JP2004241124A - Disk device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To safely load a disk by easily mounting it inside the recess of a disk tray when a disk device is set upright to use. <P>SOLUTION: When a disk 4 is inserted into the recess 3 of the disk tray 2 in parallel to the disk mounting surface 3a in the recess 3, and the outer circumference of the disk 4 is pressed on a 1st slope 20 formed on the opposite side of the disk mounting surface 3a side in the recess 3 by the tips of lock arms 15, disk holding members, arranged on the periphery of the recess 3, the disk 4 is made to slip into the recess 3 while letting the lock arms 15 escape outward from the recess 3 against the compression coil springs 19; then the lock arms 15 are reset to the center side in the recess 3 by the compression coil spring 19 and the periphery of the disk 4 is guided by a 2nd slope 21 formed on the disk mounting surface 3a side in the recess 3; and thus the disk 4 is held in the recess 3. <P>COPYRIGHT: (C)2004,JPO&NCIPI

Description

  The present invention relates to a disk device such as a CD player and a CD-ROM drive, and more particularly to a device for placing a recording and / or reproducing disk on a disk tray and loading the disk into a disk device body.

  2. Description of the Related Art Conventionally, in a disk device such as a CD player or a CD-ROM drive, as shown in FIGS. 40 and 41A, a horizontally long opening 1a is formed on the front surface of a disk device main body 1 formed in a flat box shape. The disc tray 2 is mounted horizontally through the opening 1a so as to be horizontally movable in and out of the directions of arrows a and a '. Then, a substantially circular recess 3 is formed on the horizontal top plate 2a of the disc tray 2 formed of a synthetic resin or the like, and the recording and / or reproducing disc 4 such as a CD or CD-ROM is inserted into the recess. 42, the disc 4 is loaded horizontally by the disc tray 2 into the disc apparatus main body 1 from the direction of arrow a, as shown in FIG. Have been.

  At this time, as shown in FIGS. 43 and 44, a notch 5 is formed from the center of the recess 3 of the disc tray 2 to the end in the loading direction (the direction of the arrow a). A disk table 6, an optical pickup 7, and a disk clamper 8 are arranged above and below the disk.

  As shown in FIG. 43, when the disk tray 2 is ejected outside the disk device main body 1 in the direction of arrow a ', the disk table 6 and the optical pickup 7 in the disk device main body 1 and the disk clamper 8 are connected. The pair of upper and lower support frames 9 and 10 are retracted about the fulcrum shafts 11 and 12 in the directions of arrows b and c, which are the vertical directions of the disk tray 2.

  As shown in FIG. 44, when the loading of the disk tray 2 into the disk device main body 1 from the direction of the arrow a is completed, the pair of upper and lower support frames 9 and 10 are moved around the fulcrum shafts 11 and 12 by arrows b 'and They are simultaneously driven to rotate in the direction c '. Then, the disc table 6 and the optical pickup 7 are inserted into the notch 5 of the disc tray 2 from below in the direction of arrow b ', and the disc table 6 is fitted into the center hole 4a of the disc 4 from below. Is lifted upward from the disk mounting surface 3a of the recess 3 of the disk tray 2. Then, the disc 4 is chucked between the disc clamper 8 descending from the direction of arrow c 'and the disc table 6, and the optical pickup 7 is brought close to the lower surface of the disc 4.

  Thereafter, the disk 4 is driven to rotate by the disk table 6, and recording and / or reproduction of the disk 4 is performed by the optical pickup 7.

  By the way, as shown in FIG. 40 and FIG. 41A, this type of conventional disk device is configured such that the disk 4 is horizontally mounted on the disk mounting surface 3a of the recess 3 of the disk tray 2 and is loaded. This machine was designed for horizontal use and was not suitable for vertical use.

  That is, as shown in FIG. 41B, when the disk tray 2 is used upright with the disk device main body 1, the recess 3 becomes vertical, and the disk 4 will be placed vertically in the recess 3. However, there is a problem that the disc 4 slides in the direction of the arrow d due to its own weight at the tapered surface 3b on the outer periphery of the recess 3 and the disc 4 cannot be placed on the disc tray 2.

  On the other hand, in the CD-ROM drive industry in particular, there has been an increasing demand for vertical use of disk devices for the purpose of installing the disk devices in a narrow space with the miniaturization of computers.

  The present invention allows one disk drive to be used both horizontally and vertically, especially when the disk is used vertically, the disk can be easily loaded into the recess of the disk tray and can be safely loaded. A disk tray on which a disk is placed in a recess, a disk tray driving mechanism for loading the disk tray into the disk device main body and ejecting the disk tray outside the disk device main body, and A disc holding member provided on the outer periphery of the recess, and a first slope formed at a tip of the disc holding member on a side opposite to a disc mounting surface side in the recess, and A first slope for releasing the disc holding member to the outside of the recess by pressing the outer periphery of the disc to be inserted; A second slope formed at the tip of the member on the side of the disc mounting surface in the recess, wherein after the outer periphery of the disk has passed over the first slope toward the side of the disk mounting surface, A second inclined surface for guiding the outer periphery of the disk toward the disk mounting surface side of the recess and holding the same in synchronization with the return of the holding member to the center of the recess.

The disk device of the present invention can be loaded while holding the outer periphery of the disk inserted into the recess of the disk tray with the disk holding member, so that one disk device can be used both horizontally and vertically. . In particular, when inserting the disk into the recess of the disk tray and pressing the outer circumference of the disk against the first slope of the disk holding member, the disk holding member escapes outside the recess, and the outer circumference of the disk is released. After the disk climbs over the first slope, in synchronization with the return of the disk holding member to the center of the recess, the outer periphery of the disk is moved toward the disk mounting surface of the recess by the second slope of the disk holding member. Since the disc is guided and held as it is, the disc can be easily loaded into the recess of the disc tray and can be safely loaded when used vertically.

The disk device of the present invention further includes a biasing means for biasing the disk holding member to move from the outside of the recess toward the center, thereby making it easier to insert and hold the disk into the recess of the disk tray. be able to.
The disk device of the present invention includes the release means for releasing the holding of the outer periphery of the disk by the disk holding member, so that after the loading is completed, the disk can be floated in the recess of the disk tray and driven to rotate.
In the disk device of the present invention, the disk holding member is moved up and down with respect to the disk mounting surface in the recess around a rotation fulcrum provided at the other end opposite to the end where the first and second slopes are formed. The disk holding member is configured to be rotatable in the direction, and the releasing means is moved to the distal end side and the other end side on a control surface formed between the distal end and the other end of the disk holding member, thereby holding the disk holding member. By controlling the member between the disk holding position and the release position where the disk is released, it is possible to easily and easily hold the disk and release the holding.

  An embodiment of a disk drive according to the present invention will be described below with reference to FIGS. The same components as those in FIGS. 40 to 44 are denoted by the same reference numerals, and the description will not be repeated.

[Description of Disk Tray]
First, the disk tray will be described with reference to FIGS.

[Description of disk tray shape]
First, as shown in FIG. 24 to FIG. 28, in the outer periphery of the recess 3 of the disc tray 2, the loading direction and the ejecting direction, ie, the front-back direction (arrow a, a ′ direction) and the left-right direction (arrow a, a ′ direction) (In the direction perpendicular to), four grooves 14 are formed at four corners. These grooves 14 are formed along two radiations P from the center O of the recess 3. In these four grooves 14, four lock arms 15 serving as disk holding means are mounted.

[Description of lock arm]
Next, as shown in FIGS. 22, 23, and 29 to 34, the lock arm 15 is formed of a synthetic resin or the like, and the tip 15 a is formed with a groove facing the center O of the recess 3. The tip 15a is inserted into the groove 14 from below to project upward from the tapered surface 3b of the recess 3 above the disk mounting surface 3a. The other end 15b of the lock arm 15 is disposed below the top plate 2a of the disk tray 2, and a pair of guide pins 16 integrally formed on both sides of the other end 15b are formed by grooves on the lower surface of the top plate 2a of the disk tray 2. 14 are slidably and rotatably held by a pair of substantially U-shaped sliding guides 17 integrally formed on both sides.

  Accordingly, the lock arm 15 is held by the groove 14 and the pair of sliding guides 17, and the pair of guide pins 16 are configured to be slidable in the directions of arrows e and e 'along the pair of sliding guides 17. The lock arm 15 is configured to be rotatable around the pair of guide pins 16 in the directions of arrows f and f '.

  Thus, the lock arm 15 is configured to be horizontally movable in the directions of arrows e and e 'parallel to the disk mounting surface 3a along the radiation P with the tip 15a protruding above the groove 14. At the same time, the distal end 15a of the lock arm 15 is configured to be rotatable in the directions of arrows f and f ', which are directions substantially perpendicular to the disk mounting surface 3a.

