gear 103 in the second position. When a boss-like convex portion 114 provided on the gear support member 113 is located in the first groove portion 139, the swing gear 103 as the fifteenth gear is engaged with the sixteenth gear 104. Yes.

  The gear switching mechanism 131 is configured as described above, and as shown in FIG. 22, before the disc is inserted into the housing from the disc inlet / outlet, a boss-like convex portion 114 provided on the gear support member 113. Is located in the first groove 139 and meshes the rocking gear 103 with the sixteenth gear 104.

  Then, the disc is inserted into the housing 2 from the disc entrance 3 and the disc transport mechanism 91 is switched on. The disc is transported into the housing by the disc transport mechanism 91 and the disc centering member 81 is moved at the front end of the disc. When pushed and rotated, as shown in FIG. 23, the rack 134 is pressed by the operation portion 83 provided on the bowl-shaped tongue piece 89 of the disc centering member 81. The pressed rack 134 is in a state in which a so-called trigger is pulled, and the gear 133 of the rack 134 meshes with the pinion gear 132 integrated with the fourteenth gear 102 of the disk transport mechanism 91 and slides by the rotation of the pinion gear 132. To do.

  When the rack 134 slides by a predetermined amount, as shown in FIG. 24, the pin 137 comes into contact with the end of the long hole 136 and the gear switching member 135 slides together with the rack 134. When the gear switching member 135 slides by a predetermined amount, the boss-shaped protrusion 114 provided on the gear support member 113 moves from the first groove 139 into the third groove 141 via the second groove 140. To do.

  The boss-like convex portion 114 provided on the gear support member 113 moves to the third groove portion 141 through the second groove portion 140. At this time, the gear support member 113 is centered on the shaft 112. Rotating to disengage the swing gear 103 as the fifteenth gear and the sixteenth gear 104. Accordingly, the connection of the rotation transmission mechanism 93 of the disk transport mechanism 91 is cut off, and the rotation of the first roller 32 and the second roller 33 by the motor 92 is prevented. Then, as shown in FIG. 25, the mechanical chassis 11 is raised and lowered while the boss-like convex portion 114 moves in the third groove portion 141.

( 9 ) Configuration of Mechanical Chassis Lifting Mechanism The mechanical chassis lifting mechanism lifts the mechanical chassis toward the disk positioned substantially directly above the disk table by the disk centering member, and the disk mounted on the mechanical chassis. The disk is chucked on the table, and after the recording and / or reproduction on the disk is completed, the mechanical chassis is lowered to release the chucking of the disk and the disk can be ejected.

  As shown in FIG. 26, the mechanical chassis raising / lowering mechanism 151 has a cam engagement convex portion 152 provided on the free end side of the mechanical chassis 11 whose one end is rotatably attached to the base plate 4 by the pivot shaft 14. It is configured by engaging with a cam groove 153 for raising / lowering the mechanical chassis provided on the side surface of the gear switching member 135.

  The cam groove 153 for raising / lowering the mechanical chassis is continuous with a first cam groove portion 154 that holds the mechanical chassis 11 in a lowered position (disc chucking release position) and one end portion of the first cam groove portion 154. A second cam groove 155 that raises the mechanical chassis 11 from the lowered position, and a third cam groove 11 that is continuous with one end of the second cam groove 155 and holds the mechanical chassis 11 in the raised position (disk chucking position). Cam groove portion 156.

  Before the disk is inserted into the housing from the disk entrance / exit, as shown in FIG. 26, the cam engaging convex part 152 provided on the mechanical chassis 11 is positioned in the first cam groove part 154 so that the mechanical chassis 11 is moved. It is held at the lowered position (disc chucking release position).

  Then, when the disk is inserted into the housing from the disk inlet / outlet, the disk transport mechanism 91 is switched on, and the gear switching member 135 is slid by a predetermined amount together with the rack 134, the mechanism chassis 11 is provided as shown in FIG. The cam engaging convex portion 152 moves from the first groove portion 154 to the third groove portion 156 via the second groove portion 155, and holds the mechanical chassis 11 in the raised position (disc chucking position).

( 10 ) Constitution of the transport roller contact / separation mechanism The transport roller contact / separation mechanism performs recording and / or reproduction on the disk by separating the transport roller from the disk after completion of the disk chucking and making the disk rotation free. Sometimes it is for bringing the transport roller into contact with the disk.

  As shown in FIG. 22, the transport roller contact / separation mechanism 161 is slidably attached to the end of the gear switching member 135 by a long hole 162 and a pin 163 within the length of the long hole 162. Rotating cam operating body 164, first and second protrusion engaging portions 166, 167 provided on the rotating cam operating body 164 and engaged with protrusions 165 provided on the gear switching member 135, and the switch mechanism And a roller contact / separation protrusion 168 provided on the rotation cam 65 of the motor 61.

