JP2007102939A - Disk drive - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To create forces of two directions to be applied to an arm for detecting the loading completion of a recording disk by simple constitution. <P>SOLUTION: When a trigger plate 46 is located on a rear position P1, a depression control part 44 formed on the left side end part of an eject arm 41 is brought into contact with a trigger pin 47 of a trigger plate 46. When the eject arm 41 is rotated in the counterclockwise direction in this state, the depression control part 44 depresses the trigger pin 47, the trigger plate 46 is moved in the forward direction and a spring 49 is extended. Thereby tensile force for rotating the eject arm 41 in the clockwise direction is created by the spring 49. When the trigger plate 46 is moved forward up to a front position P3 by a pinion 66 on the other hand, the depression control part 44 is separated from the trigger pin 47, the spring 49 is extended and tensile force for rotating the eject arm 41 in the counterclockwise direction is created. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a disk drive such as a DVD drive or a CD (Compact Disc) drive.

  A disk drive that reads or records information from a recording disk such as a DVD, CD, Blu-ray disk, or magnetic disk is used in various apparatuses such as a disk player, a disk recorder, an audio system, a personal computer, and a car navigation system. Yes.

  There are two types of disk drives: a type in which a recording disk can be attached / detached as in a general optical disk drive, and a type in which a recording disk cannot be attached / detached, such as a general hard disk drive. Further, the type of disk drive to which a recording disk can be attached / detached includes a slot-in system, a drawer system, a tray system, and the like regarding a recording disk attachment / detachment system.

  The slot-in type disk drive has a structure in which the recording disk is pulled into the disk drive using a loading arm during loading, and the recording disk is pushed out of the disk drive using the ejection arm during ejection. There is something.

  For example, the operation at the time of loading of this type of disk drive is as follows. When the user inserts the recording disk into the disk slot, the peripheral edge of the recording disk comes into contact with a roller provided at the tip of each loading arm, thereby pushing the loading arm and slightly rotating the loading arm. This triggers the motor to start and the rollers start rotating. Then, the recording disk is pulled into the disk drive by the rotation of the roller. As the recording disk is pulled, the loading arm further rotates and the loading arm opens. When the recording disk approaches the pull-in completion position, the recording disk comes into contact with the tip of the eject arm provided at the back (inner rear side) of the disk drive, thereby pushing the eject arm and rotating the eject arm. When the recording disk reaches the pull-in completion position, that is, the clamp position on the turntable, the eject arm rotates by a predetermined angle, thereby detecting that the recording disk has reached the pull-in completion position. Based on this detection, the recording disk is clamped. When the clamping operation is completed, the loading arm and the eject arm are separated from the peripheral edge of the recording disk. After this, the motor stops and the rotation of the rollers stops. As a result, the recording disk can be rotated at a high speed on the turntable.

  In addition, the ejection operation of this type of disk drive is as follows, for example. When an instruction to eject (eject) the recording disk clamped in the disk drive is issued, the motor starts and the roller starts rotating. Then, the clamp is released, and the eject arm and the loading arm come into contact with the peripheral edge of the recording disk. Further, the eject arm pushes the recording disk toward the disk slot. The recording disk is conveyed toward the outside of the disk drive through the disk slot by the rotation of the roller. As the recording disk is conveyed, the loading arm rotates and the loading arm closes. When the recording disk reaches an appropriate stop position in the vicinity of the disk slot, the motor stops and the rotation of the roller stops. As a result, the recording disk stops at an appropriate position near the disk slot.

  By the way, the eject arm detects the completion of drawing of the recording disk by bringing one end side into contact with the rear peripheral edge of the recording disk during loading, and at the time of clamping, the one end side is separated from the rear peripheral edge of the recording disk. Create a state that can rotate at high speed on the turntable.

  Therefore, at the time of loading, in order to bring one end of the eject arm into contact with the rear peripheral edge of the recording disk, it is desirable to apply a force to the eject arm so that the eject arm rotates in a direction in which the one end of the eject arm advances.

  On the other hand, at the time of clamping, it is desirable to apply a force to the eject arm so that the eject arm rotates in a direction in which the one end side of the eject arm moves backward in order to separate the one end side of the eject arm from the rear peripheral edge of the recording disk.

  That is, the direction of the force applied to the eject arm is opposite between loading and clamping.

  Such application of force to the eject arm is often performed using a spring. If the direction in which the force is applied to the eject arm is opposite between loading and clamping, a complex structure such as using multiple springs to switch the urging force of these springs between loading and clamping. There is a risk that it must be adopted.

  If the structure of the disk drive becomes complicated, it may be difficult to reduce the number of parts, to make the disk drive smaller, thinner, lighter, or to reduce manufacturing costs.

  The present invention has been made in view of the above-described problems, and an object of the present invention is to create a disk that can generate a force in two directions applied to an arm that detects completion of drawing of a recording disk with a simple configuration. To provide a drive.

  In order to solve the above problems, a disk drive according to claim 1 is a disk drive that reads or records information on a recording disk, and is rotatable with respect to a substrate and a support shaft. A first end portion that is supported and extends from the support shaft to one side in the left-right direction and detects the completion of drawing of the recording disk by contacting the rear edge of the recording disk at the time of loading; An arm having a second end extending to the other side, a spring connecting portion formed between the support shaft and the second end, and supported by the base plate so as to be movable in the front-rear direction; A moving member that moves forward from the intermediate position to the front position, and a second end of the arm that is provided at the second end of the arm, and the advance of the second end caused by the rotation of the arm, Transfer A pushing control unit that pushes the member from the rear position to the intermediate position, and a conveyance mechanism that conveys the moving member pushed to the intermediate position by the pushing control unit from the intermediate position to the front position; One end side is connected to the spring connecting portion of the arm, the other end side is connected to the moving member, and the spring pulls the spring connecting portion of the arm when the moving member moves in the forward direction.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

(Overall configuration and operation of the disk drive)
FIG. 1 shows an embodiment of a disk drive of the present invention. A disk drive 10 in FIG. 1 is a device that reads or records information on a recording disk such as a DVD, CD, or Blu-ray disk. The disk drive 10 is a type in which a recording disk can be attached and detached, and adopts a slot-in method for attaching and detaching the recording disk.