  A spring support pin 18a of a spring receiving plate 18 integrally formed on the lower surface of the top plate 2a of the disc tray 2 at a free end of the groove 14, and a spring support pin integrally formed on a lower portion of the other end 15b of the lock arm 15. A compression coil spring 19 as urging means is mounted between the lock arm 15c and the lock arm 15c. The distal end 15a of the motor 15 is urged to rotate in the direction of the arrow f, which is the direction away from the disk mounting surface 3a upward.

  The forward position of the lock arm 15 in the direction of the arrow e is regulated by a pair of sliding guides 17 which also serve as a stopper, and the rotational position of the lock arm 15 in the direction of the arrow i is regulated by a release means described later.

  First and second slopes 20 and 21 are formed on the tip end 15a of the lock arm 15 in a substantially angled manner along the directions indicated by arrows f and f 'which are perpendicular to the disc mounting surface 3a. Have been.

  A release arm sliding surface 22, which will be described later, is formed on the upper surface between the distal end 15a and the other end 15b of the lock arm 15, and the release arm sliding surface 22 is a horizontal step formed on the distal end 15a side. It is formed by a portion 22a and a slope 22b that is formed so as to gradually decrease from the step portion 22a toward the other end 15b.

[Explanation of release lever]
Next, as shown in FIGS. 27 and 35 to 39, a pair of left and right release levers 24 constituting the release means are formed of synthetic resin or the like. At the lower part of the plate 2a, it is parallel and symmetrically attached to both left and right positions. A pair of release arms 25 extending symmetrically in the oblique front-rear direction from both ends 24 a of the pair of release levers 24 in the longitudinal direction along the front-rear direction are provided on the release arm sliding surfaces 22 of the pair of lock arms 15. It is placed on the upper part in a substantially orthogonal state. A vertical cam driven pin 26 integrally formed on the upper part of the central part in the length direction of the pair of release levers 24 is formed on the lower surface of the top plate 2a of the disk tray 2 in the left-right direction (arrows g, g '). ) Is loosely fitted in a pair of elongated holes 27 along the same direction.

  The lengthwise ends 24a of the pair of release levers 24 are disposed between a pair of four bosses 28 integrally formed on the lower surface of the top plate 2a of the disk tray 2, and screws are provided on the lower surfaces of these bosses 28. Each pair is stopped and is supported from below by four washers 29 in total.

  Accordingly, the pair of release levers 24 are mounted movably in the directions of arrows g and g ', which are the left and right directions, along the lower surface of the top plate 2a of the disk tray 2.

  The wide end portions 31a of the cam lever 31, which is formed in a substantially U-shape with sheet metal or the like, extend horizontally between the central portion in the longitudinal direction of the pair of release levers 24 and the lower surface of the top plate 2a of the disk tray 2. Intervened.

  A pair of cam follower pins 26 of a pair of release levers 24 penetrate through substantially crank-shaped cam grooves 32 formed symmetrically at these wide end portions 31a, and these cam follower pins 26 and the cam grooves 32 are formed. The cam mechanism 33 is constituted by these.

[Explanation of rack lever]
A substantially L-shaped rack lever 34 made of synthetic resin or the like is horizontally mounted on one side of the lower surface of the top plate 2a of the disc tray 2, and the rack lever 34 is connected to an emergency eject mechanism 140 described later. The operation member of the disc tray drive mechanism 55 in FIG. The rack lever 34 moves along arrow a, along a guide groove (not shown) parallel to the front-rear direction (arrow a, a 'direction side) which is the loading direction and the eject direction formed on the lower surface of the top plate 2a. It is configured to be slidable in the a 'direction and is supported from below by a pair of washers 29. A rack 35 is formed on one side surface of the rack lever 34 and is parallel to the directions of arrows a and a '. The pinion is rotatably driven by a motor of a disk tray drive mechanism, which will be described later, mounted in the disk drive body 1. 36 is meshed with the rack 35.

  Then, a connecting portion 31b vertically bent downward from a longitudinal center portion of the cam lever 31 to a distal end of a distal arm 34a integrally formed at a right angle in the horizontal direction from the distal end of the rack lever 34 in the direction of the arrow a '. Are inserted from above and connected integrally.

  A tension coil spring 38 serving as a rack lever urging means is provided between a spring locking portion 34b integrally formed with the rack lever 34 and a spring locking portion 37 integrally formed on the lower surface of the top plate 2a of the disk tray 2. The rack lever 34 is urged to move in the direction of arrow a 'with respect to the top plate 2a of the disk tray 2 by the extension coil spring 38, and is integrally formed on the lower surface on the front end side of the top plate 2a. The stopper 39 is abutted from the direction of the arrow a '.

  On the lower surface of the top plate 2a of the disc tray 2, a pair of guides for guiding the pair of release levers 24 for positioning in the direction of arrow g, a total of four stoppers 40 and the wide end portions 31a of the cam lever 31, are provided. The pins 41 and the like are integrally formed.

[Description of vertical use]
Next, according to the disk tray 2 configured as described above, as shown in FIGS. 24 to 26, the disk device main body 1 and the disk tray 2 can be used vertically while standing upright.

  At this time, first, as shown in FIG. 24, when the disk tray 2 is ejected from the disk device main body 1 in the direction of the arrow a ', the rack lever 34 is moved by the tension coil spring 38 in the direction of the arrow a' as shown in FIG. And is in contact with the stopper 39.

  Then, the cam lever 31 is moved in the direction of the arrow a ′ integrally with the rack lever 34, and the pair of cam driven pins 26 is moved in the direction of the arrow g along the pair of elongated holes 27 by the pair of cam grooves 32 of the pair of cam mechanisms 33. Driven.

  Accordingly, the pair of release levers 24 are moved in parallel in the direction of the arrow g to abut against each pair of stoppers 40, and as shown in FIGS. It is moved on the sliding surface 32 in the direction of the arrow j and reaches the step 22a.

  Thereby, as shown in FIGS. 31 and 32, the four lock arms 15 are pressed by the four release arms 25 in the direction of arrow f 'against the four compression coil springs 19, and are held horizontally. . In this horizontal state, the four lock arms 15 are positioned at the holding positions advanced by the four compression coil springs 19 in the direction of arrow e.

  Therefore, as shown in FIG. 24, it is simple to insert the disk 4 in parallel from the horizontal arrow h direction toward the center O in the recess 3 of the vertical disk tray 2 while keeping the disk 4 in the vertical position. According to the one-touch mounting method, as shown in FIG. 22 and FIG. 25, the four positions of the outer periphery 4b of the disk 4 inserted into the recess 3 in the vertical posture are simultaneously held by the four lock arms 15, and the disk 4 Are positioned stably and accurately so that there is no backlash at the center O in the recess 3.

  That is, as shown in FIGS. 31 and 32, when the disc 4 is inserted into the recess 3 from the direction of the arrow h, the outer periphery 4b of the disc 4 is It is pressed against four first slopes 20.

  Then, the four lock arms 15 are retracted in the direction of arrow e 'against the four compression coil springs 19 as indicated by the dashed line, by the guiding action of the four first slopes 20, and the outer periphery 4b of the disk 4 Slides from the first slope 20 to the second slope 21 at the tips 15 a of the four lock arms 15.

  Then, at that moment, the four lock arms 15 are advanced by the four compression coil springs 19 toward the center O of the recess 3 in the direction of arrow e. Then, the outer periphery 4b of the disk 4 is pressed in the direction of the arrow h by the guide action of the four second slopes 21 of the tips 15a of the four lock arms 15, and the disk 4 is placed in the recess 3. It is crimped parallel to the surface 3a.

  As a result, as shown in FIGS. 22 and 25, the disk 4 is stably held in the recess 3 by the four lock arms 15 without rattling while the disk 4 remains in the vertical posture. The four lock arms 15 that move forward in the direction of arrow e toward the center O of the recess 3 can evenly press the four places of the outer periphery 4b of the disk 4 from the direction of arrow e. 3 can be accurately positioned at the center O.

[Explanation of disc loading operation]
Next, when the front panel 2b of the disc tray 2 is pushed in the direction of arrow a after the disc is mounted, an eject switch described later is operated, and as shown in FIG. And the rack 35 of the rack lever 34 is driven in the direction of arrow a.

  Then, the disk tray 2 is pulled in the direction of the arrow a integrally with the rack lever 34 via the tension coil spring 38, and as shown in FIG. Loaded in the direction.