  As shown in FIG. 25, when the gear switching member 135 continuously moves after the end of the disk chucking, the slide of the gear switching member 135 causes the protrusion 165 to be second as shown in FIG. The rotary cam operating body 164 is slid by engaging with the protrusion engaging portion 167. When the rotating cam operating body 164 slides, a protrusion engaging portion 169 provided at an end of the rotating cam operating body 164 engages with the roller contacting / separating protrusion 168 to rotate the rotating cam 65.

  When the rotary cam 65 is rotated, the first arm 34 and the second arm 35 are rotated in a direction away from each other via the synchronous drive gear group 38 of the disk insertion guide mechanism 31, so that the first The arm 34 and the second arm 35 are separated from the peripheral surface of the disk, so that the disk is in a rotation-free state. The rotary cam operating body 164 is attached to the gear switching member 135 by the long hole 162 and the pin 163 so as to be movable relative to the gear switching member 135. This is to prevent interference with 65.

( 11 ) Configuration of Duplicate Disc Insertion Prevention Mechanism The disc duplicate insertion prevention mechanism informs that the disc has already been inserted into the casing by blocking the disc entrance when the disc has already been inserted into the casing. The other disc cannot be inserted, and is provided at a substantially central portion of the disc entrance.

  As shown in FIGS. 29 and 30, the disc overlap insertion preventing mechanism 171 urges the disc insertion preventing member 172 capable of blocking the disc entrance 3 and the disc insertion preventing member 172 to a position where the disc entrance 3 is shut off. Urging member 173, and a disc insertion preventing member operating mechanism for moving the disc insertion preventing member 172 from a position for blocking the disc entrance 3 to a position for opening the disc entrance 3 against the urging force of the urging member 173 174.

  The disc insertion blocking member 172 includes a blocking member main body portion 175 that is inserted into and removed from the central portion of the disk inlet / outlet port 3 and a base portion 176 provided with the blocking member main body portion 175 at the distal end portion. The base portion 176 has a shaft. A base plate 4 is pivotally attached to the base plate 4 by 177. When the base 176 is rotated in one direction around the shaft 177, the blocking member main body 175 provided at the tip of the base 176 enters the disk entrance 3 through the hole 178 provided in the base plate 4. Thus, the central part of the disk entrance 3 is blocked. When the disc insertion blocking member 172 is integrally molded with a synthetic resin and is pressed by a disc to be inserted in a state where the central portion of the disc inlet / outlet 3 is blocked, the blocking member main body portion 175 is pressed. The front end portion and the base end portion are pressed against the opening / closing member receiving portion 179a on the top panel side and the opening / closing member receiving portion 179b on the base plate side to prevent the discs from being inserted repeatedly.

  The biasing member 173 has one end locked to the base 176 and the other end locked to the base plate 4, and the disk insertion blocking member 172 rotates counterclockwise about the shaft 177. The blocking member main body 175 is caused to enter the disk entrance / exit 3 through a hole 178 provided in the base plate 4. A coil spring is used for the urging member 173.

  As shown in FIG. 31, the disk insertion preventing member operating mechanism 174 enters between the base 176 and the base plate 4 and presses the base 176 against the urging force of the urging member 173. A pressing operation portion 181 having a convex portion 180 having a shape, a slide member 182 provided with the pressing operation portion 181, and a pinion 184 engaged with a rack-like gear 183 provided on one side surface of the slide member 182. It is equipped with. The pinion 184 meshes with a rack-like gear 185 provided on the gear switching member 135.

  Before the disc is inserted into the housing from the disc entrance 3, the trapezoidal convex portion 180 enters between the base portion 176 and the base plate 4, as shown in FIGS. 30 to 32. The base 176 is pressed against the urging force of the urging member 173, and the blocking member main body 175 is extracted from the disk inlet / outlet 3 to open the disk inlet / outlet 3.