  The disk drive 10 can read or record information on a plurality of types of recording disks having different diameters. For example, information can be read or recorded on both a recording disk 1 having a diameter of 8 cm (see FIG. 2) and a recording disk 2 having a diameter of 12 cm (see FIG. 7).

  As shown in FIG. 1, the outer shell of the disk drive 10 includes a chassis 11 and a front cover 12.

  The chassis 11 is made of, for example, a metal material, has a bottom plate, and has side plates and a ceiling plate as necessary.

  The front cover 12 is made of, for example, a resin material. A disk slot 13 is formed in the front cover 12. The disk slot 13 is a groove through which the recording disk passes when loading and ejecting the recording disk.

  In the following description, the arrow X direction in FIG. 1 is referred to as the left-right direction, the arrow Y direction is referred to as the front-rear direction, and the arrow Z direction is referred to as the up-down direction.

  FIG. 2 shows the inside of the disk drive 10. As shown in FIG. 2, the disk drive 10 includes a pair of loading arms 21, 21, a rack plate 31, a select plate 37, an eject arm 41, a trigger plate 46, a first shift bar 51, a second shift bar 55, a traverse mechanism 61, A motor 65, a pinion 66, a switch unit 69, a control circuit 75, and the like are provided.

  The loading arms 21 and 21 are arranged symmetrically at positions near the disk slot 13 on the front side of the disk drive 10. Each loading arm 21 is rotatably supported on the chassis 11 via a support shaft 22. Each loading arm 21 is made of, for example, a resin material or a metal material.

  A roller 23 is rotatably attached to the top surface of the tip of each loading arm 21. The roller 23 is rotated by a motor 65. The left roller 23 contacts the left peripheral edge of the recording disk. The right roller 23 contacts the right peripheral edge of the recording disk.

  The loading arms 21 and 21 sandwich the recording disk via the rollers 23 and 23 and transport the recording disk. The loading arms 21 and 21 rotate as the recording disk advances or retreats, whereby the leading ends of the loading arms 21 and 21 are opened and closed.

  A gear 24 is fixed to the lower surface of the shaft portion of each loading arm 21. The left gear 24 meshes with the left rack portion 31 </ b> A of the rack plate 31 through the pinion 25. The right gear 24 directly meshes with the right rack portion 31 </ b> B of the rack plate 31. The gear 24, the pinion 25, and the rack portions 31A and 31B convert the rotation of each loading arm 21 into the movement of the rack plate 31 in the left-right direction. Specifically, the rotation of each loading arm 21 when each loading arm 21 is opened is converted into the leftward movement of the rack plate 31, and the rotation of each loading arm 21 when each loading arm 21 is closed is the rack. This is converted into a rightward movement of the plate 31.

  The rack plate 31 is located in the vicinity of the disk slot 13 on the front side of the disk drive 10 and is disposed between the chassis 11 and the loading arms 21 and 21. The rack plate 31 is supported by the chassis 11 so as to be movable in the left-right direction. The rack plate 31 is made of, for example, a metal material. The rack plate 31 is formed with a pair of rack portions 31A and 31B.

  A switching edge 32 is formed at the right rear portion of the rack plate 31. The switching edge 32 extends linearly in the left-right direction. When the switching edge 32 moves in the left-right direction due to the movement of the rack plate 31 in the left-right direction, the presence or absence of contact between the switching edge 32 and the switching lever of the first switch 71 changes, and thereby the first switch 71 is switched on and off. . Further, when the switching edge 32 moves in the left-right direction due to the movement of the rack plate 31 in the left-right direction, the presence / absence of contact between the switching edge 32 and the switching lever of the second switch 72 changes, and thereby the second switch 72 is turned on / off. Switches.

  A select cam groove 33 is formed in the left rear portion of the rack plate 31. A select pin 38 of a select plate 37 is inserted into the select cam groove 33. In addition, two retraction control grooves, that is, a first retraction control groove 34 and a second retraction control groove 35 are formed on the left rear portion of the rack plate 31. When the rack plate 31 moves leftward and the first shift bar 51 moves forward, the retraction control pin 53 of the first shift bar 51 enters one of the retraction control grooves 34 and 35.

  The select plate 37 is disposed on the left side of the disk drive 10. The select plate 37 is supported by a motor blanket (not shown) fixed to the chassis 11 so as to be movable in the front-rear direction. Thereby, the select plate 37 can move in the front-rear direction with respect to the chassis 11. The select plate 37 is made of, for example, a metal material. On the left side of the disk drive 10, several members overlap in the vertical direction. The select plate 37 is generally positioned below the rack plate 31, the trigger plate 46 and the second shift bar 55 and positioned above the pinion 66.

  A select pin 38 is provided on the front upper surface of the select plate 37. One end of the select pin 38 extends upward, is inserted into the select cam groove 33 of the rack plate 31, and the other end is fixed to the select plate 37. The select pin 38 and the select cam groove 33 convert the movement of the rack plate 31 in the left-right direction into the movement of the select plate 37 in the front-rear direction. Specifically, the select pin 38 and the select cam groove 33 convert the leftward movement of the rack plate 31 into the rearward movement of the select plate 37 and the rightward movement of the rack plate 31 in front of the select plate 37. Convert to moving direction.

