JP2011034640A - Disk device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To safely eject a disk by manual operation in emergency. <P>SOLUTION: When an operation pin 70 inserted to an emergency hole 3b of a bezel 3 is pushed inward, a first ejection lever 51 and a second ejection lever 52 are moved backward and a first transmission gear 41 is pushed down to a disengaged position. When the first transmission gear 41 is pushed down to the disengaged position, a loading slider 34 is moved forward by a coil spring 35 to start the ejection of the disk D1. After moving forward, the loading slider 34 is received by a receiving portion 51a of the first ejection lever 51, thereby temporarily stopping the disk D1 at a half-ejection position where the disk D1 slightly protrudes from the bezel 3. Thereafter, when the operation pin 70 is pulled out in this state, the loading slider 34 moves forward following the pull-out of the operation pin, and the disk D1 is ejected to a full-ejection position. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a disk device capable of manually ejecting a disk in an emergency.

  In various information devices such as computers and car navigation devices, disks (for example, CDs, DVDs, Blu-ray disks, etc.) capable of storing a large amount of information are used as recording media. This disc is loaded into a disc device, and information is recorded and reproduced. In general, disk devices built in information equipment include a tray type in which a tray storing a disk is loaded and unloaded, and a slot-in type in which a disk is loaded and unloaded through a slot. In this slot-in type disk device, a disk transport mechanism having a loading slider that is moved by a motor is provided. When the disc is inserted into the slot of the front bezel, the disc transport mechanism is slightly moved and the motor is started. When the motor is started, the loading slider moves and the disc is transported by the disc transport mechanism.

  The slot-in type disk device does not require a tray, and thus is small and lightweight, and is widely used for notebook computers and the like. When the disk is unloaded from the disk device, the disk ejection is instructed by a push button operation or the like. By this instruction, the motor reverses and the disc is automatically carried out.

  However, when the power supply is interrupted due to a power failure or the like, or a problem occurs in the disk device itself, the disk is not automatically taken out but remains in the disk device. In order to cope with this emergency situation, the disk device is provided with a disk forced ejection mechanism.

  In the disk devices of Patent Documents 1 to 3, a disk transport mechanism having a loading slider, a motor for driving the loading slider, a transmission gear mechanism having a plurality of gears and transmitting the rotation of the motor to the loading slider are provided. In addition, a rotating plate that holds one of the gears in the transmission gear mechanism and rotates it to a non-meshing position for releasing the meshing with the other gear is provided as a disk forced ejection mechanism. In these disk apparatuses, the disk is loaded into the main body case when the loading slider moves forward, and the disk is unloaded from the main body case when the loading slider moves backward. In an emergency, when the operation pin is pushed into the hole on the front surface of the main body case, the rotating plate is rotated and the gear is rotated to the non-meshing position. When the operation pin is further pushed in with the gear meshing released, the loading slider is pushed backward by the operation pin, and the disc is carried out of the main body case.

JP 2009-037710 A JP 2008-198264 A JP 2007-220276 A

  In Patent Documents 1 to 3, the disk is forcibly ejected to the eject position when the operation pin is pushed in the farthest. Since the operator performs the push-in operation by grasping the operation pin with a finger, the disc may collide with the finger during the push-in operation and be injured when the disc is ejected to the eject position. was there.

  SUMMARY OF THE INVENTION An object of the present invention is to provide a disk device with improved safety by eliminating the risk of a disk colliding with a finger or the like when the disk is manually ejected in an emergency.

  In order to achieve the above object, a disk device according to the present invention has a loading slider that moves in the front-rear direction by a motor in a disk device in which a disk is loaded into a main body case through a slot, and the loading slider moves backward. A disc transport mechanism that carries the disc into the main body case when the loading slider moves forward, and urges the loading slider forward when the loading slider moves forward. A first spring, a plurality of gears, a transmission gear mechanism that transmits the rotation of the motor to the loading slider, and a discharge operation that is moved backward by being pushed by an operation member inserted from the front surface of the main body case Means, a second spring for biasing the discharge operation means forward, and the discharge The first gear in the transmission gear mechanism is moved from the meshing position to the non-meshing position while the ejecting manipulation means moves backward, and the transmission gear mechanism is moved to the disc transport mechanism side. A clutch means for returning the first gear to the meshing position while the discharge operation means returns to the front, and the discharge operation means, and the first gear is not engaged. The loading operation means receives the loading slider moved forward by the first spring after moving to the position, and the discharging operation means until the first gear moves to the meshing position when the discharging operation means returns to the front. Stop means for allowing the loading slider to move forward following the above.