  The disk tray 2 that has been completely loaded into the disk device main body 1 from the direction of arrow a comes into contact with a later-described tray loading stopper in the disk device main body 1 and stops. At this time, since the disk 4 can be stably held vertically without rattling and can be loaded, it can be used even if the vertical posture of the disk device main body 1 shown in FIG. is there.

  After the disc tray 2 stops, the pinion 36 continues to rotate overstroke in the direction of arrow i by the motor of the disc tray drive mechanism as shown in FIG.

  Then, as shown in FIG. 36, the rack lever 34 is moved in the direction of the arrow a by an overstroke S against the tension coil spring 38 with respect to the disk tray 2 from the reverse position indicated by the dashed line to the forward position indicated by the solid line. The cam lever 31 is moved by the overstroke S in the direction of arrow a with respect to the disc tray 2 while being guided by the pair of guide pins 41 by the tip arm 34a of the rack lever 34.

  Then, the pair of cam follower pins 26 are driven in the direction of arrow m along the pair of long holes 27 by the pair of cam grooves 32 of the pair of cam mechanisms 33 of the cam lever 31, and the pair of release levers 24 are moved in the direction of arrow g '. 33 and 34, these release arms 25 move on the release arm sliding surface 22 of the lock arm 15 from the step 22a to the slope 22b in the direction of the arrow j 'as shown in FIGS. .

  Then, as shown in FIGS. 33 and 34, the four lock arms 15 are rotated by the four compression coil springs 19 around the four guide pins 16 to the non-holding position in the arrow f direction, and the four lock arms 15 The second slope 21 of the tip 15a is separated from the outer periphery 4b of the disk 4 in the direction of arrow f, and the holding of the disk 4 is released.

  At about the same time, as shown in FIG. 23, the disk table 6 is fitted into the center hole 4a of the disk 4 from the direction of the arrow b ', as described later, and the chucking magnet 6a of the disk table 6 is used. The chucking plate 8a of the disc clamper 8 is attracted, and the disc clamper 8 magnetically chucks the outer periphery of the center hole 4a of the disc 4 on the disc table 6 in the direction of the arrow c '. The disk 3 is floated in the direction of arrow h 'from the disk mounting surface 3a at the place 3.

  At this time, as described above, since the disk 4 is loaded with the four lock arms 15 accurately positioned at the center O of the recess 3 of the disk tray 2, the disk table 6 is placed in the center hole 4a of the disk 4. Can be smoothly fitted from the direction of arrow b ', and the magnetic chucking operation of the disk 4 by the disk table 6 and the disk clamper 8 can be performed smoothly. Therefore, no chucking mistake of the disk 4 occurs.

Then, in the completion state of the disk chucking, as shown in FIGS. 33 and 34, the gap G ₁ is formed between the disk mounting face 3a and the disc 4 of the recess 3 of the disk tray 2, the disk 4 gap G ₂ is formed between the distal end 15a of the outer circumference 4b and four locking arms 15.

  Therefore, after that, when the disk table 6 is driven to rotate by the spindle 45 of the spindle motor 44 shown in FIG. 23, and the disk 4 is driven to rotate integrally with the disk table 6 to perform recording and / or reproduction of the disk 4, The disk 4 can rotate stably in a non-contact state with respect to the disk tray 2 and the four lock arms 15.

[Explanation of disc eject operation]
At the time of ejection, when an eject button 43 attached to the front panel 1b of the disk device main body 1 shown in FIG. 26 is pressed, an eject switch described later is operated, and the pinion 36 shown in FIG. It is driven to rotate in the direction of arrow i 'by the motor of the mechanism.

  Then, as described later, at the same time when the disk table 6 and the disk clamper 8 are detached from the disk 4 in the directions of arrows b and c, as shown in FIG. After the outer periphery 4a of the disk 4 is held by the four lock arms 15, the disk 4 is ejected by the disk tray 2 out of the disk device main body 1 in the direction of arrow a 'as shown in FIG.

  When the disk 4 is pulled in the direction of arrow h 'after the ejection shown in FIG. 25, as shown by a dashed line in FIGS. 31 and 32, the two slopes 21 of the tips 15a of the four lock arms 15 are used. By the guide action, the four lock arms 15 escape in the direction of arrow e 'against the four compression coil springs 19, so that the disk 4 can be easily removed from between the tips 15a of the four lock arms 15 in the direction of arrow h' with one touch. be able to.

[Description of Disk Unit]
Next, the disk drive body will be described with reference to FIGS.

[Explanation of box-type configuration of disk unit]
First, as shown in FIG. 5, a disk device main body 1 is formed of a synthetic resin or the like and has a front panel 1b formed with a horizontally long opening 1a, a horizontal chassis 1c formed of a synthetic resin or the like, and this chassis 1c. A flat box shape is formed by a cover 1d formed of a stainless thin plate or the like that covers the upper, lower, left, right, and rear portions of the device. The printed circuit board 1d is horizontally mounted below the chassis 1c.

[Explanation of the disc tray guide]
Next, as shown in FIGS. 1 to 6, the disk tray 2 is guided by a pair of left and right tray guides 51 formed at both left and right positions on the chassis 1c, and the disk tray 2 is passed through the opening 1a. 1 is mounted on a chassis 1c so as to be horizontally movable in and out of the directions of arrows a and a '.

[Description of the disc tray stopper]
Then, a tray loading stopper 52 for regulating the loading completion position of the disk tray 2 loaded into the disk device main body 1 in the direction of arrow a, and the ejection completion of the disk tray 2 ejected out of the disk device body 1 in the direction of arrow a '. A tray eject stopper 53 for regulating the position is integrally formed on the chassis 1c.

[Description of tray drive mechanism]
A disk tray drive mechanism 55 for loading and ejecting the disk tray 2 in the directions of arrows a and a 'is attached to a position on one side of the chassis 1c and close to the front panel 1a. .

  As shown in FIGS. 14 to 17, the disc tray drive mechanism 55 includes a motor 56, a pinion 36 that is an output gear for driving the rack lever 34, and a gear train that connects the motor 56 and the pinion 36. 57. In the gear train 57, a worm 58 fixed to a motor shaft 56a of a motor 56, a clutch movable gear 60 integral with a worm wheel 59 constantly meshed with the worm 58, and the clutch movable gear 60 mesh , A clutch fixed gear 61 that is rotated at a fixed position so as to be disengaged is provided. All the gears from the clutch fixed gear 61 to the pinion 36 in the gear train 57 are rotatably mounted on the outer periphery of a plurality of gear support shafts 62 on the chassis 1c.

[Description of clutch]
The clutch 63 incorporated in the gear train 57 rotatably holds the worm wheel 59 and the clutch movable gear 60, and is rotatably mounted around the fulcrum shaft 64 on the chassis 1c in the directions of arrows k and k '. And a clutch lever 67 mounted rotatably in directions of arrows m and m 'around a fulcrum shaft 66 on the chassis 1c.

  The distal end of the clutch driven lever 65 and the distal end of the clutch lever 67 intersect at a substantially right angle, and a cam driven pin 68 attached to the distal end of the clutch driven lever 65 has an arc-shaped length provided at the distal end of the clutch lever 67. The cam driven pin 68 and the cam groove 69 form a cam mechanism 70 which is engaged from above into the cam groove 69 which is a hole. The cam groove 69 is formed approximately in an arc around the fulcrum shaft 64, and the radius of curvature of the cam groove 69 is larger than the radius of rotation of the cam follower pin 68.

  The clutch lever 67 is rotationally urged in the direction of the arrow m by a torsion coil spring 71, which is a clutch lever urging means attached around the fulcrum shaft 66, and is brought into contact with a stopper 72 on the chassis 1c. Then, the rotational force of the clutch lever 67 in the direction of arrow m by the torsion coil spring 71 urges the clutch driven lever 65 to rotate in the direction of arrow k by the cam action of the cam mechanism 70, and the clutch movable gear 60 is moved to the clutch fixed gear 61. It is configured to be meshed and biased.

  The gear train 57 and the clutch 63 in the tray drive mechanism 55 are disposed in a recess 73 formed on the chassis 1c. As shown in FIG. It is covered with a gear train cover 74 such as a stainless steel plate.

[Explanation of eject spring]
Next, as shown in FIGS. 1, 2, 13 and 21, a downward projection 75 is integrally formed at a position on one side of the lower surface of the disk tray 2, which is offset in the direction of arrow a. An eject slider 76 pushed in the direction of arrow a by the projection 75 is slidably mounted in the directions of arrows a and a 'along a guide groove 77 formed in the chassis 1c and parallel to the directions of arrows a and a'. I have.

  A tension coil spring 80 as an eject spring is provided between a pair of spring engaging portions 78 and 79 integrally formed at the lower end of the eject slider 76 and the lower portion of the chassis 1c. The slider 76 is urged to slide in the direction of arrow a '.

