JP2009199646A - Disk drive - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a disk drive which can acquire proper clamp force without enlarging clamp sound in the status when the disk is not mounted, while maintaining vibration isolation performance of a turntable. <P>SOLUTION: The disk device includes: a clamper spring 81 which energizes a clamper 25 in a disk mounting status; and a pedestal spring 83 which pushes back a pedestal section 21 when it is pushed in. Consequently an optical disk 1 can be clamped by clamp force combined with clamper spring elastic force F3 and magnetic attraction force F2 without deflecting a float rubber 211 since the pedestal section 21 is pushed back by pedestal spring elastic force F4, while a clamper 25 is clamped on a turntable 24 by the magnetic attraction force F2 and clamper spring elastic force F3. The magnetic attraction force F2 can be made small compared with a configuration which acquires the clamp force only with the magnetic attraction force, and the clamp sound in the status when the disk is not mounted can be made small. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a disk device.

  2. Description of the Related Art Conventionally, disk devices for reproducing or recording a disk such as a DVD (Digital Versatile Disk) and a CD (Compact Disc) have been widely used. Such a disk device is usually provided with a clamp device for holding the disk. And the structure which clamps a disk-shaped recording medium is known by pressing a clamper on a turntable using a spring in a clamp apparatus (for example, refer patent documents 1, 2).

The one described in Patent Document 1 includes a disk pressing portion provided on an opening / closing lid of an optical disk device, and a pressing spring that biases the disk pressing portion. In addition, when the optical disc is mounted, the rotating member of the disc pressing portion presses the optical disc from the upper surface by a pressing spring.
The thing of patent document 2 is provided with the leaf | plate spring which has a fork part which supports a clamper. Then, when the optical disk is held, the clamper receives a downward pressing force from the spring and presses the optical disk onto the turntable.

  However, in the configuration in which the spring is urged only by the elastic force as described in Patent Documents 1 and 2, there is a risk of slipping (disk slip) on the turntable when the disk-shaped recording medium is rotated at high speed. . Therefore, in order to obtain a large clamping force (a force for clamping the disc-shaped recording medium between the clamper and the turntable) that does not cause the disc to slip even at high speed rotation, a configuration using the elastic force and magnetic force of the spring described above has been studied. (For example, refer to Patent Documents 3 and 4).

The one described in Patent Document 3 includes an elastic member having one end fixed on the clamper plate and the other end abutting against the apex of the clamper A. In addition, the four corners of the chassis where the spindle motor is disposed are attached to the elevator via anti-vibration rubber. The disk is chucked by the clamper B and the spindle motor by urging the clamper A toward the spindle motor with this elastic member. Furthermore, the structure which chucks a disk with the attractive force of a magnet is taken.
The thing of patent document 4 is provided with the convex part which protrudes from the holder metal plate of a clamper, and the clamper holding plate which contact | abuts a convex part at the time of disc mounting. The traverse having the turntable is provided with a floating rubber that absorbs external vibration. And the structure which presses a disk to a turntable using the magnetic force of a magnet and a yoke board is further employ | adopted as a convex part is urged | biased by a clamper holding plate.

Japanese Patent Laid-Open No. 10-3718 JP 2000-36149 A JP 2003-91904 A JP 2005-332456 A

  However, in the configurations as described in Patent Documents 3 and 4, the floating rubber or the like is bent by the spring elastic force and the turntable sinks, so that a necessary clamping force may not be obtained. In order to obtain the necessary clamping force while avoiding such sinking of the turntable, a configuration in which the hardness of the floating rubber is increased or a configuration in which the magnetic force is increased without using the spring elastic force can be considered. However, in the configuration in which the hardness of the floating rubber is increased, the amount of bending with respect to a predetermined vibration is reduced, and the vibration isolation performance for the turntable may be reduced. Further, in the configuration in which the magnetic force is increased, there is a possibility that the collision sound between the clamper and the turntable (hereinafter referred to as clamping sound) when the disc-shaped recording medium is not sandwiched is increased.

  In view of these points, the present invention provides a disc device that maintains vibration-proof performance for a turntable and that can obtain an appropriate clamping force without increasing the clamping noise when the disc-shaped recording medium is not mounted. One purpose is to provide it.