  The discharge operation means includes a first discharge operation lever that is pushed by the operation member, and a second discharge operation lever that is pushed and moves together after the first discharge operation lever moves in a predetermined play section. It is preferable to provide.

  Further, it is preferable that the stop means is a receiving portion that stands vertically from the first discharge operation lever, the front surface of the receiving portion is pressed by the operation member, and the rear surface receives the loading slider.

  Further, when the loading slider is driven by the motor via the transmission gear mechanism to automatically carry out the disk, it is preferable that the loading slider moves forward to a position where the tip of the loading slider is substantially in contact with the stop means.

  According to the present invention, during the pushing operation of the operation member, the loading slider is received by the stop means of the ejection operation means, and the disk is stopped at a position slightly protruding from the slot before the eject position. The disc is ejected to the eject position following the pulling operation. Accordingly, when the disc is manually ejected in an emergency, the disc is not ejected all at once to the eject position, so that the disc can be prevented from colliding with a finger and the safety can be improved.

  Further, since the loading slider is moved forward by the first spring, the pushing amount of the operating member can be reduced as compared with the case where the operating member pushes the loading slider, and the discharging operation is simplified.

It is a perspective view of a disk device. FIG. 5 is a perspective view of the disk device showing a state in which the disk is ejected to a half eject position when the disk is forcibly ejected. It is a perspective view which shows the inside of a disc apparatus. It is a top view which shows the inside of a disc apparatus. It is a bottom view which shows the inside of a disc apparatus. It is a perspective view which shows a loading slider. It is sectional drawing which shows operation | movement of a raising / lowering frame. It is a top view of the principal part of this invention which shows the state in which the disk is not loaded. It is a top view of the principal part of this invention which shows the state with which the disk was loaded. It is a perspective view of the principal part of this invention in the state with which the disk was loaded. It is a disassembled perspective view which shows a 1st discharge operation lever, a 2nd discharge operation lever, and a mesh release lever. It is a side view which shows a transmission gear mechanism when a 1st transmission gear exists in a meshing position. It is a side view which shows a transmission gear mechanism when a 1st transmission gear moves to a non-meshing position. It is a top view of the principal part of this invention which shows the state which pushed the 1st discharge operation lever with the operation pin and moved the 1st transmission gear to the non-meshing position. It is a top view of the principal part of this invention which shows the state which the loading slider moved to the half eject position. It is a top view of the principal part of this invention which shows the state which the loading slider moved to the full eject position manually.

  1 and 2, the disk device 1 includes a main body case 2, and a bezel 3 is attached to the front surface thereof. The bezel 3 is provided with a slot 3a for inserting the disk D1, a push button 4 for instructing ejection of the disk D1, and an indicator 5 for displaying the operating state of the disk device 1. The disk D1 has a center hole D1a for chucking.

  The bezel 3 is formed with an emergency hole 3b for forcibly discharging the disc D1 manually in an emergency. As shown in FIG. 2, the disk D1 is ejected to a half-ejection position that protrudes about 20 mm from the bezel 3 by pushing the operating member (operation pin) 70 inserted into the emergency hole 3b. Following the pulling of the operation pin 70, the disk D1 is ejected to the full eject position at the time of forced ejection indicated by a two-dot chain line.

  A top plate 9 is attached to the main body case 2. Near the center of the top plate 9, an opening 9a is formed through which the chucking head 13 (see FIG. 3) slightly enters when the disk D1 is chucked. A recess 9b for forming a protruding portion on the inner wall of the main body case 2 is provided around the opening 9a. The protrusion of the main body case 2 receives the disk D1 when the chucking head 13 is inserted into the center hole D1a of the disk D1.