[Description of disk tray lock mechanism]
Next, as shown in FIGS. 1, 2, 13 and 19, a downward projection 82 is integrally formed at one side of the lower surface of the disk tray 2 at a position deviated in the direction of arrow a. A disk tray lock mechanism 83 for locking and unlocking the projection 82 is mounted on the chassis 1c at a position offset in the direction of arrow a.

  The disk tray lock mechanism 83 has a lock lever 85 rotatably mounted on the chassis 1 c via a fulcrum shaft 84 in the directions of arrows n and n ′. A lock portion 85a for locking the lock 82 is integrally formed. A tension coil spring 88 serving as a lock lever urging means is provided between a pair of spring locking portions 86 and 87 integrally formed on the tip of the lock lever 85 and the chassis 1c. The lock lever 85 is urged to rotate in the direction of arrow n and is in contact with the stopper 82 on the chassis 1c.

  A cam follower pin 89 integrally formed at the end of the lock lever 85 on the fulcrum shaft 84 side is opposite to the rack 35 at the end of the rack lever 34 attached to the lower surface of the disk tray 2 in the direction of arrow a. A cam mechanism 91 that rotates the lock lever 85 in the directions of arrows n and n ′ is constituted by the cam 90 integrally formed on the side surface of the side.

[Description of rack lever lock mechanism]
Next, as shown in FIGS. 1, 2, 13, and 18 to 20, the gap between the end of the rack lever 34 attached to the lower surface of the disk tray 2 in the direction of the arrow a and the top of the chassis 1 c. A rack lever lock mechanism 93 for locking and unlocking by a push-push method is attached to the rack lever.

  The push / push type rack lever lock mechanism 93 includes a leaf spring 95 fitted in a shallow concave portion 94 formed on the chassis 1c and a screw boss integrally formed on the chassis 1c in the concave portion 94. A lock lever 97 which is loosely fitted on the outer periphery of a 96 and is disposed on a leaf spring 95, a lock pin 98 which is vertically fixed on the tip of the lock lever 97, and an end of the rack lever 34 in the direction of arrow a A horizontal plate portion 99 integrally formed on the side of the rack 35 at a position deviated above the rack 35, and a lock groove 100 formed on the lower surface of the horizontal plate portion 99. .

  Note that a lock lever 97 is locked to the boss 96 by a flanged screw 101 screwed to the boss 96 from above, and the lock lever 97 is horizontal with respect to the boss 96 in the directions of arrows q and q ′. , And rotatable in the directions of arrows r and r ', which are vertical directions. Then, the leaf spring 95 urges the lock lever 97 to rotate in the direction of arrow r. The free end portion 97a of the lock lever 97 is loosely fitted in a small-sized concave portion 102 formed on the chassis 1c, and the swing width of the lock lever 97 in the directions of arrows q and q 'is restricted by the concave portion 102. It is configured to be.

  The lock groove 100 formed on the lower surface of the horizontal plate portion 99 has a wide entrance 100a opened at the end of the horizontal plate portion 99 in the direction of arrow a, and an arrow a 'from one side of the entrance 100a. 100b extending linearly in a direction parallel to the rack lever 34, a zigzag path 100c extending laterally in a zigzag manner from the end of the linear path 100b in the direction of arrow a ', and a linear path 100b extending from the zigzag path 100c. And a detour route 100d that is detoured to the other side. A lock portion 100e for locking the lock pin 98 is formed in the middle of the zigzag path 100c. Further, between the straight path 100b and the lock 100e of the zigzag path 100c, there is provided a slope 100f that gradually descends in the direction of the arrow a 'and a reverse running prevention step 100g, and the lock 100e of the zigzag path 100c. A reverse running prevention step portion 100h is also provided between the detour route 100d and the detour route 100d, and the straight route 100b and the detour route 100d are connected at the same height and flush.

[Explanation of disk table elevating mechanism]
Next, as shown in FIG. 1, FIG. 2, FIG. 5, and FIG. 8 to FIG. 10, the disk table 6 is vertically inserted into two large and small openings 104 and 105 formed substantially in the center of the chassis 1c. A disk table elevating mechanism 106, which is driven to move up and down in the directions b and b ', is attached.

  The disk table elevating mechanism 106 includes a main movable frame 107 disposed in a large opening 104 formed in the direction of the arrow a of the chassis 1c and a small opening 105 formed in the direction of the arrow a 'of the chassis 1c. And the sub movable frame 108 disposed. Note that the main movable frame 107 and the sub movable frame 108 are formed of synthetic resin or the like.

  Then, a pair of left and right ends 107a of the main movable frame 107 on the opposite side to the sub movable frame 108 in the direction of the arrow a are moved to the chassis 1c by the pair of left and right fulcrum parts 109 in the directions of the arrows b and b 'which are the vertical direction. It is rotatably mounted. Also, an end 108a of the sub movable frame 108 on the opposite side to the main movable frame 107 in the direction of arrow a 'is directed vertically to the chassis 1c by a pair of left and right fulcrum shafts 110 integrally formed on both left and right sides thereof. It is mounted so as to be rotatable in the s and s' directions. The center end 107b of the main movable frame 107 in the direction of the arrow a 'and the forked end 108b of the auxiliary movable frame 108 in the direction of the arrow a are opposed to each other from the directions of the arrows a and a'. The tips 107b and 108b are connected to each other by a connecting portion 111 so as to be rotatable with respect to the vertical directions of arrows b and b 'and arrows s and s'.

  As shown in FIG. 8A, the connecting portion 111 has a substantially upward U-shaped connecting arm 112 disposed between the forked ends 108b of the sub movable frame 108. A pair of left and right fulcrum shafts 113 that are parallel to the pair of left and right fulcrum shafts 110 are integrally formed on both left and right sides. The connecting arm 112 is rotatably mounted between the forked ends 108b of the sub movable frame 108 by the pair of left and right fulcrum shafts 113.

  A boss 114 for screwing is vertically formed integrally on a substantially central portion of the connecting arm 112 in the left-right direction, and a rubber drum or the like is formed on the outer periphery of the boss 114 in a hollow drum shape for vibration absorption. The insulator 115 is fitted. The distal end 107a of the main movable frame 107 is fitted in an annular groove 116 formed on the middle outer periphery of the insulator 115 in the vertical direction. The insulator 115 is pressed from above by a flanged screw 117 screwed to the boss 114 from above, and is held on the outer periphery of the boss 114.

  As shown in FIG. 8B, a pair of left and right fulcrum portions 109 are formed into a hollow drum shape with rubber or the like around the outer periphery of a screw boss 118 integrally formed vertically on the chassis 1c. The left and right ends 107a of the main movable frame 107 in the direction of the arrow a are fitted into an annular groove 120 formed on the middle outer periphery of the insulator 119 in the vertical direction. The insulator 119 is pressed from above by a flanged screw 121 screwed to the boss 118 from above and held on the outer periphery of the boss 118.

  As shown in FIGS. 1, 2, 11, and 12, the spindle motor 44 is fixed to the main movable frame 107 at a position deviated in the direction of arrow a 'by a plurality of screws 123. The disk table 6 fixed to the upper end of the spindle 45 by a pin 124 is disposed above the main movable frame 107.

[Description of the cam mechanism of the disc table elevating mechanism]
Next, as shown in FIG. 1, FIG. 2, FIG. 7, FIG. 9, and FIG. A cam mechanism 126 is provided which drives the frame 107 to rotate in the directions of arrows b and b 'and drives the disk table 6 to move up and down in the directions of arrows b and b'.

  The cam mechanism 126 is provided on the chassis 1c along a pair of left and right guide rails 127 integrally formed on one side of the small opening 105 of the chassis 1c and on one side of the recess 73 of the chassis 1c. , A ′ slider, a cam groove 129 formed on the side of the sub-movable frame 108 of the cam slider 128, and a middle part of the sub-movable frame 108 in the direction of the arrows a and a ′. The cam follower pin 130 is formed integrally on one side surface and is loosely fitted in the cam groove 129. The cam slider 128 is formed of a synthetic resin, and the cam slider 128 slides in the direction of arrow a 'by a tension coil spring 131 which is a cam slider urging means provided between the cam slider 128 and the chassis 1c. It is urged and is in contact with the stopper 132 on the chassis 1c. The cam groove 129 has a low portion 129a, an inclined portion 129b, and a high portion 129c.

  The driving means of the cam slider 128 is constituted by the tip arm 34a of the rack lever 34, and the cam slider 128 is configured to be pushed and slid by the tip arm 34a in the direction of arrow a.