  A stopper 39 for restricting the rotation of the eject arm 41 is provided on the upper surface on the rear side of the select plate 37. The upper end side of the stopper 39 extends upward, and the lower end side passes through a through groove 91 (see FIG. 12) formed in the select plate 37 and is fixed to a motor blanket (not shown).

  The eject arm 41 detects that the recording disk has been pulled in by one end contacting the rear peripheral edge of the recording disk during loading and moves the recording disk forward by pushing the rear peripheral edge of the recording disk during ejection. Let The eject arm 41 is rotatably supported on the upper surface of the rear part of the select plate 37. The eject arm 41 is made of, for example, a metal material or a resin material. The eject arm 41 rotates around the support shaft 42. The support shaft 42 of the eject arm 41 moves in the front-rear direction as the select plate 37 moves in the front-rear direction. A contact member 43 is attached to the upper surface of one end side of the eject arm 41. The contact member 43 contacts the periphery of the recording disk.

  Further, a push control unit 44 is formed on the other end side of the eject arm 41. When the eject arm 41 rotates backward, the push control unit 44 moves forward, pushes the trigger pin 47 of the trigger plate 46, and pushes the trigger plate 46 forward.

  The trigger plate 46 is located above the rear portion of the select plate 37 and is attached to a motor blanket (not shown) fixed to the chassis 11 so as to be movable in the front-rear direction. The trigger plate 46 is made of, for example, a metal material. The trigger plate 46 can move in the front-rear direction with respect to the select plate 37 above the select plate 37. The trigger plate 46 is connected to an select arm 37 that is rotatably attached to a select plate 37 via a support shaft 42 via a coil spring 49. Therefore, the trigger plate 46 moves in the front-rear direction together with the eject arm 41 as the select plate 37 moves in the front-rear direction.

  The trigger plate 46 is disposed so as to cover the select plate 37 and the eject arm 41. However, the rack portion 46 </ b> A formed at the front right edge portion of the trigger plate 46 descends from the trigger plate 46 near the right edge of the select plate 37 and sinks below the select plate 37. The rack portion 46A meshes with a pinion 66 disposed below the select plate 37 when the trigger plate 46 advances.

  A trigger pin 47 is provided on the rear lower surface of the trigger plate 46. One end side of the trigger pin 47 extends downward, and the other end side is fixed to the lower surface of the trigger plate 46. One end side of the trigger pin 47 extends to a position where it can come into contact with the push control unit 44 of the eject arm 41.

  A first transmission pin 48 is provided on the front right edge of the trigger plate 46. One end side of the transmission pin 48 extends rightward and is inserted into the transmission groove 51 </ b> A of the first shift bar 51. The other end of the transmission pin 48 is fixed to the right edge of the trigger plate 46.

  A coil spring 49 is attached between the eject arm 41 and the trigger plate 46. The coil spring 49 pulls the other end side of the eject arm 41 forward.

  The first shift bar 51 is supported on the chassis 11 so as to be movable in the front-rear direction. The shift bar 51 is formed of, for example, a resin material and is thicker than the rack plate 31 and the select plate 37 that are metal plates, for example.

  A transmission groove 51 </ b> A is formed on the left side surface of the first shift bar 51. The transmission groove 51A extends substantially parallel to the bottom plate of the chassis in the front-rear direction. A transmission pin 48 of the trigger plate 46 is inserted into the transmission groove 51A. A second transmission pin 52 is provided on the front upper surface of the shift bar 51. One end side of the transmission pin 52 extends upward and is inserted into the transmission slot 55 </ b> A of the second shift bar 55, and the other end side is fixed to the upper surface of the shift bar 51. A retraction control pin 53 is provided on the front upper surface of the first shift bar 51. One end of the retraction control pin 53 extends upward to a position where it can come into contact with the retraction control grooves 34, 35 of the rack plate 31, and the other end is fixed to the upper surface of the shift bar 51. The retraction control pin 53 enters one of the retraction control grooves 34 and 35 of the rack plate 31 when the rack plate 31 moves leftward and the first shift bar 51 moves forward. The retraction control pin 53 and the retraction control grooves 34 and 35 further move the rack plate 31 moved leftward during the loading process to the left during clamping.

  The second shift bar 55 is supported on the chassis 11 so as to be movable in the left-right direction. The shift bar 55 is formed of, for example, a resin material and is thicker than the rack plate 31 and the select plate 37 that are metal plates, for example.

  A transmission slot 55 </ b> A is formed at the left end of the second shift bar 55. The second transmission pin 52 of the first shift bar 51 is inserted into the transmission slot 55A. An elevating groove 55 </ b> B is formed on the rear side surface of the second shift bar 55. The elevating groove 55B is a cam groove for elevating the traverse mechanism 61 by moving the shift bar 55 in the left-right direction, and the right end is at the low position and the left end is at the high position. Elevating pins 64 attached to the traverse mechanism 61 are inserted into the elevating grooves 55B.

  A switching stick 56 is formed at the right end of the second shift bar 55. The switching stick 56 extends linearly in the left-right direction. When the switching stick 56 moves in the left-right direction due to the movement of the shift bar 55 in the left-right direction, the presence / absence of contact between the switching stick 56 and the switching lever of the third switch 73 changes, whereby the third switch 73 is turned on / off.