  3 and 4, the base panel 6 is fixed so as to partition the main body case 2 up and down. The base panel 6 has an opening 6a extending obliquely from the center. An elevating frame 7 is disposed in the opening 6a and is attached to the base panel 6 at a plurality of locations by a known buffer support structure 8. When the disk D1 is carried into or out of the main body case 2, the elevating frame 7 has the bezel 3 side as a support shaft, and the tip portion located at the center of the apparatus swings in the vertical direction. Further, the elevating frame 7 is formed with an opening 7a extending obliquely from the center.

  A drive unit 10 is attached to the tip of the elevating frame 7. The drive unit 10 includes a spindle motor 11, a turntable 12, and a chucking head 13. The spindle motor 11 is fixed to the back surface of the elevating frame 7, and the turntable 12 is fixed to the drive shaft thereof. The chucking head 13 is formed integrally with the turntable 12, and enters the center hole D1a of the disk D1 at the chucking position when the lifting frame 7 is raised. The chucking head 13 is provided with a plurality of chucking claws 13a urged by springs, and detachably holds the disk D1. The chucking release pin 14 receives the disk D1 and removes it from the chucking head 13 when the elevating frame 7 is lowered.

  A head unit 17 is attached to the lifting frame 7. The head unit 17 includes a carriage 18 exposed from the opening 7a of the lifting frame 7 and a pickup head 19 held by the carriage 18. When recording / reproducing information, the carriage 18 moves along the opening 7a.

  On the base panel 6, a disk support arm 20 for carrying in and out the disk D1 and an attracting arm 21 for carrying the disk D1 inserted from the slot 3a into the main body case 2 are arranged. . The disk support arm 20 holds the front end of the disk D1 with the holder 20a and swings about the shaft 22. The attracting arm 21 holds the rear end of the disk D1 with the flanged roller 21a and swings about the shaft 23. A link lever 24 is connected to swing the attracting arm 21. In the link lever 24, the pin 24 a moves along the cam groove 25.

  FIG. 4 shows the case where the disk D1 is in the fully ejected position at the time of automatic unloading, the disk D1 is in the automatic loading start position, and the case where the disk D1 is in the recording / reproducing position after completion of chucking. It is shown.

  In FIG. 5, the carriage 18 holding the pickup head 19 is supported by guide shafts 26 and 27. Both ends of the guide shafts 26 and 27 are fixed to the back surface of the elevating frame 7. The rotation of the thread motor 28 is transmitted to the screw shaft 30 via the gear train 29. As the screw shaft 30 rotates, the carriage 18 moves forward / backward.

  A loading motor 31 having a worm gear 31a is disposed on the back surface of the base panel 6. The rotation of the loading motor 31 is transmitted to the disk transport mechanism 33 through the transmission gear mechanism 32, and the disk D1 is loaded or unloaded. Is called. The main parts of the disk transport mechanism 33 are a loading slider 34, a disk support arm 20, and an attracting arm 21.

  The loading slider 34 includes a rack gear 34a, a hook-like spring hook 34b (see FIG. 8), a cam groove 34c for pressing the pin 24a of the link lever 24, and a cam groove 34d for operating the link lever 36. Is provided. The cam groove 34 c extends in the lateral direction, and the pin 24 a is moved along the cam groove 25 by pushing the pin 24 a in the moving direction of the loading slider 34.

  The link lever 36 has a pin 36a fitted in the cam groove 34d of the loading slider 34, and rotates around the shaft 37 when the loading slider 34 moves. The link lever 36 is connected to the base portion 20b via a link arm 38. The base portion 20 b is integrally connected to the disc support arm 20 disposed on the surface of the base panel 6 by a shaft 22. A switch 39 is disposed around the base portion 20b and is turned on when the disk support arm 20 is rotated by pushing the disk D1. In response to the signal from the switch 39, a control circuit (not shown) rotates the loading motor 31 and starts automatic loading of the disk D1.

  The link arm 38 includes a first arm 38a, a second arm 38b slidably connected to the first arm 38a, and a spring 38c for keeping the arms 38a and 38b in the shortest state. Has been. The slidable link arm 38 swings the disk support arm 20 without operating the link lever 36 while the disk D1 is pushed into the main body case 2 by the user, that is, until automatic loading is started. It becomes possible. When the loading slider 34 is moved backward, the spring 38c biases the loading slider 34 forward.