  According to the first aspect of the present invention, there is provided a chassis, a pedestal portion attached to the chassis via an elastically deformable vibration isolating member, and a disc-shaped recording medium attached to the pedestal portion and having a shaft hole. A turntable that is detachably provided on the turntable, and holds the disc-shaped recording medium by the turntable, and the turntable is moved away from the clamper by moving the pedestal portion away from the clamper. Pedestal perspective means for engaging with and disengaging from the clamper, and the turntable includes a substantially columnar fitting / inserting portion that can be inserted into and removed from the shaft hole of the disc-shaped recording medium, and a first portion provided in the fitting insertion portion. The clamper is formed in a concave shape that can be engaged and disengaged at one end in the axial direction of the fitting insertion portion, and a second magnetic body that generates a magnetic force with the first magnetic body. Insert And a clamper main body for holding the second magnetic body, wherein the clamper moves the clamper when the disc-shaped recording medium is sandwiched between the turntable and the clamper. A first urging means for urging the pedestal in the direction of the first urging force, and a first urging means for urging the pedestal in a direction substantially opposite to the urging direction when the pedestal is urged by the urging force of the first urging means. And a second urging means.

Hereinafter, an embodiment of the present invention will be described with reference to the drawings.
In the present embodiment, a disk device which is a processing device for recording and reading information on an optical disk as a disk-shaped recording medium will be described as an example. It should be noted that, for example, a reproduction device, a recording device, a game machine, or the like that performs recording and reproduction processing such as video data recording provided with a portable disk device is not limited to an optical disk, but a magnetic disk, a magneto-optical disk, or the like Any disk device that records or reads various information on this recording medium can be targeted. Examples of the recording medium include a CD (Compact Disc), a DVD (Digital Versatile Disc), a BD (Blu-ray Disc), and an HD-DVD (High Definition DVD).

[Disk unit configuration]
[Overall configuration]
First, the overall configuration of a disk device according to an embodiment of the present invention will be described.
FIG. 1 is an exploded perspective view showing an overall schematic configuration of a disk device according to an embodiment of the present invention.
In FIG. 1, the disk device 100 has a metal case body 10. The case body 10 includes an upper case 11 having a lower surface and a front surface that open over two surfaces, a lower case 12 that closes the lower surface of the upper case 11, and a decorative plate 13 that closes the front surface of the upper case 11. is doing.
The upper case 11 is formed with a substantially circular clamper spring insertion hole 11A. The upper case 11 is attached with a cover pressing member 14 that is formed in a substantially square plate shape and closes the clamper spring insertion hole 11A. The decorative plate 13 is formed with an opening 13A.

The case body 10 is provided with a frame 15 made of synthetic resin. The frame body 15 constitutes the case body 10 with the upper case 11, the lower case 12 and the decorative plate 13.
Further, the frame body 15 is provided with a clamper support member 17 that is fixed in a state of substantially closing the opening surface of the frame body 15. A support hole 171 is formed in the clamper support member 17 at a position facing a turntable 24 of the rotation drive means 23 described later. A substantially disc-shaped clamper 25 is rotatably mounted on the periphery of the support hole 171 so as to close the support hole 171. Between the clamper 25 and the cover pressing member 14, a clamper spring 81 as a first urging means and a substantially cylindrical clamper cover 82 whose one surface is closed are provided.

A main body 20 is disposed on the frame 15. The main body 20 has a pedestal 21 formed in, for example, a metal flat frame shape. The pedestal 21 is attached to the frame 15 at the other edge so that one edge can be rotated in the vertical direction. Specifically, the other edge of the pedestal portion 21 is attached to the frame body 15 via a float rubber 211 as a vibration isolating member.
A float base 22 is attached between the frame 15 and the pedestal portion 21 along one edge of the pedestal portion 21. The float base 22 has a longitudinal attachment holding portion 221 along one edge of the pedestal portion 21, and a pair of pivots integrally protruding substantially vertically at both ends in the longitudinal direction of the attachment holding portion 221. Arm portion 222.
Both ends of one edge of the pedestal portion 21 are attached to the attachment holding portion 221 via float rubber 211. The ends of the pair of rotating arm portions 222 are pivotally supported by the frame 15 so as to be rotatable. The pedestal 21 is guided to rotate by the float base 22.
Here, the frame 15 and the float base 22 constitute the chassis of the present invention.
Further, the pedestal portion 21 is provided with a rotation driving means 23 having a turntable 24, a pickup 31, and a process moving means 32 for moving the pickup 31.