  When the disk is inserted into the housing from the disk entrance 3, the motor 92 is switched on as described above, the disk is transported by the disk transport mechanism 91, and the disk centering member 81 is rotated. The rack 134 is pressed, and the gear switching member 135 slides as a trigger, and the pinion 184 meshed with the linear gear 185 provided on the gear switching member 135 rotates, and the pinion 184 is rack-shaped. The slide member 182 engaged with the gear 183 also slides in conjunction with the gear switching member 135. When the gear switching member 135 is slid to the position where the mechanical chassis 11 is raised to the disk chucking position by the cam groove 153 for raising / lowering the mechanical chassis provided on the side surface thereof, FIGS. 29, 33, and 34 are used. As shown in FIG. 6, in the slide member 181, the trapezoidal cam portion 180 of the pressing operation portion 181 comes out from between the base portion 176 and the base plate 4 to release the pressing of the base portion 176. Accordingly, the base 176 is rotated by the urging force of the urging member 176, and the blocking member main body 175 enters the disk inlet / outlet 3 from the hole 178 provided in the base plate 4 and enters the center of the disk inlet / outlet 3. Block the part. In the above embodiment, the blocking member main body 175 and the base 176 are formed of synthetic resin. However, a metal pin is used for the blocking member main body 175, and the metal pin is used as the synthetic resin base 176. May be planted.

(12) Operation Next, the operation of the disc recording and / or reproducing apparatus will be described separately for a case where an 8 cm disc is inserted and a case where a 12 cm disc is inserted.

When an 8 cm disc is inserted As shown in FIG. 37, when an 8 cm disc 6 is inserted from the disc entrance 3, the tip of the 8 cm disc 6 hits the peripheral surfaces of the first roller 32 and the second roller 33. . When the 8 cm disc 6 is further inserted, the distance between the first roller 32 and the second roller 33 is increased, so that the first arm 34 and the second arm 35 widen each other. To turn. At this time, the first and second rollers 32 and 33 are in a state of biting on the peripheral surface of the 8 cm disk 6. The rotation cam 65 of the switch mechanism 61 is rotated via the interlocking gear group 66 by the rotation of the first arm 34 and the second arm 35, and the second cam surface 72 provided on the rotation cam 65 performs the first operation. 1 switch 62 is turned on. When the first switch 62 is turned on, the motor 92 of the disk transport mechanism 91 rotates, and the rotation of the motor 92 is transmitted to the first roller 32 and the second roller 33 via the rotation transmission unit 93. .

  As the first roller 32 and the second roller 33 rotate, the 8-cm disk 6 is conveyed into the housing. When the 8 cm disc 6 is conveyed to a predetermined position and the tip of the disc 6 comes into contact with the first disc abutting portion 82A and is pushed, the disc centering member 81 is counterclockwise about the shaft 84. Rotate. When the central portion of the 8 cm disc 6 is moved almost directly above the disc table 12, the disc centering member 81 is prevented from further rotation by the stopper 85, and the 8 cm disc 6 is positioned. Is done.

  When the disk centering member 81 rotates, the rack 134 is pressed by the operation portion 83 provided on the bowl-shaped tongue piece 89 of the disk centering member 81. This pressing acts as a trigger, and the rack 134 is engaged with the small-diameter gear 132 integral with the fourteenth gear 102 of the disk transport mechanism 91 and slides.

When the rack 134 slides by a predetermined amount, the pin 137 comes into contact with the end of the long hole 136 and the gear switching member 135 slides together with the rack 134. When the gear switching member 135 slides by a predetermined amount, the boss-like protrusion 114 provided on the gear support member 113 moves from the first groove portion 140 into the third groove portion 142 via the second groove portion 141. .

By the gear support member 113 boss-like protrusions 114 provided to move said third groove 142, the gear support member 11 3, 15 of the gear 103 rotates around the shaft 112 and the The meshing of the 16 gears 104 is released. Accordingly, the connection of the rotation transmission portion 93 of the disk transport mechanism 91 is cut off, and the rotation of the first roller 32 and the second roller 33 by the motor 92 is prevented.

  Even when the connection of the rotation transmission unit 93 of the disk transport mechanism 91 is interrupted, the rotation of the motor 92 is caused by the first pulley 96, the endless belt 97 that is hung at one end on the first pulley 96, A second pulley 98 on which the other end of the endless belt 97 is hung, an eleventh gear 99 provided on the rotation shaft of the second pulley 98, and a twelfth gear meshing with the eleventh gear 99 100, a thirteenth gear 101 meshed with the twelfth gear 100, a fourteenth gear 102 meshed with the thirteenth gear 101, a small-diameter gear 132 integrated with the fourteenth gear 102, and a rack It is transmitted to the gear switching member 135 via 134 and the gear switching member 135 is slid.