  As shown in FIG. 6, a cam groove 34 e is formed on the side surface of the loading slider 34. In the cam groove 34e, the elevating pin 7b of the elevating frame 7 is inserted, and the elevating frame 7 is moved up and down. The cam groove 34e is continuously provided with a low position portion 34f for keeping the elevating frame 7 in the lowered position, an inclined portion 34g for raising or lowering the elevating frame 7 and a high position portion 34h for keeping the elevating frame 7 in the recording / reproducing position. Is formed.

  As shown in FIG. 7A, when the elevating pin 7b of the elevating frame 7 is positioned at the lower portion 34f of the cam groove 34e, the elevating frame 7 is set at the lowered position. When the elevating pin 7b moves along the inclined portion 34g of the cam groove 34e, the elevating frame 7 rises as shown in FIG. 7B, and the chucking head 13 enters the center hole D1a of the disk D1. As shown in FIG. 7C, when the elevating pin 7b moves to the uppermost part of the inclined portion 34g, the elevating frame 7 is set at the disk mounting position, and the disk D1 is locked by the chucking claw 13a. As shown in FIG. 7D, when the elevating pin 7b enters the high position portion 34h of the cam groove 34e, the elevating frame 7 is set at the recording / reproducing position slightly lowered from the disk mounting position. At this recording / reproducing position, the elevating frame 7 is substantially parallel.

  As shown in FIG. 8, one end of a coil spring 35 is hooked on the spring hook 34 b, and the other end of the coil spring 35 is hooked on a hook-like spring hook 6 b provided on the back surface of the base panel 6. Yes. The loading slider 34 is biased forward by a coil spring 35.

  As shown in FIGS. 8 to 11, the transmission gear mechanism 32 includes a first transmission gear 41, a second transmission gear 42, and a third transmission gear 43. The first transmission gear 41 is attached to a pin 46 fixed to the base panel 6 so as to be rotatable and movable in the vertical direction. The second and third transmission gears 42 and 43 are rotatably attached to pins 47 and 48 fixed to the base panel 6.

  The first transmission gear 41 includes a small-diameter gear 41a and a large-diameter gear 41b that is integrally formed below the small-diameter gear 41a. Similarly, the second transmission gear 42 includes a large-diameter gear 42a and a small-diameter gear 42b that are integrally formed, and the third transmission gear 43 includes a small-diameter gear 43a and a large-diameter gear 43b that are integrally formed. It is configured.

  A worm gear 31 a is fixed to the rotating shaft of the loading motor 31, and the worm gear 31 a meshes with the large-diameter gear 41 b of the first transmission gear 41. The small diameter gear 41a meshes with the large diameter gear 42a, and the small diameter gear 42b meshes with the large diameter gear 43b.

  The loading slider 34 is provided so as to be movable in the front-rear direction between the full eject position shown in FIG. 8 and the disk loading position shown in FIG. The rack gear 34a of the loading slider 34 meshes with the small diameter gear 43a. The rotation of the loading motor 31 is transmitted to the rack gear 34a via the large diameter gear 41b, the small diameter gear 41a, the large diameter gear 42a, the small diameter gear 42b, the large diameter gear 43b, and the small diameter gear 43a, and the loading slider 34 is moved. .

  When the loading slider 34 moves backward, which is a direction away from the bezel 3, the disk D1 is loaded into the main body case 2, and when the loading slider 34 moves forward, which is the direction approaching the bezel 3, the disk D1. Is carried out from the main body case 2 toward the fully ejected position.

  A first discharge operation lever 51 is disposed below the first transmission gear 41. A second discharge operation lever 52 is placed on the first discharge operation lever 51. Each discharge operation lever 51, 52 is attached to the main body case 2 so as to be movable in the front-rear direction. Further, a mesh release lever 53 for forcibly releasing the meshing of the small diameter gear 41a and the large diameter gear 42a is disposed on the back surface of the base panel 6 and above the second discharge operation lever 52. . The first and second discharge operation levers 51 and 52 may be integrally formed.