[Description of Disk Table]
Next, as shown in FIGS. 11 and 12, the disk table 6 has an annular disk mounting surface 6b on which the disk 4 is mounted on an outer peripheral upper surface, and a center hole of the disk 4 on a central upper surface. A center ring hub 6c having a truncated cone shape into which the center ring 4a is fitted is formed, and an annular chucking magnet 6a is embedded in the center of the upper surface of the center ring hub 6c.

[Explanation of disc clamper]
As shown in FIG. 3 to FIG. 5, FIG. 11 and FIG. 12, a clamper is mounted on the upper portion of the chassis 1c so as to straddle the upper position of the disk tray 2 which is horizontally moved in and out from the directions of arrows a and a 'on the chassis 1c. Holder 134 is mounted horizontally. As shown in FIG. 2, the clamper holder 134 is attached to a pair of left and right clamper holder mounting parts 135 integrally formed at the upper ends of the left and right sides of the chassis 1c at the intermediate positions in the directions of the arrows a and a '. Screwed from above.

  A circular hollow portion 137 is formed horizontally just above the disc table 6, which is a central portion of the clamper holder 134, and a circular hole 138 is formed in a central portion below the hollow portion 137. Then, a disk clamper 8 formed into a disk shape by a synthetic resin or the like is loosely fitted into the circular hollow portion 137 by a flange 8b integrally formed on the outer periphery of the upper end thereof, and the disk clamper 8 projects downward from the circular hole 138. Then, the flange 8b is in contact with the lower flange 137a of the circular hollow portion 137. An annular disk pressing surface 8c is formed on the lower surface of the outer periphery of the disk clamper 8, a truncated cone-shaped recess 8d is formed on the lower surface of the center, and a magnetic plate such as an aluminum plate is formed on the upper portion of the recess 8d. The chucking plate 8a is buried horizontally.

[Explanation of the emergency eject mechanism]
Next, as shown in FIG. 1, FIG. 4, FIG. 14, FIG. 15, and FIG. 17, the clutch 63 and the disc tray drive mechanism 55 are located on one side of the gear train 57 of the chassis 1c near the front panel 1b. The emergency eject mechanism 140 for operating the rack lever 34, which is the operated member, is attached.

  The emergency eject mechanism 140 has an emergency lever 141 which is an emergency eject operation means formed of a sheet metal or the like, and the emergency lever 141 is attached to a lower portion of the chassis 1c. A linear guide groove 143 formed on the emergency lever 141 is loosely fitted into a guide pin 142 integrally formed on the lower portion of the chassis 1c. The formed guide pin 143 is loosely fitted in a substantially crank-shaped guide groove 145 formed in the chassis 1c.

  A projection 146 pushed in the direction of arrow a by the guide pin 144 is integrally formed on one side surface of the rack lever 34. Further, a protrusion 67a integrally formed on one side of the clutch lever 67 of the clutch 63 is inserted into a notch 147 formed on one side of the recess 73 of the chassis 1c. A cam mechanism 150 is formed by the formed cam follower pin 148 and the cam surface 149 formed on the side of the emergency lever 141 on the clutch 63 side.

  Then, the emergency lever 141 is guided by the pair of guide pins 142 and 144 and the guide grooves 143 and 145, and the guide pin 144 and the cam surface 149 are disengaged from the projection 146 and the cam follower pin 148 as shown in FIG. Between the disengaged position (return position) in which the engagement state is established, and the engagement position (forward movement position) in which the guide pin 144 and the cam surface 149 are engaged with the protrusion 146 and the cam driven pin 148. Thus, the emergency lever 141 is configured to be movable in the directions of arrows t and t '. The emergency lever 141 is biased backward to a non-engagement position (return position) in the direction of arrow t 'by a tension coil spring 151 which is an emergency lever biasing means provided between the emergency lever 141 and the chassis 1c. Further, accidental interference of the emergency lever 141 with the cam follower pin 68 of the clutch lever 67 and the projection 146 of the rack lever 34 is prevented.

  When the emergency lever 141 is returned to the non-engagement position (return position), the operated portion 141a integrally formed at the end of the emergency lever 141 in the direction of the arrow a 'is moved forward. It is configured to be located immediately behind the emergency operation hole 152 formed in the panel 1b.

[Description of switches]
Next, as shown in FIGS. 1 to 3, an eject button 43 is attached to the front panel 1 b of the disk device main body 1, and the eject button 43 and the front panel 2 b of the disk tray 2 are turned on and off by the eject button 43. eject switch SW ₁ is a micro-switch is mounted on an end portion of the arrow a 'direction side of the printed circuit board 1e that. The arrow a of the ejection completion detection switch SW ₃ is the printed circuit board 1e by the loading completion switch SW ₂ and the disk tray 2 by the rack lever 34 is a micro switch which is ON-OFF operation is a micro switch which is ON-OFF operation and The switches SW ₂ and SW ₃ are mounted on the end on the a ′ direction side, and project through the through-hole 155 formed in the chassis 1 c and onto the chassis 1 c.

[Explanation of optical pickup]
Next, as shown in FIGS. 1 to 5, an opening 157 is formed in the main movable frame 107 on the side of the disk table 6 in the direction of arrow a, and the opening 157 has the objective lens 7a of the optical pickup 7 therein. A carriage 7b is mounted movably in the directions of arrows a and a '.

  At this time, the carriage 7b is guided by a pair of guide shafts 158 attached to the lower part of the main movable frame 107 on the left and right sides of the opening 157 in parallel with the directions of the arrows a and a 'so as to be movable in the directions of the arrows a and a'. It is configured. Then, a rack 163 in which a pinion 162 driven forward and reverse through a gear train 161 and a stepping motor 160 constituting an example of a linear motor 159 attached to the main movable frame 107 is attached to one side of the carriage 7b. By driving, the carriage 7b is driven at a predetermined pitch in the directions of arrows a and a '.

  The spindle motor 44 and the stepping motor 159 attached to the main movable frame 107 are electrically connected to the printed board 1e via a flexible printed board (not shown) or the like.

[Description of the operation of the disk unit]
Next, the driving operation of the disk tray 2 by the disk tray driving mechanism 55, the disk table lifting / lowering mechanism 106, the emergency eject mechanism 140, etc. of the disk device main body 1 configured as described above will be described in order.

[Eject completion status of disk tray]
First, as shown in FIGS. 24 and 27, when the disc tray 2 is completely ejected from the inside of the disc device main body 1 in the direction of arrow a ', the contacted portion 2c of the disc tray 2 shown in FIG. The tray-eject stopper 53 of the chassis 1c is brought into contact with the tray a in the direction of arrow a 'and stopped, and the eject completion detection switch 155 shown in FIG. 1 is turned off.

  Then, in the ejection completed state, as shown in FIG. 9, the cam slider 128 is moved backward in the direction of the arrow a 'by the tension coil spring 131, and the cam follower pin 130 of the sub movable frame 108 is moved to the lower position of the cam groove 129. Part 129a.

  As a result, as shown in FIG. 5A, the sub movable frame 108 is rotated about the fulcrum shaft 110 in the direction of the arrow s, and the main movable frame 107 is moved to the disk table 6, the spindle motor 44, the optical pickup 7, and the like. The disc table 6 is lowered below the insertion position of the disc tray 2 by being rotated about the fulcrum 109 in the direction of arrow b by the load.

  In the ejection completed state, as shown in FIG. 15, the clutch movable gear 60 constituting the clutch 63 in the gear train 57 of the disk tray drive mechanism 55 is meshed with the clutch fixed gear 61 by the urging force of the torsion coil spring 71. Thus, the clutch 63 is held in the transmission state.

[Disk loading operation by disk tray]
Next, in this ejected state, as shown in FIGS. 25 and 28, the disc 4 is inserted into the recess 3 of the disc tray 2 from the direction of arrow h, and is shown in FIG. After holding the outer periphery 4b of the disk 4 as described above, the front panel 2b of the disk tray 2 is lightly pushed in the direction of arrow a.

Then, eject switch SW ₁ shown in FIG. 1 is OFF operation, the motor 56 of the disk tray drive mechanism 55 is normally rotated.

  Then, as shown in FIG. 15, the pinion 36 is driven to rotate forward in the direction of the arrow i by the motor 55 via the worm 58, the worm wheel 59, the gear train 57 including the clutch movable gear 60 and the clutch fixed gear 61, and the pinion is 36 drives the rack 35 in the direction of arrow a.

  When the rack lever 34 integrated with the rack 35 is driven in the direction of arrow a, as described above, the disk tray 2 is pulled in the direction of arrow a by the rack lever 34 via the tension coil spring 38, as shown in FIG. As shown in FIGS. 3 to 5B, the disk tray 2 is automatically loaded into the disk device main body 1 from the direction of arrow a.