  The traverse mechanism 61 is provided with a turntable 62, an optical pickup 63, and the like. The motor 65 rotationally drives the pinion 66 and rotationally drives the roller 23 of each loading arm 21. The pinion 66 is disposed below the select plate 37. As described above, the select plate 37 and the trigger plate 46 move in the front-rear direction, but the axis of the pinion 66 does not move. The pinion 66 transmits the power of the motor 65 to the trigger plate 46 during the clamping operation, and moves the second shift bar 55, the first shift bar 51, the traverse mechanism 61, and the like.

  Note that the trigger plate 46, the first shift bar 51, the second shift bar 55, the lift pin 64, the motor 65, the pinion 66, the turntable 62, and a clamper provided above the turntable 62 so as to face the turntable 62 (see FIG. (Not shown) etc. constitute a clamping mechanism.

  The switch unit 69 is disposed on the right side of the disk drive 10. The switch unit 69 includes a switch board 70, a first switch 71, a second switch 72, a third switch 73, and wiring. The switches 71 to 73 and the wiring are provided on the switch board 70.

  Each switch 71, 72, 73 is provided with a switching lever. Push the switch lever to turn it on. When you release the switch lever, the switch lever automatically rises and the switch turns off. The switching levers of the first switch 71 and the second switch 72 are pushed in when the switching edge 32 of the rack plate 31 contacts. That is, the first switch 71 and the second switch 72 are switched on and off depending on the presence or absence of contact with the switching edge 32. On the other hand, the switching lever of the third switch 73 is pushed in when the switching stick 56 of the second shift bar 55 contacts. In other words, the third switch 73 is switched on and off depending on the presence or absence of contact with the switching stick 56.

  The control circuit 75 controls the driving of the motor 65 during loading, clamping and ejection based on the on / off states of the switches 71 to 73. Specifically, the control circuit 75 receives output signals output from the switches 71 to 73, respectively. Then, the control circuit 75 outputs a drive signal for driving the motor 65 to the motor 65.

  Further, the control circuit 75 includes a disk identification circuit 76. The disc identification circuit 76 identifies the type of the recording disc using the on / off state of the second switch 72 when the recording disc is at the clamp position. The disc identification circuit 76 outputs an identification signal indicating the identification result of the type of the recording disc. This identification signal is used in the control circuit 75 for driving control of the motor 65.

  When the recording disk 1 having a diameter of 8 cm is inserted into the disk drive 10, the disk drive 10 operates as follows, for example.

  As shown in FIG. 3, when the recording disk 1 is inserted into the disk drive 10, the periphery of the recording disk 1 contacts the roller 23 of each loading arm 21 and pushes each loading arm 21 backward. Thereby, each loading arm 21 opens. When each loading arm 21 is opened, the rack plate 31 moves to the left by the meshing of the gear 24, the pinion 25, and the rack portions 31A and 31B. When the rack plate 31 moves, the switching edge 32 is separated from the switching lever of the first switch 71, and the first switch 71 is switched from on to off. In response to this, the control circuit 75 starts driving the motor 65. Thereby, the roller 23 of each loading arm 21 starts rotating, and the recording disk 1 is drawn into the disk drive 10 by the rotation of the roller 23.

  As the recording disk 1 is drawn and the recording disk 1 is conveyed backward, each loading arm 21 is further opened, and the rack plate 31 is further moved leftward. Eventually, the rear edge of the recording disk 1 comes into contact with the contact member 43 of the eject arm 41, and the one end side of the eject arm 41 is retracted. When one end side of the eject arm 41 moves backward, the other end side of the eject arm 41 moves forward, and the push control unit 44 of the eject arm 41 pushes the trigger pin 47 to move the trigger plate 46 forward.

  As shown in FIG. 4, when the recording disk 1 is transported to the clamp position and one end side of the eject arm 41 is retracted to a predetermined position, the trigger plate 46 is advanced to a predetermined position by the advancement of the push control unit 44. . When the trigger plate 46 moves forward to a predetermined position, the rack portion 46A of the trigger plate 46 meshes with the pinion 66. The pinion 66 is always rotating while the motor 65 is driven. When the rack portion 46 </ b> A of the trigger plate 46 is engaged with the pinion 66, the trigger plate 46 is further advanced by the rotation of the pinion 66. That is, at the moment when the rack portion 46 </ b> A of the trigger plate 46 is engaged with the pinion 66, the power source that advances the trigger plate 46 is switched from the pressing force of the pressing control unit 44 to the rotation of the pinion 66.

  As shown in FIG. 5, when the trigger plate 46 moves forward and the transmission pin 48 of the trigger plate 46 hits a stopper in the transmission groove 51A of the first shift bar 51 (for example, the inner wall of the front end of the transmission groove 51A), the first shift bar 51 also moves forward. To do. When the first shift bar 51 moves forward, the second shift bar 55 moves rightward by the transmission pin 52 of the first shift bar 51. When the second shift bar 55 moves to the right, the switching stick 56 also moves to the right. As a result, the right end of the switching stick 56 contacts the switching lever of the third switch 73, and the third switch 73 is switched from OFF to ON. When the third switch 73 is switched from OFF to ON, the control circuit 75 stops driving the motor 65. Thereby, the rotation of the roller 23 of each loading arm 21 and the rotation of the pinion 66 are stopped.

  When the second shift bar 55 moves to the right, the lift pins 64 inserted into the lift grooves 55B of the second shift bar 55 are lifted, and the traverse mechanism 61 is raised accordingly. As a result, the recording disk 1 is clamped between the turntable 62 and a clamper (not shown) disposed above the turntable 62.