  The first discharge operation lever 51 includes a receiving portion 51a for receiving the loading slider 34 and the operation pin 70, a spring hook portion 51b, a protrusion 51c for pushing the second discharge operation lever 52, and a long hole-shaped guide hole 51d. Is formed. This 1st discharge | emission control lever 51 is comprised with the thin metal plate, and each part 51a-51c is formed by the bending process. The receiving portion 51a stands vertically from the first discharge operation lever 51, a concave portion into which the operation pin 70 is inserted is formed on the front surface, and a convex portion that receives the loading slider 34 is formed on the rear surface. One end of a coil spring 55 is hooked on the spring hook portion 51 b, and the other end of the coil spring 55 is hooked on a hook-shaped spring hook portion 2 a provided on the main body case 2. The first discharge operation lever 51 is biased forward by a coil spring 55. A fixing pin 57 formed in the main body case 2 is inserted into the guide hole 51d.

  The second discharge operation lever 52 is formed with an insertion hole 52a through which the pin 46 is inserted, a spring hook portion 52b, and an opening 52c into which the protrusion 51c is inserted. Further, the second discharge operation lever 52 is formed with a clutch projection 52d for pushing up the first transmission gear 41 to a meshing position for meshing with the second transmission gear 42, and a boss 52e for swinging the meshing release lever 53. ing. One end of a coil spring 56 for urging the second discharge operation lever 52 forward is hooked on the spring hook portion 52b. The other end of the coil spring 56 is a hook-like spring hook portion provided in the main body case 2. 2b. The second discharge operation lever 52 can swing around the pin 46 against the coil spring 56 by the difference between the width of the opening 52c and the plate thickness of the protrusion 51c. In FIG. 10, the coil springs 35, 55, and 56 are not shown.

  As shown in FIGS. 12 and 13, the clutch protrusion 52 d escapes from below the large-diameter gear 41 b and allows the first transmission gear 41 to descend when the second discharge operation lever 52 moves rearward. . When the first transmission gear 41 is lowered, the meshing of the small diameter gear 41a and the large diameter gear 42a is released. On the contrary, when the second discharge operation lever 52 moves forward, the clutch protrusion 52d enters under the large-diameter gear 41b and raises the first transmission gear 41. The clutch protrusion 52d has an inclined surface and has a substantially triangular shape so that it can easily enter under the large-diameter gear 41b.

  The mesh release lever 53 is attached to a rectangular support plate 59 fixed to the base panel 6, and has a restoring force (spring force) against swinging around the support plate 59. The mesh release lever 53 includes a rectangular attachment hole 53a into which the support plate 59 is inserted, a rib 53b that contacts the boss 52e, and a tapered push-down projection 53c that forcibly pushes down the first transmission gear 41 to the non-engagement position. And are formed. The rib 53b includes a first inclined portion 53d that swings the mesh release lever 53 counterclockwise by the pressing of the boss 52e, and a second inclined portion 53e that prevents the clockwise swing (return). The pressing protrusion 53c enters the large diameter gear 41b after the clutch protrusion 52d of the second discharge operation lever 52 comes out from under the large diameter gear 41b.

  Next, the operation of the above embodiment will be described. Prior to the insertion of the disk D1, as shown in FIG. 8, the loading slider 34 has moved to the disk ejection position, and the ejection control levers 51 and 52 have been moved forward by the coil springs 55 and 56, respectively. Yes. In this state, as shown in FIG. 12, since the first transmission gear 41 is pushed up to the meshing position by the clutch protrusion 52d, the small-diameter gear 41a is meshed with the large-diameter gear 42a.

  When the disk D1 is inserted from the slot 3a of the bezel 3, the tip side of the disk D1 is supported by the holder 20a of the disk support arm 20, as shown in FIG. In response to the pushing of the disk D1, as shown in FIG. 5, while the link arm 38 is extended against the spring 38c, the disk support arm 20 together with the base portion 20b is centered on the shaft 22 in FIG. Rotate to.

  When the disk support arm 20 is further pushed in, the base portion 20b turns on the switch 39. Based on the signal from the switch 39, the loading motor 31 starts to rotate. The rotation of the loading motor 31 is transmitted to the loading slider 34 via the first transmission gear 41, the second transmission gear 42, and the third transmission gear 43, and the loading slider 34 moves rearward.

  When the loading slider 34 moves rearward, the pin 24a of the link lever 24 is pushed by the cam groove 34c, so that the pin 24a moves along the cam groove 25. As a result, the link lever 24 moves, and the attracting arm 21 swings clockwise in FIG. 4 with the shaft 23 as a fulcrum. In this attracting arm 21, a flanged roller 21a attached to the front end pushes the rear end of the disk D1.