Then, as shown in FIGS. 1 and 2, the loaded portion 2 d of the disk tray 2 is stopped by contacting the tray loading stopper 52 of the chassis 1 c, and at this time, the loading completion is detected by the rack lever 34. switch SW ₂ is turned ON, the loading completion of the disc tray 2 is detected.

  Immediately before the disc tray 2 comes into contact with the tray loading stopper 52, as shown in FIG. 21, the projection 75 of the disc tray 2 comes into contact with the eject slider 76, and the eject slider 76 is moved along the guide groove 77 by an arrow. Slide in direction a.

  Then, the extension coil spring 80 is pulled in the direction of arrow a by the eject slider 76, and the ejection force of the disc tray 2 is automatically charged to the extension coil spring 80.

Meanwhile, after being detected loading completion of the disc tray 2 by the loading completion detection switch SW _2, carried out continuously a positive rotational drive to the motor 56 of the disk tray drive mechanism 55 has passed a predetermined time, after the elapse of a predetermined time, A sequence in which driving is performed once in reverse rotation and then automatically stopped is incorporated in software (F / W).

  Then, the drive operation of the overstroke S of the rack lever 34 as described with reference to FIG. 36 is performed by the forward rotation of the motor 56 after the completion of the loading of the disk tray 2 is detected. The movement of the rack lever 34 in the direction of the arrow a due to the overstroke S causes the disk tray lock mechanism 83 to lock the disk tray 2, the rack lever lock mechanism 93 to lock the rack lever 34, The operation of releasing the holding state of the disk 4 and the operation of mounting (chucking) the disk 4 on the disk table 6 by the operation of lifting the disk table 6 by the disk table lifting mechanism 106 are performed.

  That is, first, after the disc tray 2 comes into contact with the tray loading stopper 52 from the direction of the arrow a and the disc tray 2 is stopped, the motor 56 is continuously rotated forward, as shown in FIG. Then, the rack lever 34 is moved in the direction of the arrow a against the disc tray 2 by the overstroke S by the tension coil spring 38.

  At this time, the disc tray lock mechanism 83 shown in FIG. 19 is driven by the cam follower pin of the lock lever 85 almost at the same time when the disc tray 2 comes into contact with the tray loading stopper 52, as shown by the dashed line in FIG. 89 rides on the cam 90 of the rack lever 34, the lock lever 85 rotates in the direction of the arrow n ′ against the extension coil spring 88 and escapes, and the projection 82 of the disc tray 2 moves to the lock portion 85 a of the lock lever 85. On the other hand, it enters the direction of arrow a.

  Next, at the moment when the rack lever 34 starts moving in the direction of the arrow a due to the overstroke S, the cam 90 of the rack lever 34 moves against the cam follower pin 89 of the lock lever 85 as shown by the solid line in FIG. Since the lock lever 85 is disengaged in the direction of arrow a, the lock lever 85 is rotated in the direction of arrow n by the tension coil spring 88, and the lock portion 85a enters the protrusion 82 of the disk tray 2 in the direction of arrow a '.

  As a result, the lock portion 85a of the lock lever 85 prevents the protrusion 82 of the disk tray 2 from moving in the direction of the arrow a ', so that the disk tray 2 is directly locked at the position where it abuts against the tray loading stopper 52. Is done.

Next, the rack lever lock mechanism 93 shown in FIGS. 18 to 20 is moved by the overstroke S of the rack lever 34 in the direction of the arrow a and the last return operation in the direction of the last arrow a '. As shown in FIG. 20, while the lock lever 97 rotates in the directions of the arrows q and q 'and in the directions of the arrows r and r', the lock pin 98 relatively moves into the lock groove 100 as shown in FIGS. It is inserted from the direction of arrow a '. At this time, the lock pin 98 travels from the entrance 100a of the cam groove 100 through the linear path 100b and the slope 100f and the step 100g of the zigzag path 100c in the directions of the arrows u ₁ and u ₂ to reach the lock section 100e. Then, the lock pin 98 is automatically locked by the lock portion 100e.

  The locking operation of the lock pin 98 of the rack lever lock mechanism 93 at this time is a so-called push-push type locking operation, in which the rack lever 34 is moved by an overstroke S with respect to the disk tray 2 in the direction of arrow a. Will be locked.

  When the overstroke S of the rack lever 34 moves in the direction of the arrow a, the pair of left and right release levers 24 shown in FIG. 36 is driven in the direction of the arrow g ', and as shown in FIG. The holding state of the outer periphery of the disk 4 on the disk tray 2 by the lock arm 15 is automatically released.

  On the other hand, in the disk table lifting / lowering mechanism 106 shown in FIGS. 5 and 7 to 10, the tip arm 34a of the rack lever 34 moves in the direction of the arrow a due to the overstroke S of the rack lever 34, and the cam slider 126 of the cam mechanism 126 moves. 128 is pushed in the direction of the arrow a against the tension coil spring 131 from the backward movement position shown in FIG. 9 to the forward movement position shown in FIG.

  Then, as shown in FIG. 10, the cam driven pin 130 of the sub movable frame 108 is pushed up from the low portion 129a of the cam groove 129 of the cam slider 128 through the inclined portion 129b to the high portion 129c, and the sub movable frame Reference numeral 108 rotates around the fulcrum shaft 110 in the direction of the arrow s' from the lowered position shown in FIG. 5A to the raised position shown in FIG. 5B.

  Then, the leading end 107b of the sub movable frame 108 is driven to move up by the leading end 107b of the main movable frame 107 via the connecting portion 111, and the main movable frame 107 is also moved from the lowered position shown in FIG. The main movable frame 107 is driven to rotate in the direction of the arrow b 'to the ascending position shown in FIG.

  As a result, the disk table 6 and the optical pickup 7 are driven to move upward from the lowered position shown in FIG. 5A to the raised position shown in FIG. Is inserted into the notch 5 of the disc tray 2 from the direction of arrow b '.

  Then, as shown in FIG. 12, the centering hub 6c of the disk table 6 is fitted into the center hole 4a of the disk 4 on the disk table 6 from the direction of arrow b ', and the disk mounting surface 6b of the disk table 6 As a result, the disk 4 is pushed up in the direction of arrow b '.

  Then, at this time, the disk pressing surface 8c of the disk clamper 8 is pushed up by the disk 4 in the direction of arrow c, and the flange 8b of the disk clamper 8 is pushed up to the vertical intermediate position of the circular hollow portion 137 of the clamper holder 134. Then, the disc clamper 8 is brought into a non-contact state with the clamper holder 134.

  Further, at this time, the chucking plate 8a of the disk clamper 8 is attracted in the direction of the arrow c 'by the chucking magnet 6a of the disk table 6, and the disk 4 is magnetically chucked on the disk table 6 by the disk clamper 8.

  By this series of disk mounting operations, the disk 4 is automatically mounted on the disk table 6 as shown in FIG. 23, and the mounted disk 4 is mounted on the disk mounting surface 3a of the disk tray 2. Automatically in the direction of the arrow c, which is above.

  By the movement of the rack lever 34, which is one drive source, in the direction of arrow a due to the overstroke S, the holding state of the outer periphery of the disk 4 by the four lock arms 15 is mechanically released, and the disk table 6 is mechanically moved. Since the disk 4 is mounted on the disk table 6 by the upward drive, the operation timings of the two can be mechanically and accurately synchronized.

  As a result, as shown in FIG. 11, at the moment when the centering hub 6c of the disk table 6 which is raised in the direction of the arrow b 'is loosely fitted into the center hole 4a of the disk 4 from the direction of the arrow b', the four The holding state of the outer periphery of the disk 4 by the lock arm 15 can be released. The operation timing can be easily and accurately set by the shape of the cam groove 129 which is the cam of the cam slider 128.

  As a result, when the disk 4 is mounted on the disk table 6, the state of the outer periphery of the disk 4 held by the four lock arms 15 and the magnetic chucking operation of the disk 4 by the disk clamper 8 never interfere with each other. . Therefore, the center hole 4a of the disk 4 is forcibly fitted into the centering hub 6c of the disk table 6 while the outer periphery of the disk 4 is held by the four lock arms 15, and the disk 4 is damaged. Magnet chucking of the disk 4 onto the disk table 6 can be performed while the center hole 4a of the disk 4 is smoothly and accurately fitted to the outer peripheral taper surface of the centering hub 6c of the disk table 6 without any occurrence. it can.

  Then, after the disk 4 is automatically mounted on the disk table 6, the objective lens 7a of the optical pickup 7 is brought close to the lower surface of the disk 4, as shown in FIG.