  The frame 15 is provided with a disc tray 50 that moves in a horizontally movable manner. The disc tray 50 is formed in a substantially rectangular plate shape and has a tray portion 51 on which the optical disc 1 is placed. A window closing plate portion 52 that closes the window portion 13 </ b> A of the decorative plate 13 is attached to one edge of the tray portion 51.

The frame 15 is provided with an opening / closing driving means 60 as a pedestal distance means for carrying the disk tray 50 in and out. The opening / closing drive means 60 includes a drive transmission unit 61 provided with gears, pulleys, endless belts, and the like, and an in / out electric motor 64 as a motor. The opening / closing drive means 60 advances and retracts the disc tray 50 from the window portion 13 </ b> A of the decorative plate 13 through the drive transmission portion 61 by driving the electric motor 64 for entering and exiting.
Further, the opening / closing drive means 60 has a moving cam 68 disposed so as to be movable along the width direction of the frame body 15. The moving cam 68 is provided with a link groove (not shown) that engages with an engagement pin (not shown) of the float base 22. The moving cam 68 moves along the width direction of the frame 15 when the drive motor 61 is driven by the driving motor 64, and the pedestal portion moves by moving the engaging pin along the link groove. 21 is rotated in the up-down direction which is an advancing / retreating direction with respect to the clamper 25. In other words, to move the pedestal portion in the present invention closer to the clamper means to rotate the pedestal portion 21 in the vertical direction that is the advancing / retreating direction with respect to the clamper 25, that is, to approach / separate. A circuit board 70 is detachably attached to the frame 15.

[Configuration of main parts]
Next, the configuration of the main part of the disk device 100 will be described. In the following description, the state in which the optical disk 1 is not mounted is referred to as a disk non-mounted state, and the mounted state is referred to as a disk mounted state as appropriate.
FIG. 2 is a cross-sectional view showing a schematic configuration of a main part of the disk device when the disk is not loaded. FIG. 3 is a cross-sectional view showing a schematic configuration of a main part of the disk device in a disk-mounted state.

As shown in FIGS. 2 and 3, the rotation driving means 23 includes a turntable 24 and a motor 26 that rotates the turntable 24.
The turntable 24 is formed in a substantially disc shape, and has a substantially columnar insertion portion 241 that is inserted into the shaft hole 1 </ b> A of the optical disc 1, and an outer periphery on one end side in the axial direction of the insertion portion 241. And a mounting portion 242 for projecting in a bowl shape on which the optical disc 1 is mounted. A magnet 243 serving as a first magnetic body is embedded at the tip of the insertion portion 241.
The motor 26 to which the motor support plate 212 is attached is fixed to the pedestal portion 21 and provided at a position facing the clamper 25.

  In addition, the float base 22 to which the pedestal portion 21 is fixed includes a float base bottom surface portion 223 positioned below the motor support plate 212. Between the float base bottom surface part 223 and the motor support plate 212, a pedestal spring 83 is disposed as second urging means. The base spring 83 is not contracted when the downward biasing force is not applied to the base portion 21 and the float rubber 211 is not bent, and the downward biasing force is applied to the float rubber 211 so that the float rubber 211 is not bent. It is formed in a shape that shrinks when it is damaged. The pedestal spring 83 is provided at a position substantially opposite to the clamper 25 with the turntable 24 interposed therebetween.

A cover engaging recess 14A that is recessed in a substantially spherical shape is provided in the approximate center of the cover pressing member 14.
The clamper 25 formed in a substantially disc shape is a second plate having a substantially plate shape such as a clamper main body portion 251 made of synthetic resin and a metal plate that is held by the clamper main body portion 251 and generates a magnetic force with the magnet 243. And a clamper plate 252 as a magnetic body.
The clamper main body 251 has a concave insertion portion 251A in which the other end in the axial direction of the fitting insertion portion 241 can be inserted and removed, and protrudes outwardly from the opening edge of the insertion portion 251A in a bowl shape. The holding portion 242 has a holding portion 251B that holds the optical disc 1 and a flange portion 251C that protrudes outwardly from the periphery of the holding portion 251B in a hook shape. Further, the insertion portion 251A has a side wall portion 251D that forms the peripheral surface thereof, and a bottom portion 251E that forms the bottom surface. As shown in FIG. 2, the bottom portion 251E comes into contact with the magnet 243 of the turntable 24 when the disk is not mounted, and the distance between the magnet 243 and the clamper plate 252 at this time is the unmounted distance P1. It is configured. That is, the thickness dimension of the bottom portion 251E is set to the unmounted distance P1. The thickness of the bottom portion 251E is set to be larger than that of the bottom portion configured to obtain the clamping force only by the magnetic attractive force (hereinafter referred to as magnetic attractive force) between the magnet 243 and the clamper plate 252.
The clamper plate 252 is formed in a substantially disc shape, and is provided in a state in which one surface thereof is in contact with the bottom 251E of the clamper main body 251.