  At this time, the retraction control pin 53 of the first shift bar 51 enters the first retraction control groove 34 of the rack plate 31 as the first shift bar 51 advances. Then, when the retraction control pin 53 pushes the inclined edge of the first retraction control groove 34, the rack plate 31 further moves leftward. Thereby, each loading arm 21 is further opened, the roller 23 of each loading arm 21 is separated from the peripheral edge of the recording disk 1, and an appropriate clearance is secured between the roller 23 of each loading arm 21 and the peripheral edge of the recording disk 1. The

  Further, when the rack plate 31 moves to the left by the entry of the retraction control pin 53 into the first retraction control groove 34, the select pin 38 of the select plate 37 is an inclined groove portion formed near the center of the select cam groove 33 in the left-right direction. The select plate 37 is slightly retracted by being slightly pushed backward by a part of the plate. When the select plate 37 is retracted small, the support shaft 42 of the eject arm 41 is also retracted small. At this time, the other end side of the eject arm 41 is pulled by a coil spring 49 extended by the advance of the trigger plate 46. For this reason, the eject arm 41 rotates counterclockwise, one end side of the eject arm 41 moves backward, and the contact member 43 of the eject arm 41 moves away from the periphery of the recording disk 1. Thereby, an appropriate clearance is ensured between the contact member 43 of the eject arm 41 and the peripheral edge of the recording disk 1.

  As shown in FIG. 5, when the clamping of the recording disk 1 is completed and the eject arm 41 and each loading arm 21 are retracted, the spindle motor 65 (not shown) starts driving, the turntable 62 rotates, and the recording disk 1 rotates. Then, information is read from or recorded on the recording disk 1 by the optical pickup 63.

  When reading or writing of information to the recording disk 1 is completed and an instruction to eject the recording disk 1 is given, the motor 65 is started in response to this instruction. The rotation direction of the motor 65 at this time is the opposite direction to that during loading. Then, the pinion 66 starts reverse rotation, whereby the first shift bar 51 and the trigger plate 46 are moved backward. Further, the second shift bar 55 moves to the left, the switching stick 56 moves to the left, the switching stick 56 moves away from the switching lever of the third switch 73, and the third switch 73 switches from on to off. Further, the traverse mechanism 61 is lowered. Further, the retraction control pin 53 of the first shift bar 51 retreats from the first retraction control groove 34 of the rack plate 31, and the rack plate 31 moves rightward by the force of a spring (not shown). As a result, each loading arm 21 is closed, and the roller 23 of each loading arm 21 comes into contact with the periphery of the recording disk 1. Further, when the trigger plate 46 is retracted, the eject arm 41 is rotated clockwise, one end side of the eject arm 41 is advanced, and the contact member 43 is in contact with the peripheral edge of the recording disk 1. Further, each roller 23 starts reverse rotation when the motor 65 starts rotating.

  Then, the recording disk 1 is pushed by the contact member 43 of the eject arm 41 and further conveyed forward by the reverse rotation of the roller 23 of each loading arm 21.

  As shown in FIG. 6, as the recording disk 1 is conveyed in the forward direction, the leading end side of each loading arm 21 is closed and the rack plate 31 is moved in the right direction. Then, the switching edge 32 of the rack plate 31 contacts the switching lever of the first switch 71, and the first switch 71 is switched from OFF to ON. When the first switch 71 is switched from OFF to ON, the control circuit 75 stops driving the motor 65. Thereby, the rotation of the roller 23 of each loading arm 21 is stopped, and the recording disk 1 is stopped at the ejection completion position.

  As for the ejection completion position, for example, in any recording disk, a portion corresponding to about 3/5 to 3/4 of the surface area is exposed to the outside from the disk slot 13 and the remaining portion is the disk drive 10. It is desirable that the position stays inside. As a result, it is possible to prevent the recording disk from dropping out of the disk slot 13 during ejection, and to make it easier for the user to take out the ejected recording disk by hand.

  Thereafter, when the user pushes the recording disk 1 stopped at the ejection completion position into the disk drive 10 again, each loading arm 21 is thereby opened, the rack plate 31 is moved leftward, and the first switch 71 is turned on. Is switched to OFF and the driving of the motor 65 is started. As a result, the rotation of the roller 23 of each loading arm 21 starts, and the recording disk 1 is drawn into the disk drive 10 again.

  When the recording disk 2 having a diameter of 12 cm is inserted into the disk drive 10, the disk drive 10 operates as follows, for example.

  As shown in FIG. 7, when the recording disk 2 is inserted into the disk drive 10, the peripheral edge of the recording disk 2 contacts the roller 23 of each loading arm 21 and pushes each loading arm 21 backward. Thereby, each loading arm 21 opens. When each loading arm 21 is opened, the rack plate 31 moves to the left by the meshing of the gear 24, the pinion 25, and the rack portions 31A and 31B. When the rack plate 31 moves, the switching edge 32 is separated from the switching lever of the first switch 71, and the first switch 71 is switched from on to off. As a result, the control circuit 75 starts driving the motor 65. Thereby, the roller 23 of each loading arm 21 starts rotating, and the recording disk 2 is drawn into the disk drive 10 by the rotation of the roller 23.

  As shown in FIG. 8, as the recording disk 2 is drawn and the recording disk 2 is conveyed backward, the loading arm 21 is further opened, and the rack plate 31 is further moved leftward. Then, the switching edge 32 is separated from the switching lever of the second switch 72, and the second switch 72 is switched from on to off. The control circuit 75 does not change the operation due to the switching of the second switch 72 at this time. Therefore, the motor 65 continues to rotate and the recording disk 2 continues to be conveyed.