  Further, the loading slider 34 rotates the link lever 36 clockwise in FIG. 4 by the cam groove 34d. The rotation of the link lever 36 is transmitted to the base portion 20b via the link arm 38, and rotates the disk support arm 20 in the clockwise direction in FIG. Accordingly, the disk D1 is held by the disk support arm 20 and the attracting arm 21 and is carried into the main body case 2.

  When the disk D1 is carried into the chucking position, the center hole D1a of the disk D1 coincides with the chucking head 13 as shown in FIG. At this time, the elevating pin 7 b of the elevating frame 7 reaches the inclined portion 34 g of the cam groove 34 e of the loading slider 34. Thereafter, since the lifting pins 7b move along the inclined portion 34g in conjunction with the loading slider 34 in a state where the disk support arm 20 and the attracting arm 21 are stopped, the lifting frame 7 is shown in FIG. Ascend from the lowered position.

  As shown in FIG. 7B, when the elevating frame 7 is raised, the chucking head 13 slightly enters the center hole D1a of the disk D1. When the disk D1 is further pushed up by the chucking head 13, as shown in FIG. 7C, the disk D1 is received by the protruding portion of the inner wall of the main body case 2 formed by the concave portion 9b of the top plate 9, so that the chucking head 13 Fully enters the center hole D1a and is locked by the chucking claw 13a. As shown in FIG. 7D, after the chucking, the elevating frame 7 is slightly lowered so that the disk D1 is separated from the top plate 9, and the elevating pin 7b enters the high position part 34h of the cam groove 34e. As a result, the elevating frame 7 is positioned at the recording / reproducing position slightly lowered from the disk mounting position.

  During the chucking operation, the disk support arm 20 and the attracting arm 21 are stopped. When the chucking is completed, the disk support arm 20 and the attracting arm 21 are released from the disk D1 with the last stroke of the loading slider 34 and released. Since the loading slider 34 turns on the switch (not shown) at the timing when the disc support arm 20 and the attracting arm 21 release the holding of the disc D1, the loading motor 31 stops and the loading of the disc D1 is completed. To do. After loading the disk D1, the disk D1 is rotated at a high speed, and then the head unit 17 is driven to record / reproduce the disk D1.

  When the disk D1 is automatically carried out from the main body case 2, the push button 4 of the bezel 3 is operated or a command from the information device is sent to the disk device 1. A control circuit (not shown) of the disk device 1 first stops the spindle motor 11 and then reverses the loading motor 31. By the reverse rotation of the loading motor 31, the loading slider 34 moves forward.

  When the forward movement of the loading slider 34 is started, the disk support arm 20 and the attracting arm 21 are slightly swung to hold the outer periphery of the disk D1. Next, the elevating frame 7 moves from FIG. 7 (D) toward FIG. 7 (A). First, the elevating frame 7 is lowered after slightly rising from the recording / reproducing position. Then, the lifting frame 7 is lowered to the lowered position. During this lowering, the disk D1 is received by the chucking release pin 14, and therefore the disk D1 is removed from the chucking head 13. After the elevating frame 7 is lowered, the disk support arm 20 and the attracting arm 21 swing again, and the disk D1 is unloaded to the full eject position at the time of automatic unloading shown in FIG.

  At the time of automatic unloading, the loading slider 34 is moved by the loading motor 31. Therefore, when the disk D1 is unloaded from the main body case 2 as shown in FIG. Almost abuts. As a result, when the disc D1 is carried out of the main body case 2 and the erroneous operation of inserting the operation pin 70 into the emergency hole 3b is performed, the first ejecting operation lever 51 does not move and the erroneous operation is performed. Thus, the first discharge operation lever 51, the second discharge operation lever 52, etc. are not damaged.

  During the operation of the disk device 1, the loading motor 31 may not operate due to battery exhaustion, power supply interruption, failure, etc., and the disk D 1 loaded in the main body case 2 may not be automatically carried out. In this case, as shown in FIGS. 14 to 16, the operation pin 70 is inserted into the emergency hole 3b, and the disk D1 is forcibly ejected.