A substantially spherical cover engaging convex portion 821 that engages with the cover engaging concave portion 14A is provided at substantially the center of one surface of the clamper cover 82. The clamper cover 82 is provided so as to be rotatable with respect to the cover pressing member 14 by engagement between the cover engaging convex portion 821 and the cover engaging concave portion 14A.
The clamper spring 81 is provided in a state where one end side in the axial direction is in contact with the clamper plate 252 and the other end side is positioned in the clamper cover 82. The clamper spring 81 is in a disc-unmounted state as shown in FIG. 2 and does not contract when the bottom portion 251E of the clamper 25 and the magnet 243 are in contact with each other. It is formed in a shape that shrinks when the optical disk 1 is present between the turntable 25 and the turntable 24.
When the turntable 24 and the clamper 25 rotate when the optical disk 1 is reproduced, for example, the clamper spring 81 and the clamper cover 82 also rotate.

[Disk unit operation]
Next, the operation of the disk device 100 will be described.

First, the operation when the disk is not loaded will be described.
When the disc tray 50 is carried into the disc device 100 in a state where the optical disc 1 is not placed, the pedestal portion 21 rises and the rotational drive means 23 also rises.
The turntable 24 is attracted to the clamper 25 side by the magnetic force generated between the magnet 243 of the turntable 24 and the clamper plate 252 of the clamper 25, and corresponds to the unmounted distance P1 as shown in FIG. The bottom portion 251E and the magnet 243 are brought into close contact with each other by the downward magnet attractive force F1. In addition, as described above, the clamper spring 81 does not contract when the disk is not mounted, so the pedestal 21 is not pushed in and the pedestal spring 83 does not contract. That is, only the magnet attractive force F <b> 1 acts on the turntable 24 when the disk is not mounted.

Next, the operation when the disk is mounted will be described.
When the optical disc 1 placed on the disc tray 50 is carried into the disc device 100, the pedestal portion 21 is raised, and the rotation driving means 23 is also raised at the same time, and the optical disc 1 is inserted into the insertion portion 241 of the turntable 24. The shaft hole 1A is inserted and the optical disc 1 is placed on the placement portion 242.
The turntable 24 is attracted to the clamper 25 side by the magnetic force generated between the magnet 243 and the clamper plate 252, and the downward magnet corresponding to the distance between the magnet 243 and the clamper plate 252 as shown in FIG. The optical disk 1 is clamped by the suction force F2. Here, the distance P2 between the magnet 243 and the clamper plate 252 (hereinafter referred to as a mounted distance) P2 is a thickness dimension of the optical disc 1 and a clearance dimension between the holding portion 251B and the mounting portion 242 when not mounted. The difference (hereinafter referred to as an increased dimension at the time of mounting) is added to the distance P1 when not mounted, which is longer than when the disk is not mounted. For this reason, the magnitude of the magnet attractive force F2 is smaller than the magnet attractive force F1.

Further, when the optical disc 1 is sandwiched, the clamper spring 81 positioned above the clamper 25 is contracted by an increased dimension when mounted. The clamper 25 is biased downward by an elastic force (hereinafter referred to as clamper spring elastic force) F3 generated along with this contraction, and the pedestal portion 21 to which the turntable 24 and the like are attached is also biased downward. . Further, when the pedestal portion 21 is pushed downward, the pedestal spring 83 is contracted, and the pedestal portion 21 is pushed back upward by an elastic force (hereinafter referred to as a pedestal spring elastic force) F4 generated along with this contraction. For this reason, the float rubber 211 does not bend.
That is, the base spring elastic force F4 having the same magnitude as the clamper spring elastic force F3 acts in the substantially opposite direction, so that the sink of the base portion 21 is prevented, and the clamper spring elastic force F3, the magnet attractive force F2, The optical disc 1 is clamped with a clamping force that combines the above.