  When the gear switching member 135 is slid, the cam engaging convex portion 152 provided on the free end side of the mechanical chassis 4 is the second of the cam groove 153 for raising / lowering the mechanical chassis provided on the side surface of the gear switching member 135. Are introduced into the third cam groove portion 156 through the cam groove portion 155 to raise the mechanical chassis 4 to the disk chucking position. When the mechanical chassis 4 rises to the disk chucking position, the arm operating member 27 is operated by a protrusion (not shown) provided on the mechanical chassis 4 to release the pressing of the chucking member support arm 23 by the arm operating member 27. Then, the chucking member support arm 23 is lowered by the spring force of the torsion coil spring 28 and overlaps the upper surface of the top panel 5. As the mechanical chassis 4 is raised and the chucking member support arm 23 is lowered, the 8-cm disk 6 is placed on the disk table 12 and is chucked by the disk table 12 and is chucked. As a result, the magnet is chucked on the disk table. On the other hand, the slide member 182 slides through the rack-shaped gear 185, the pinion 184, and the rack-shaped gear 183 by the sliding of the gear switching member 135, and the trapezoidal cam of the pressing operation portion 181 provided on the slide member 182. The blocking member main body 175 is provided on the base plate 4 by the spring force of the coil spring as the urging member 173 as the part 180 comes out from between the base 176 and the base plate 4 to release the pressing of the base 176. The hole 178 enters the inside of the disk inlet / outlet 3 to close the center of the disk inlet / outlet 3, and the mechanical chassis 11 is locked at the disk chucking position by the chucking lock part 199 of the mechanical chassis locking mechanism 191.

  When the gear switching member 135 is further slid after the 8-cm disk 6 is magnet chucked on the disk table 12, as shown in FIG. 28, the end of the rotary cam operating body 164 assembled to the gear switching member 135 is obtained. The protrusion engaging portion 169 provided on the portion engages with the roller contact / separation protrusion 168 provided on the rotating cam 65 to rotate the rotating cam 65.

  The rotation of the rotary cam 65 causes the first arm 34 and the second arm 35 to rotate away from each other via the synchronous drive gear group 38 of the disk insertion guide mechanism 31, and FIG. As shown, the first arm 34 and the second arm 35 are separated from the peripheral surface of the 8-cm disk 6 so that the disk is free to rotate. Then, recording and / or reproduction of an 8 cm disc is performed.

  When the eject button is pushed after the recording and / or reproduction is finished, the motor 92 is rotated reversely, and the reverse operation is performed when the disc is inserted, and the 8 cm disc 6 is ejected to the disc inlet / outlet 3 side. The mechanical chassis 11 is locked at the disc chucking release position by the lock portion 192 when the chucking release of the mechanical chassis lock mechanism 191 is released.

When a 12 cm disc is inserted As shown in FIG. 39, when a 12 cm disc 7 is inserted from the disc entrance 3, the tip of the 12 cm disc 7 hits the peripheral surfaces of the first roller 32 and the second roller 33. . When a 12 cm disc 7 is further inserted, the distance between the first roller 32 and the second roller 33 is increased, so that the first arm 34 and the second arm 35 increase the distance between each other. To turn. The rotation cam 65 of the switch mechanism 61 rotates through the interlocking gear group 66 by the rotation of the first arm 34, and the first switch 62 is turned on by the second cam surface 72 provided on the rotation cam 65. Put it in a state. When the first switch 62 is turned on, the motor 92 of the disk transport mechanism 91 rotates, and the rotation of the motor 92 is transmitted to the first roller 32 and the second roller 33 via the rotation transmission unit 93. .

  As the first roller 32 and the second roller 33 rotate, the 12-cm disk 7 is transported into the housing, so that the first arm 34 and the second arm 35 are spaced apart from each other. To turn. Since the 12 cm disk 7 is 4 cm larger in diameter than the 8 cm disk 6, the first arm 34 and the second arm 35 rotate more than that, so the rotating cam 65 of the switch mechanism 61 is also 8 cm. Compared with the case of the disk 6, it rotates extra. By this rotation, the second switch 63 is also turned on at the third cam surface 73. When both the first switch 62 and the second switch 63 are turned on, the transport speed of the 12 cm disk 7 is increased.

  When the central portion of the 12 cm disc 7 is moved almost directly above the disc table 12, the disc centering member 81 is prevented from further rotation by the stopper 85, and the 12 cm disc 7 is positioned. Is done. At the time of ejection, the motor 92 rotates in the reverse direction, and the operation opposite to that at the time of inserting the disc is performed, and the 12 cm disc 6 is discharged to the disc inlet / outlet 3 side.