  Accordingly, thereafter, while the disk 4 is driven to rotate integrally with the disk table 6 and the disk clamper 8 by the spindle motor 44, the stepping motor 160 of the linear motor 159 of the optical pickup 7 shown in FIG. By driving the rack 163 of the carriage 7b and driving the carriage 7b in the directions of arrows a and a 'along a pair of guide shafts 158, the objective lens 7a is moved in the directions of arrows a and a' to Desired recording and / or reproduction can be performed.

[Eject operation of disk by disk tray]
Recording and / or after playing the disc 4, by pressing the eject button 43 shown in FIGS. 1 and 4, or ON operation of the ejection switch SW _1, or the eject command signal from a host computer is output, FIGS. 14 In the sequence shown in FIG. 17, the motor 56 of the disk tray drive mechanism 55 is reversely driven at the time of disk loading, and is driven once in the forward rotation and then in the reverse rotation.

  Then, by the reverse operation at the time of disc loading, the rack lever 34 is slightly returned once in the direction of arrow a and then moved in the direction of arrow a '. The rack lever lock mechanism 93 shown in FIGS. 18 to 20 performs a push-push type lock release operation by the switching movement operation in the ′ direction.

That is, as shown in FIGS. 19 and 20, proceeding to the lock pin 98 from the lock portion 100e of the locking groove 100 through the stepped portion 100h of the zig-zag path 100c arrow u ₃ direction to detour path 100d of the lock lever 97 The lock of the rack lever 34 is automatically released. Then, by the movement of the arrow a 'direction of the rack lever 34 after this, the lock pin 98 is advanced in the arrow u ₄ directions from the detour path 100d to the linear path 100b, exit from the entrance 100a in the direction of arrow a.

  When the lock of the rack lever 34 by the rack lever lock mechanism 93 is released, the disk tray lock mechanism 83 holds the locked state of the disk tray 2. Thus, the pinion 36 is driven to rotate in the direction of arrow i 'in the reverse direction, and the rack lever 34 moves from the position shown by the solid line to the position shown by the one-dot chain line in FIG. The disc is moved in the direction of arrow a 'with respect to the disc tray 2 by the distance.

  Then, as shown in FIG. 5A, the disk table 6 and the optical pickup 7 are lowered in the direction of arrow b by the disk table elevating mechanism 106 as shown in FIG. The disk table 6 and the disk clamper 8 are detached from the disk 4 in the directions of the arrows b and c, and the outer periphery of the disk 4 is automatically held again by the four lock arms 15 as shown in FIG. . That is, at this time, the cam slider 128 of the cam mechanism 126 of the disk table elevating mechanism 106 is moved by the tension coil spring 131 in the direction of the arrow a 'by the movement of the rack lever 34 in the direction of the arrow a', as shown in FIGS. And the cam follower pin 130 of the sub movable frame 108 is pushed down from the high portion 129c of the cam groove 129 to the low portion 129a through the inclined portion 129b. Then, the sub movable frame 108 is rotated around the fulcrum shaft 110 from the raised position shown in FIG. 5B to the lowered position shown in FIG. 5A in the arrow s direction, and the main movable frame 107 is moved. It is lowered in the direction of arrow b from the raised position shown in FIG. 5B to the lowered position shown in FIG. Then, the disk table 6 and the optical pickup 7 mounted on the main movable frame 107 are lowered in the direction of arrow b from the raised position shown in FIG. 5B to the lowered position shown in FIG. 5A.

  When the rack lever 34 is moved in the direction of the arrow a 'to the position shown by the one-dot chain line in FIG. 36, as shown by the one-dot chain line in FIG. 34, the lock lever 85 is rotated in the direction of arrow n 'against the extension coil spring 88, and the lock of the disc tray 2 is released.

  Then, as shown in FIG. 36, when the pinion 36 is continuously rotated in the direction of arrow i 'in the reverse direction, the tip arm 34a of the rack lever 34 pushes the stopper 39 of the disk tray 2 in the direction of arrow a'. The disk tray 2 is automatically ejected in the direction of the arrow a 'from the disk device main body 1 integrally with the lever 34.

  Then, as shown in FIGS. 24 and 27, the disc tray 2 is completely ejected in the direction of the arrow a ', and the abutted portion 2c of the disc tray 2 is moved to the eject stopper 53 shown in FIG. When the disc tray 2 is stopped due to the contact, the ejection completion detection switch 155 is turned off again, and the motor 56 is automatically stopped.

[Emergency eject operation]
In order to take out the disk 4 from the disk device main body 1 in an emergency such as when the power is cut off due to a power failure or some kind of failure in the loading state of the disk tray 2 shown in FIGS. When performing an emergency eject, as shown in FIG. 17, a wire-like operating member such as a zem clip which is an operating member for the emergency eject is inserted into an emergency operating hole 152 formed in the front panel 1b of the disk device main body 1. 153 is pushed in the direction of arrow a.

  Then, the operated portion 141a of the emergency lever 141 is pushed in the direction of the arrow a by the wire-like operating member 153, and while being guided by the guide pins 142, 144 and the guide grooves 143, 145, the emergency lever 141 is moved as shown in FIG. It is pushed out in the direction of arrow t against the tension coil spring 151 from the disengaged position (return position) shown to the engagement position (forward position) shown in FIG.

  17, first, the cam follower pin 148 of the clutch lever 67 is pushed in the direction of the arrow m 'by the cam surface 149 of the emergency lever 141, and the clutch lever 67 is pressed against the torsion coil spring 71. And is rotationally driven in the direction of arrow m '.

  Then, as shown in FIG. 17, the clutch driven lever 65 is rotated in the direction of arrow k 'by the cam mechanism 70, the clutch movable gear 60 of the clutch 63 is disengaged from the clutch fixed gear 61 in the direction of arrow k', and the clutch 63 is switched to the non-transmission state, and the pinion 36 can rotate freely.

  When the emergency lever 141 is further pushed in the direction of the arrow t, the guide pin 144 of the emergency lever 141 is moved to the protrusion 146 of the rack lever 34 while the clutch 63 is kept in the non-transmission state, as shown in FIG. Is pushed in the direction of arrow a, and the rack lever 34 is pushed out in the direction of arrow a against the extension coil spring 38.

  Then, the lock of the rack lever 34 by the rack lever lock mechanism 93 is released as in the case of the normal ejection.

  Then, when the wire-like operation member 153 is pulled out from the emergency operation hole 152 in the direction of the arrow a ', the emergency lever 141 moves from the engagement position (forward movement position) shown in FIG. 17 to the non-engagement position (return movement) shown in FIG. The rack lever 34 is pulled back by the tension coil spring 38 in the direction of the arrow a 'with respect to the disc tray 2 while the tension coil spring 151 pulls the rack lever 34 back in the direction of arrow a'. At this time, since the clutch 63 has already been switched to the non-transmission state, the pinion 36 idles lightly by the rack 35.

  When the rack lever 34 is pulled back from the position indicated by the solid line in FIG. 36 to the position indicated by the alternate long and short dash line in the direction of the arrow a ′ in the same manner as in the normal ejection, the item “disc ejection operation by the disc tray” is described. As described in FIGS. 7 and 9, the cam slider 128 of the cam mechanism 126 of the disc table lifting mechanism 106 is pulled back in the direction of the arrow a 'by the tension coil spring 131, and the sub movable frame 129 is supported by the fulcrum shaft. The main movable frame 107 is rotated in the direction of the arrow s from the raised position shown in FIG. 5B to the lowered position shown in FIG. 5A around the center 110, so that the main movable frame 107 is shown in FIG. It is lowered in the direction of arrow b from the raised position to the lowered position shown in FIG. Then, the disk table 6 mounted on the main movable frame 107 is lowered in the direction of arrow b from the raised position shown in FIG. 5B to the lowered position shown in FIG. 5A. After the disk table 6 is lowered, the disk tray lock 83 is unlocked.

  At the moment when the lock of the disc tray 2 is released, as shown in FIG. 21, the eject slider 76 is moved from the position shown by the dashed line to the position shown by the solid line in FIG. The eject slider 76 pushes the protrusion 75 of the disc tray 2 in the direction of arrow a '.

  As a result, the disk tray 2 is automatically ejected from the disk device main body 1 by a predetermined length (about 15 mm to about 20 mm) in the direction of arrow a '. Therefore, after this, the user can easily eject the disk tray 2 in the direction of the arrow a 'by manually putting the hand on the front panel 2b of the disk tray 2, so that the disk 4 can be easily removed from the disk tray 2. it can.