  The opening of the loading arms 21 and 21 when the recording disk 2 having a diameter of 12 cm is conveyed is larger than the opening of the loading arms 21 and 21 when the recording disk 1 having a diameter of 8 cm is conveyed. As a result, the amount of movement of the rack plate 31 when the recording disk 2 having a diameter of 12 cm is conveyed is larger than the amount of movement of the rack plate 31 when the recording disk 1 having a diameter of 8 cm is conveyed. Thus, when the rack plate 31 is moved largely to the left, the select pin 38 inserted into the select cam groove 33 of the rack plate 31 is formed by all the inclined grooves formed near the center of the select cam groove 33 in the left-right direction. The select plate 37 is largely retracted by being largely pushed backward. Thereby, the support shaft 42 of the eject arm 41 is largely retracted, and the trigger plate 46 is also retracted greatly.

  When the recording disk 2 continues to be conveyed, the rear peripheral edge of the recording disk 2 comes into contact with the contact member 43 of the eject arm 41 and the one end side of the eject arm 41 is moved backward. When one end side of the eject arm 41 moves backward, the other end side of the eject arm 41 moves forward, and the push control unit 44 of the eject arm 41 pushes the trigger pin 47 to move the trigger plate 46 forward.

  As shown in FIG. 9, when the recording disk 2 is transported to the clamp position and one end side of the eject arm 41 is thereby retracted to a predetermined position, the trigger plate 46 is advanced to a predetermined position by the advancement of the push control unit 44. . When the trigger plate 46 moves forward to a predetermined position, the rack portion 46A of the trigger plate 46 meshes with the pinion 66. When the rack portion 46 </ b> A of the trigger plate 46 is engaged with the pinion 66, the trigger plate 46 is further advanced by the rotation of the pinion 66.

  As shown in FIG. 10, when the trigger plate 46 moves forward and the transmission pin 48 of the trigger plate 46 hits the front end inner wall of the transmission groove 51A of the first shift bar 51, for example, the first shift bar 51 also moves forward. When the first shift bar 51 moves forward, the second shift bar 55 moves rightward by the transmission pin 52 of the first shift bar 51. When the second shift bar 55 moves to the right, the switching stick 56 also moves to the right. As a result, the right end of the switching stick 56 contacts the switching lever of the third switch 73, and the third switch 73 is switched from OFF to ON. When the third switch 73 is switched from OFF to ON, the control circuit 75 stops driving the motor 65. Thereby, the rotation of the roller 23 of each loading arm 21 and the rotation of the pinion 66 are stopped.

  When the second shift bar 55 moves to the right, the lift pins 64 inserted into the lift grooves 55B of the second shift bar 55 are lifted, and the traverse mechanism 61 is raised accordingly. As a result, the recording disk 2 is clamped between the turntable 62 and a clamper (not shown) disposed above the turntable 62.

  At this time, the retraction control pin 53 of the first shift bar 51 enters the second retraction control groove 35 of the rack plate 31 as the first shift bar 51 advances. Then, when the retraction control pin 53 pushes the inclined edge of the second retraction control groove 35, the rack plate 31 further moves leftward. Thereby, each loading arm 21 is further opened, the roller 23 of each loading arm 21 is separated from the peripheral edge of the recording disk 2, and an appropriate clearance is secured between the roller 23 of each loading arm 21 and the peripheral edge of the recording disk 2. The

  Further, when the rack plate 31 moves to the left due to the retraction control pin 53 entering the second retraction control groove 35, the select pin 38 of the select plate 37 is moved backward by the groove portion formed at the right end portion of the select cam groove 33. Slightly pushed in the direction, the select plate 37 is retracted slightly. When the select plate 37 is retracted small, the support shaft 42 of the eject arm 41 is also retracted small. At this time, the other end side of the eject arm 41 is pulled by a coil spring 49 extended by the advance of the trigger plate 46. For this reason, the eject arm 41 rotates counterclockwise, one end side of the eject arm 41 moves backward, and the contact member 43 of the eject arm 41 moves away from the periphery of the recording disk 2. Thereby, an appropriate clearance is secured between the contact member 43 of the eject arm 41 and the periphery of the recording disk 2.

  As shown in FIG. 10, when the clamping of the recording disk 2 is completed and the ejection arm 41 and each loading arm 21 are retracted, the spindle motor 65 (not shown) starts to drive, the turntable 62 rotates, and the recording disk 2 rotates. Then, information is read from or recorded on the recording disk 2 by the optical pickup 63.

  When reading or writing of information to the recording disk 2 is completed and an instruction to eject the recording disk 2 is given, the motor 65 is started in response to this instruction. The rotation direction of the motor 65 at this time is the opposite direction to that during loading. Then, the pinion 66 starts reverse rotation, whereby the first shift bar 51 and the trigger plate 46 are moved backward. Further, the second shift bar 55 moves to the left, the switching stick 56 moves to the left, the switching stick 56 moves away from the switching lever of the third switch 73, and the third switch 73 switches from on to off. Further, the traverse mechanism 61 is lowered. Further, the retraction control pin 53 of the first shift bar 51 retreats from the second retraction control groove 35 of the rack plate 31, and the rack plate 31 moves rightward by the force of a spring (not shown). As a result, each loading arm 21 is closed, and the roller 23 of each loading arm 21 comes into contact with the periphery of the recording disk 2. Further, when the trigger plate 46 is retracted, the eject arm 41 is rotated clockwise, one end side of the eject arm 41 is advanced, and the contact member 43 contacts the periphery of the recording disk 2. Further, each roller 23 starts reverse rotation when the motor 65 starts rotating.

  Then, the recording disk 2 is pushed by the eject arm 41 and further conveyed forward by the reverse rotation of the roller 23 of each loading arm 21.