  As shown in FIG. 14, when the operation pin 70 is pushed in, the first discharge operation lever 51 moves backward against the bias of the coil spring 55. When the first discharge operation lever 51 moves about 2 mm (play section), the protrusion 51 c comes into contact with the rear end of the opening 52 c of the second discharge operation lever 52. Thereafter, the second discharge operation lever 52 moves together with the first discharge operation lever 51.

  When the operation pin 70 is further pushed and each of the discharge operation levers 51 and 52 further moves rearward by about 2 mm, the clutch protrusion 52d is separated from the lower surface of the first transmission gear 41 as shown in FIG. It can move downward under its own weight. Simultaneously or immediately after this, as shown in FIG. 14, the boss 52e presses the first inclined portion 53d and the second inclined portion 53e of the rib 53b in this order. When the boss 52e presses the first inclined portion 53d, the mesh release lever 53 swings counterclockwise with the support plate 59 as a fulcrum. By this swinging, the pressing protrusion 53c enters the upper surface of the large-diameter gear 41b of the first transmission gear 41, so that even when the first transmission gear 41 is stopped at the meshing position, it can be pushed down to the non-meshing position. Since the pressing protrusion 53c enters the upper surface of the large diameter gear 41b after the clutch protrusion 52d is separated from the lower surface of the large diameter gear 41b, the clutch protrusion 52d and the pressing protrusion 53c interfere with the first transmission gear 41 and are damaged. In addition, the first transmission gear 41 is pushed down, and the meshing with the second transmission gear 42 is reliably released.

  When the boss 52e swings while pushing the first inclined portion 53d, the boss 52e comes into contact with the second inclined portion 53e which becomes substantially vertical by the swing of the mesh release lever 53. Since the second inclined portion 53e is received by the boss 52e, the mesh release lever 53 is maintained in that position without returning by its own spring force.

  When the first transmission gear 41 is pushed down to the non-engagement position, the transmission gear mechanism 32 is separated into the motor side and the disk transport mechanism side. In the present embodiment, the gear on the motor side is the first transmission gear 41, and the gear on the disk transport mechanism side is the second transmission gear 42 and the third transmission gear 43.

  When the transmission gear mechanism 32 is separated into the motor side and the disk transport mechanism side, the large rotational load on the worm gear 31a is eliminated, and the third transmission gear 43 becomes rotatable. As a result, the loading slider 34 moves forward while rotating the third transmission gear 43 by the stored force of the coil spring 35, and the disk D1 ejecting operation is started.

  As shown in FIG. 15, the engagement of the first transmission gear 41 and the second transmission gear 42 is released while the operation pin 70 is pushed in, but the operation pin 70 is pushed in as it is. For this reason, the discharge operation levers 51 and 52 further move rearward by about 4 mm until the front wall surface of the guide hole 51 d of the first discharge operation lever 51 comes into contact with the fixing pin 57.

  When the loading slider 34 moves forward, the front end surface of the loading slider 34 is received by the receiving portion 51a of the first discharge operation lever 51, and stops at the half eject position. When the loading slider 34 stops at the half-eject position, the disk D1 stops at a position protruding about 20 mm from the bezel 3 as shown in FIG. This prevents the disk D1 from colliding with the finger when the disk D1 is manually ejected to the eject position in an emergency.

  When the operation pin 70 is pulled out from the emergency hole 3 b, the discharge operation levers 51 and 52 are moved forward by the coil springs 55 and 56. Following the movement of the discharge operation levers 51 and 52, the loading slider 34 is also moved forward by the coil spring 35.

  When the second discharge operation lever 52 moves forward following the pulling operation of the operation pin 70, the press of the mesh release lever 53 by the boss 52e is released, and the mesh release lever 53 is restored to the original state as shown in FIG. Return to position. When the mesh release lever 53 returns, the pressing protrusion 53c is separated from the upper surface of the first transmission gear 41, and the first transmission gear 41 can move upward. Thereafter, as shown in FIG. 12, the clutch protrusion 52d comes into contact with the lower surface of the first transmission gear 41, the first transmission gear 41 is pushed up to the meshing position by the clutch protrusion 52d, and the first transmission gear 41 is moved to the second position. Engage with the transmission gear 42.