  According to the emergency eject mechanism 140 shown in FIGS. 15 to 17, the clutch movable gear 60 of the clutch 63 provided in the gear train 57 is always meshed with the worm 58 by the worm wheel 59 integrated therewith. The clutch movable gear 60 is configured to mesh with and disengage from the clutch fixed gear 61 in the directions of arrows k and k ′, and the tip of the clutch driven lever 65 to which the clutch movable gear 60 is attached and the tip of the clutch lever 67 are substantially perpendicular. And a cam mechanism 70 in which the cam follower pin 68 of the clutch follower lever 65 is engaged in the arcuate cam groove 69 of the clutch lever 67 having a radius of curvature larger than the rotation radius of the cam follower pin 68. Thus, the distal ends of the clutch driven lever 65 and the clutch lever 67 are directly connected to each other.

  The cam mechanism 70 can lightly rotate the clutch driven lever 65 in the directions of the arrows k and k 'by rotating the clutch lever 67 in the directions of the arrows m and m'. , K 'direction is restricted by the clutch lever 67, and the cam mechanism has a function of giving priority to the operation from the clutch lever 67 side.

  Therefore, according to the configuration of the clutch 63, during normal operation, the clutch movable gear 60 is unlikely to be disengaged from the clutch fixed gear 61, and the transmission state of the gear train 57 can be stably maintained. The characteristic is that the clutch movable gear 60 can be easily disengaged from the clutch fixed gear 61 with a relatively light force (weak force).

  According to the disk table elevating mechanism 106 shown in FIGS. 1, 2, 5, and 7, three main movable frames 107 are provided on the chassis 1c with a pair of fulcrum portions 109 and a connecting portion 111 interposed therebetween. Since the insulators 115 and 119 elastically support the vibrations applied from the outside during recording and / or reproduction of the disk 4, the insulators 115 and 119 can reliably absorb the vibrations.

  Therefore, a data error or the like of the disk 4 due to the vibration can be prevented beforehand, and the characteristics and reliability of recording and / or reproduction can be significantly improved.

  As described above, one embodiment of the present invention has been described, but the present invention is not limited to the above-described embodiment, and various modifications can be made based on the technical idea of the present invention.

FIG. 3 is a plan view illustrating the inside of a disk device main body and a rack lever in an example of the disk device to which the present invention is applied. FIG. 3 is a perspective view illustrating the inside of the disk device main body. FIG. 6 is a plan view illustrating a state where loading of the disk into the disk device main body by the disk tray is completed. FIG. 4 is a perspective view of FIG. 3. FIG. 5A is a cross-sectional side view taken along the line EE of FIG. 3 for explaining the middle of loading and ejecting, and FIG. 5B is a sectional view of FIG. It is sectional drawing in the arrow direction. FIG. 3 is a perspective view showing a disk tray, a rack lever, and a cam lever. FIG. 3 is a perspective view showing a main part of a disk table elevating mechanism. FIG. 8A is an enlarged cross-sectional view taken along line FF of FIG. 1, and FIG. 8B is an enlarged sectional view taken along line GG of FIG. It is sectional drawing. FIG. 2 is an enlarged cross-sectional view taken along the line HH of FIG. 1 illustrating a lowering operation of the disk table by a disk table lifting mechanism. FIG. 2 is an enlarged cross-sectional view taken along the line HH of FIG. 1 for explaining the operation of the disk table elevating mechanism. FIG. 2 is an enlarged cross-sectional view taken along the line II of FIG. 1 and illustrating a process of mounting the disk on the disk table. FIG. 2 is an enlarged cross-sectional view taken along the line II of FIG. 1 and illustrating the completion of mounting the disk on the disk table. FIG. 4 is a plan view illustrating a positional relationship of a disk tray drive mechanism, a disk tray lock mechanism, a rack lever lock mechanism, and an emergency eject mechanism with respect to a rack lever. FIG. 3 is an exploded perspective view of a disk tray drive mechanism. It is an enlarged plan view of a disk tray drive mechanism and an emergency eject mechanism. FIG. 2 is an enlarged sectional view taken along the line JJ in FIG. 1. FIG. 4 is an enlarged plan view of the disc tray drive mechanism and the emergency eject mechanism, illustrating an emergency eject operation. FIG. 18A is an enlarged side view of the rack lever lock mechanism taken along the line KK of FIG. 1, and FIG. 18B is a view taken along the line LL of FIG. FIG. FIG. 4 is a partially cutaway plan view illustrating a disk tray lock mechanism and a rack lever lock mechanism. It is an expanded sectional view explaining lock operation and lock release operation of a rack lever lock mechanism. FIG. 2 is an enlarged cross-sectional view taken along line MM in FIG. 1. FIG. 29 is a cross-sectional view of the holding state of the disk on the disk tray taken along line AA of FIG. 28. FIG. 23 is a sectional view showing a chucking state of the disk by the disk table of FIG. 22. FIG. 4 is a perspective view showing an ejected state of the disc tray when the above-mentioned vertical use is performed. FIG. 25 is a perspective view showing a state where a disk is vertically mounted on the disk tray of FIG. 24. FIG. 25 is a perspective view showing a state in which loading of the disk into the disk device main body of FIG. 24 is completed. FIG. 25 is a side view of the disk tray of FIG. 24. FIG. 26 is a side view of the disc tray of FIG. 25. It is a perspective view of a lock arm same as the above. 30A is a plan view showing a state in which the lock arm of FIG. 29 is mounted on a disk tray, and FIG. 30B is a cross-sectional view taken along the line BB of FIG. 30A. . FIG. 31 is a cross-sectional view taken along the line CC in FIG. It is sectional drawing in the DD arrow of (A) of FIG. FIG. 32 is a cross-sectional view showing a released state of the disk holding shown in FIG. 31. FIG. 33 is a cross-sectional view illustrating a released state of the disk holding illustrated in FIG. 32. FIG. 3 is a plan view showing a mutual relationship among the lock arm, a pair of release levers, a cam lever and a rack lever according to the first embodiment. FIG. 36 is a plan view showing a driving state of a pair of release levers by the cam lever at the time of an overstroke of the rack lever of FIG. 35. FIG. 3 is a cross-sectional view illustrating a structure for attaching a release lever to the disk tray of the above. FIG. 3 is a perspective view showing a cam mechanism provided between a release lever and a cam lever of the same. It is a perspective view which shows the rack lever and pinion same as the above. FIG. 11 is a perspective view of a conventional disk drive when the disk is ejected when used horizontally. FIG. 41 is a cross-sectional view illustrating a horizontal use and a vertical use as viewed from arrows EE in FIG. 40. FIG. 9 is a perspective view showing a completed loading state of a disk when the conventional disk device is used horizontally. FIG. 5 is a side view for explaining a disk chucking release state of the disk by the disk table and the disk clamper in the disk device main body. FIG. 4 is a side view for explaining a disk chucking state by a disk table and a disk clamper in the disk device main body.

Explanation of reference numerals

DESCRIPTION OF REFERENCE NUMERALS 1 disk device main body 2 disk tray 3 recess 3a disk mounting surface of recess 3b taper surface of outer circumference of recess 4 disk 15 lock arm 15a as a disk holding member 15a tip of lock arm 15b other end of lock arm 16 rotation fulcrum Guide pin 19 which is a compression coil spring which is urging means 20 first slope 21 second slope 22 release arm sliding surface which is a control surface 25 release arm which is release means

Claims (4)

A disk tray on which the disk is placed in the recess,
A disk tray drive mechanism for loading the disk tray into the disk device body and ejecting the disk tray outside the disk device body;
A disk holding member provided on the outer periphery of the recess of the disk tray,
At the tip of the disc holding member, a first slope formed on the side opposite to the disc mounting surface side in the recess, and by pressing the outer periphery of the disc inserted into the recess, A first inclined surface for letting the disk holding member out of the recess, and a second inclined surface formed at the tip of the disk holding member on the disk mounting surface side in the recess, After the outer periphery of the disk has climbed over the first slope toward the disk mounting surface, the outer periphery of the disk is moved to the disk mounting position of the concave in synchronization with the return of the disk holding member to the center of the concave. A second inclined surface for guiding to and holding the mounting surface side. 2. The disk device according to claim 1, further comprising an urging means for urging the disk holding member to move from the outside of the recess toward the center. 2. The disk drive according to claim 1, further comprising a release unit configured to release the outer periphery of the disk by the disk holding member. The disk holding member is arranged vertically about a rotation fulcrum provided at the other end opposite to the end where the first and second slopes are formed with respect to the disk mounting surface in the recess. It is configured to rotate freely,
The release means is moved to the distal end side and the other end side on a control surface formed between the distal end and the other end of the disk holding member, so that the disk holding member is moved. 4. The disk device according to claim 3, wherein the disk is controlled to a holding position of the disk and a release position where the holding of the disk is released.

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