  As shown in FIG. 11, as the recording disk 2 is conveyed in the forward direction, the leading end side of each loading arm 21 is closed and the rack plate 31 is moved in the right direction. Then, the switching edge 32 of the rack plate 31 contacts the switching lever of the second switch 72, and the second switch 72 is switched from OFF to ON. When the second switch 72 is switched from OFF to ON, the control circuit 75 stops driving the motor 65. Thereby, the rotation of the roller 23 of each loading arm 21 is stopped, and the recording disk 2 is stopped at the ejection completion position.

  Thereafter, when the user pushes the recording disk 2 stopped at the ejection completion position into the disk drive 10 again, each loading arm 21 is thereby opened, the rack plate 31 is moved leftward, and the second switch 72 is turned on. Is switched to OFF and the driving of the motor 65 is started. As a result, the recording disk 2 is again drawn into the disk drive 10 by the rotation of the roller 23 of each loading arm 21.

(Applying force to the eject arm)
FIG. 12 shows the state of the eject arm 41 in three scenes. That is, the left side in FIG. 12 shows the state of the eject arm 41 when the recording disk is not inserted into the disk drive 10. The center in FIG. 12 shows the state of the eject arm 41 when, for example, the recording disk 2 is transported to the pull-in completion position (clamp position). The right side in FIG. 12 shows the state of the eject arm 41 when the eject arm 41 is separated from the periphery of the recording disk 2 during clamping.

  As shown in FIG. 12, the eject arm 41 is rotatably supported by the select plate 37 via a support shaft 42. One end of the eject arm 41 extends from the support shaft 42 to the right. A contact member 43 is attached to one end of the eject arm 41. During loading, the eject arm 41 detects the completion of drawing of the recording disk by bringing the contact member 43 into contact with the rear peripheral edge of the recording disk.

  The other end of the eject arm 41 extends to the left from the support shaft 42. A push control unit 44 is formed at the other end of the eject arm 41. When the eject arm 41 rotates counterclockwise and the other end of the eject arm 41 advances, the push control unit 44 pushes the trigger pin 47 of the trigger plate 46, and moves the trigger plate 46 from the rear position P1 to the intermediate position P2. Push to move.

  A spring connection portion 81 is formed between the support shaft 42 of the eject arm 41 and the other end portion.

  The trigger plate 46 is attached to a motor blanket (not shown) fixed to the chassis 11 so as to be movable in the front-rear direction. The trigger plate 46 can move forward relative to the select plate 37 from the rear position P1 through the intermediate position P2 to the front position P3.

  In addition, the trigger plate 46 includes a trigger pin 47 that is in contact with the push control unit 44 until the trigger plate 46 exists from the rear position P1 to the intermediate position P2.

  The trigger plate 46 includes a rack portion 46A that meshes with the pinion 66 when the trigger plate 46 moves forward and reaches the intermediate position P2.

  The motor 65 and the pinion 66 convey the trigger plate 46 that has been pushed to the intermediate position P2 by the push control unit 44 from the intermediate position P2 to the front position P3.

  One end of the coil spring 49 is connected to the spring connecting portion 81 of the eject arm 41, and the other end is connected to the spring connecting portion 82 of the trigger plate 46. The coil spring 49 pulls the spring connecting portion 81 of the eject arm 41 in the forward direction when the trigger plate 46 moves in the forward direction.

  As shown on the left side of FIG. 12, when the recording disk is not inserted into the disk drive 10, a force is applied to the eject arm 41 by the coil spring 49 so as to rotate in the clockwise direction D1. As a result, the contact member 43 at one end of the eject arm 41 is greatly advanced, and the pushing control unit 44 at the other end of the eject arm 41 is largely retracted.

  The coil spring 49 applies such a force to the eject arm 41 because the end of the coil spring 49 is at a substantially intermediate position between the support shaft 42 of the eject arm 41 and the other end (pushing control unit 44). It is because it is connected to the spring connection part 81 formed in the above. That is, when the eject arm 41 rotates counterclockwise, the push control unit 44 moves forward, and at the same time, the spring connection portion 81 moves forward. Further, the trigger plate 46 advances by the advancement of the push control unit 44. Since the distance between the push control unit 44 and the support shaft 42 is longer than the distance between the spring connecting portion 81 and the support shaft 42, the push control when the eject arm 41 rotates counterclockwise. The advance amount of the portion 44 is larger than the advance amount of the spring connection portion 81. Further, since the trigger plate 46 advances by the same amount as the advance amount of the push control unit 44, the advance amount of the trigger plate 46 is larger than the advance amount of the spring connection portion 81. As a result, when the eject arm 41 rotates counterclockwise, the coil spring 49 extends. When the coil spring 49 is extended, a force for pulling the trigger plate 46 backward is generated by the coil spring 49. The force for pulling back the trigger plate 46 is a force for returning the push control unit 44 to the back by contact between the trigger pin 47 and the push control unit 44. This force is a force for rotating the trigger plate 41 in the clockwise direction D1.

  Even when the recording disk 2 is inserted into the disk drive 10 and loading is started, the recording disk 2 has not reached the pull-in completion position, the trigger plate 46 has not reached the intermediate position P2, and the trigger plate 46 While the rack portion 46A is not yet engaged with the pinion 66, a force is applied to the eject arm 41 so as to rotate in the clockwise direction D1 by the coil spring 49. As a result, the recording disk 2 is inserted into the disk drive 10 and ejected from when the rear peripheral edge of the recording disk 2 contacts the contact member 43 of the eject arm 41 until the recording disk 2 reaches the drawing-in completion position. The contact member 43 of the arm 41 contacts the rear peripheral edge of the recording disk 2 with a force in the D1 direction created by the coil spring 49.