  When the first transmission gear 41 meshes with the second transmission gear 42, a large load is applied by the worm gear 31a, so that the advancement of the loading slider 34 stops. At this time, the disk D1 is ejected to the fully ejected position shown by the two-dot chain line in FIG.

  When the elevating frame 7 is lifted from the recording / reproducing position shown in FIG. 7D to the disc mounting position shown in FIG. 7C and the disc D1 is strongly pressed against the top plate 9, or the elevating frame 7 is shown in FIG. Immediately after passing through 7 (B), the lower surface of the disk D1 is received by the chucking release pin 14, and only the lifting frame 7 is lowered in a state where the lowering of the disk D1 is prevented, and chucked from the center hole D1a of the disk D1. When the head 13 is extracted, the disk discharge load becomes large, but the driving force of the coil spring 35 is larger than these disk discharge loads. As a result, the loading slider 34 does not stop halfway due to the disc ejection load, and the disc D1 is ejected to the fully ejected position.

  After the meshing between the first transmission gear 41 and the second transmission gear 42 is completed, the forward movement of the second discharge operation lever 52 stops. Thereafter, only the first discharge operation lever 51 moves forward further. For this reason, when the disk D1 is forcibly ejected, the tip of the loading slider 34 is slightly separated from the receiving portion 51a of the first ejection operation lever 51 as shown in FIG.

  In the above embodiment, the receiving portion 51a of the first discharge operation lever 51 receives both the loading slider 34 and the operation pin 70. However, the receiving portion that receives the loading slider 34 and the reception that receives the operation pin 70 are also received. The sections may be provided individually.

  Further, in the above embodiment, when the discharge operation levers 51 and 52 move rearward, the meshing between the first transmission gear 41 and the second transmission gear 42 is released. 3 The meshing with the transmission gear 43 may be released.

  Further, instead of the mesh release lever 53, a spring that biases the first transmission gear 41 toward the non-mesh position may be provided.

DESCRIPTION OF SYMBOLS 1 Disc apparatus 2 Main body case 3a Slot 20 Disc support arm 21 Attraction arm 31 Loading motor 32 Transmission gear mechanism 33 Disc conveyance mechanism 34 Loading slider 35 Coil spring 41 First transmission gear 42 Second transmission gear 43 Third transmission gear 51 First discharge Operation lever 51a Receiving portion 52 Second discharge operation lever 52d Clutch protrusion 55, 56 Coil spring 70 Operation pin D1 Disc

Claims (4)

In the disk device in which the disk is loaded into the main body case through the slot,
A loading slider that moves in the front-rear direction by a motor; and when the loading slider moves backward, the disk is loaded into the main body case, and when the loading slider moves forward, the disk is moved to the main body. A disc transport mechanism to carry out of the case;
A first spring that biases the loading slider forward;
A transmission gear mechanism having a plurality of gears for transmitting rotation of the motor to the loading slider;
A discharge operation means that moves backward by being pushed by an operation member inserted from the front surface of the main body case,
A second spring that biases the discharging operation means forward;
Provided in the discharge operation means, while the discharge operation means moves backward, the first gear in the transmission gear mechanism is moved from the meshing position to the non-meshing position, and the transmission gear mechanism is transported to the disk. Clutch means for separating the mechanism side and the motor side, and returning the first gear to the meshing position while the discharge operation means returns to the front;
The discharging operation means is provided to receive the loading slider that has moved forward by the first spring after the first gear has moved to the non-engagement position, and when the discharging operation means returns to the front. Stop means for allowing the loading slider to move forward following the discharge operation means until the first gear moves to the meshing position;
A disk device comprising:   The discharge operation means includes a first discharge operation lever that is pushed by the operation member, and a second discharge operation lever that is pushed and moves together after the first discharge operation lever moves in a predetermined play section. The disk device according to claim 1.   The stop means is a receiving portion that stands vertically from the first discharge operation lever, and a front surface of the receiving portion is pushed by the operation member, and a rear surface receives the loading slider. The disk device described.   2. The loading slider according to claim 1, wherein when the loading slider is driven by the motor via the transmission gear mechanism to automatically carry out the disk, the leading end of the loading slider moves forward to a position where it substantially contacts the stop means. The disk device according to any one of 1 to 3.

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