The perspective view of the recording and / or reproducing | regenerating apparatus of this invention. The perspective view which looked at the recording and / or reproducing | regenerating apparatus of this invention from the back side. The side view of a state in which the mechanical chassis is in the disc chucking release position. The side view in the state where a mechanical chassis exists in a disk chucking position. Sectional drawing of a disk chucking mechanism. (Chucking release position). Sectional drawing of a disk chucking mechanism. (Chucking position). The top view of a disc insertion guide mechanism. The top view of the state which the 1st, 2nd arm opened most. The side view of the 1st, 2nd roller. Explanatory drawing of a switch mechanism (a 1st, 2nd switch is an OFF state). Explanatory drawing of a switch mechanism (a 1st switch is ON and a 2nd switch is an OFF state). Explanatory drawing of a switch mechanism (a 1st, 2nd switch is an ON state). The perspective view of a rotation cam and a disk centering member. The perspective view which looked at the rotating cam and the disk centering member from the back side. Explanatory drawing which shows the state which the disk of 8 mm contact | abutted to the disk centering member. Explanatory drawing which shows the state by which the disk of 8 mm was disc-centered. Explanatory drawing which shows the state which the disk of 12 mm contact | abutted to the disk centering member. Explanatory drawing which shows the state by which the disc of 12 mm was disc-centered. The top view which shows the rotation transmission part by the side of a baseplate. The top view which shows the rotation transmission part by the top plate side. The perspective view of the principal part of a gear switching mechanism and a disk centering member. Explanatory drawing which shows the effect | action of a gear switching mechanism. Explanatory drawing which shows the effect | action of a gear switching mechanism. Explanatory drawing which shows the effect | action of a gear switching mechanism. Explanatory drawing which shows the effect | action of a gear switching mechanism. Schematic explanatory drawing of a disk raising / lowering mechanism (disc chucking cancellation | release state). Schematic explanatory drawing (disc chucking state) of the disc lifting mechanism. Explanatory drawing of the state in which the disc contact / separation mechanism is activated. Explanatory drawing which shows the state which interrupted | blocked the disc entrance by the disc duplication insertion prevention mechanism. Explanatory drawing which shows the state which open | released the disc entrance by the disc duplication insertion prevention mechanism. The top view of the principal part of a disc duplication insertion prevention mechanism (disc door opening state). AA sectional drawing of FIG. The top view of the principal part of a disc duplication insertion prevention mechanism (blocking state of a disc entrance). BB sectional drawing of FIG. The perspective view of the state which has locked the mechanical chassis to the disk chucking release position. The perspective view of the state which has locked the mechanical chassis to the disk chucking position. The top view of the state which is conveying the 8mm disc. The top view of the state which the conveyance roller left | separated from the disk. The top view of the state which is conveying the 12mm disc.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Disc recording and / or reproducing | regenerating apparatus, 2 ... Housing | casing, 3 ... Disc inlet / outlet, 4 ... Base plate, 5 ... Top panel, 6 ... 8mm disc, 7 ... 12mm disc, 11 ... Mechanical chassis, 12 ... Disc Table, 13 ... Optical pickup, 91 ... Disc transport mechanism, 92 ... Motor, 93 ... Rotation transmission part, 103 ... Swing gear, 104 ... Gear meshing with rocking gear, 131 ... Gear changer, 151 ... Mechanical chassis Elevating mechanism.

Claims (2)

A motor,
A pinion gear that rotates by the driving force of the motor and is fixed at a predetermined position ;
A rack having a first gear meshable with the pinion gear;
A gear switching member that is slidable together with the rack and in which a cam groove for swinging gear switching is formed ;
A oscillating gear support member having a boss-like projection that engages with the oscillating gear switching cam groove, and rotating according to a slide position of the gear switching member;
Wherein provided on the swing gear support member is rotated by the driving force from said motor, first position to the second gear and meshed with according to the rotation of the swing gear support member, the second A swing gear that moves between a second position that is spaced apart from the gear;
A transport roller for transporting the disk by the driving force of the motor via the second gear ;
A mechanical chassis elevating mechanism that is provided on the gear switching member, and that performs chucking of the disk and release of chucking according to the sliding of the gear switching member ;
The rocking gear switching cam groove is
A first groove that extends in a sliding direction of the gear switching member and holds the rocking gear in a first position;
An inclined second groove that moves the swing gear from the first position to the second position continuously from one end of the first groove;
A third groove that extends in the sliding direction of the gear switching member continuously to one end of the second groove and holds the rocking gear in the second position;
Reproducing apparatus according to claim <br/> further comprising a. Before the disk is inserted from the disk inlet / outlet, the rack and the pinion gear are not meshed, and when the disk is inserted from the disk inlet / outlet, the motor is switched on and the disk is transferred into the housing The playback device according to claim 1, wherein the operation unit presses the rack, and the rack is pressed to mesh with the pinion gear.

Images