  As shown in the center of FIG. 12, when the recording disk 2 is transported to the pull-in completion position, the contact member 43 of the eject arm 41 is pushed backward by the recording disk 2, and the eject arm 41 receives the biasing force of the coil spring 49. Counter-clockwise rotation. Thereby, the pushing control part 44 pushes the trigger pin 47, and the trigger plate 46 advances to the intermediate position P2. When the trigger plate 46 advances to the intermediate position P <b> 2, the rack portion 46 </ b> A of the trigger plate 46 meshes with the pinion 66. At this time, the pinion 66 is rotated by the motor 65. As the pinion 66 rotates, the trigger plate 46 moves forward toward the front position P3. As a result, the trigger pin 47 moves away from the push control unit 44. As a result, the spring connecting portion 81 of the eject arm 41 is pulled forward by the coil spring 49. Therefore, a force in the counterclockwise direction D <b> 2 is applied to the eject arm 41 by the coil spring 49.

  When a force in the counterclockwise direction D2 is applied by the coil spring 49, the eject arm 41 rotates counterclockwise as shown on the right side of FIG. This rotation is stopped when the other end side of the eject arm 41 contacts the stopper 39. As a result, the contact member 43 of the eject arm 41 is separated from the rear peripheral edge of the recording disk 2, and an appropriate clearance is secured between the contact member 43 and the rear peripheral edge of the recording disk 2.

  Note that the stopper 39 is fixed to a motor blanket (not shown) via a through groove 91 formed on the select plate 37 with the upper end extending upward and the lower end side. Therefore, the receding width D8 on one end side (contact member 43) of the eject arm is larger than the receding width D7 of the select plate 37, and a sufficient clearance can be provided around the recording disk.

  The state and operation of the eject arm 41 described with reference to FIG. 12 are substantially the same even when the recording disk 1 is inserted into the disk drive 10.

  As described above, according to the disk drive 10, although the force to be applied to the eject arm 41 during loading and the force to be applied to the eject arm 41 during clamping are opposite to each other, these forces are applied. It can be produced by a single coil spring 49. Thereby, the structure of the disk drive 10 can be simplified. Therefore, the number of parts of the disk drive 20 can be reduced, and the disk drive 10 can be reduced in size, thickness, weight, and manufacturing cost.

  The chassis 11 is a specific example of the substrate, the select plate 37 is a specific example of the support plate, the eject arm 41 is a specific example of the arm, the trigger plate 46 is a specific example of the moving member, the motor 65 and The pinion 66 is a specific example of the transport mechanism.

  Further, the present invention can be appropriately changed without departing from the gist or concept of the present invention which can be read from the claims and the entire specification, and a disk drive accompanied by such a change is also included in the technical concept of the present invention. It is.

1 is a perspective view showing an embodiment of a disk drive of the present invention. It is a top view which shows the inside of the disk drive in FIG. It is a top view which shows the inside of a disc drive when a small diameter recording disc is inserted. It is a top view which shows the inside of a disc drive when a small diameter recording disc is conveyed to the clamp position. It is a top view which shows the inside of a disk drive when a small diameter recording disk is clamped. It is a top view which shows the inside of a disc drive when a small diameter recording disc stops at an ejection completion position. It is a top view which shows the inside of a disc drive when a large diameter recording disc is inserted. It is a top view which shows the inside of the disk drive in the middle of conveyance of a large diameter recording disk. It is a top view which shows the inside of a disk drive when a large diameter recording disk is conveyed to the clamp position. It is a top view which shows the inside of a disk drive when a large diameter recording disk is clamped. It is a top view which shows the inside of a disk drive when a large diameter recording disk stops in the ejection completion position. It is explanatory drawing which shows three states of an eject arm.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Disc drive 37 Select plate 41 Eject arm 42 Support shaft 43 Contact member 44 Push control part 46 Trigger plate 47 Trigger pin 49 Coil spring 65 Motor 66 Pinion 81 Spring connection part

Claims (4)

A disk drive that reads or records information on a recording disk,
A substrate,
The substrate is rotatably supported via a support shaft, extends from the support shaft to one side in the left-right direction, and detects the completion of drawing of the recording disk by contacting the rear edge of the recording disk during loading. An arm having a first end, a second end extending from the support shaft to the other side in the left-right direction, and a spring connecting portion formed between the support shaft and the second end;
A movable member that is supported by the substrate so as to be movable in the front-rear direction and moves in the front direction from the rear position to the front position through the intermediate position;
A push control unit that is provided at the second end of the arm and pushes the moving member from the rear position to the intermediate position by the advance of the second end caused by the rotation of the arm;
A transport mechanism for transporting the moving member pushed to the intermediate position by the push control unit from the intermediate position to the front position;
One end side is connected to the spring connecting portion of the arm, the other end side is connected to the moving member, and the spring includes a spring that pulls the spring connecting portion of the arm when the moving member moves forward. Features a disc drive.   2. The disk drive according to claim 1, wherein the moving member includes a pin that is in contact with the push control unit until the moving member exists from the rear position to the intermediate position. The transport mechanism includes a pinion disposed at the intermediate position, and a motor that rotates the pinion.
The disk drive according to claim 1, wherein the moving member includes a rack portion that meshes with a pinion when the moving member moves forward and reaches the intermediate position. The arm is rotatably supported via a support shaft on a support plate supported so as to be movable in the front-rear direction with respect to the substrate.
When the support plate moves in the front-rear direction, and the arm moves in the front-rear direction, the moving member also moves in the front-rear direction together with the arm due to the connection between the arm and the moving member by the spring. The disk drive according to claim 1, wherein the disk drive is moved to.

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