[Operation of disk unit]
Next, the operation of the disk device 100 will be described based on an experiment for confirming the effect of the present invention.
FIG. 4 is an explanatory diagram showing an experimental method. FIG. 5 is a graph showing the relationship between the operation time and the volume of the clamp sound in the clampers of Examples 1 and 2 and the comparative example. FIG. 6 is a graph showing the relationship between the operation time and the volume of the unclamping sound in the clampers of Examples 1 and 2 and the comparative example.

[Sample structure]
As the clamper 901 of the first embodiment used in the experiment as shown in FIG. 4, the bottom 251E having a thickness dimension of the unmounted distance P1 as shown in FIG. 2 was applied.
Further, as the clamper 902 of the second embodiment, the one having a thickness of the bottom portion 251E smaller by 0.3 mm than the unmounted distance P1 was applied.
Further, as the clamper 903 of the comparative example, the one whose thickness of the bottom portion 251E is 0.5 mm smaller than the unmounted distance P1 was applied. Here, the clamper 903 of the comparative example is applied to a configuration in which the clamper spring 81 and the base spring 83 are not provided and the clamping force is obtained only by the magnetic attractive force.

〔experimental method〕
As shown in FIG. 4, in the anechoic chamber, the disk device 900 including the clamper 901 and the turntable 24 of Example 1 was placed on the placement table 951. Further, the microphone 953 connected to the measuring instrument 952 was suspended at a position where the distance to the center of the clamper 901 of Example 1 was 300 mm. The disk device 900 includes the same mechanism as the disk device 100 of the above embodiment except that the clamper spring 81 and the base spring 83 are not included.
Then, the disk tray was loaded into the disk device 900 when the disk was not loaded, and the relationship between the elapsed time from the start of the operation and the clamping sound when the turntable 24 and the clamper 25 were in close contact was examined. . Further, from this state, the disc tray was unloaded, and the relationship between the elapsed time from the start of the operation and the unclamping sound when the turntable 24 and the clamper 25 were separated was examined. The same relationship was examined for the clampers 902 and 903 of Example 2 and Comparative Example.

〔Experimental result〕
As shown in FIGS. 5 and 6, it was confirmed that the clamp sound and the unclamp sound were reduced in the order of the clamper 903 of the comparative example, the clamper 902 of the second example, and the clamper 901 of the first example. In particular, it was confirmed that the clamp sound of the clamper 901 of Example 1 was about 10 dB lower than that of the clamper 903 of the comparative example. Further, it was confirmed that the unclamping sound of the clamper 901 of Example 1 was about 6 dB smaller than that of the clamper 903 of the comparative example.
This is considered to be because the magnetic attractive force decreases as the distance between the magnet 243 and the clamper plate 252 increases, and the impact at the time of close contact or separation between the turntable 24 and the clamper 25 decreases.
From the above, it was confirmed that the clamping noise and the unclamping sound when the disk is not installed can be reduced by reducing the magnetic attractive force as compared with the configuration in which the clamping force is obtained only by the magnetic attractive force.

[Effect of disk unit]
As described above, in the above embodiment, the following effects can be achieved.

(1) A clamper spring 81 that urges the clamper 25 in the direction of the turntable 24 when the disc is mounted and a pedestal portion 21 provided with the turntable 24 are pushed into the disc device 100 by the urging force of the clamper spring 81. And a pedestal spring 83 that pushes back the pedestal portion 21 on the substantially opposite side to the pushing direction.
For this reason, the clamper 25 is pressed against the turntable 24 by the magnet attractive force F2 and the clamper spring elastic force F3, and the pedestal 21 is pushed back by the pedestal spring elastic force F4. The optical disk 1 can be clamped with a clamping force that combines the force F3 and the magnet attractive force F2. Therefore, it is possible to obtain a clamping force necessary for high-speed rotation while maintaining the anti-vibration performance for the turntable 24.
In addition, since the clamper spring elastic force F3 is used as a clamping force, the magnet attractive force F2 can be reduced as compared with the configuration in which the clamping force is obtained only by the magnet attractive force, and the clamp sound and unclamp when the disc is not installed. Sound can be reduced.
Furthermore, since the magnet attractive force F2 can be reduced, the force for peeling off the turntable 24 from the clamper 25 can be reduced, and the force of the electric motor 64 for entry / exit serving as a drive source for pulling down the pedestal portion 21 can be reduced.
Then, the relationship between the clamping force and the clamping sound can be adjusted by setting the thickness dimension of the bottom portion 251E in accordance with the maximum rotational speed of the turntable 24.

(2) The pedestal spring 83 is provided at a position substantially opposite to the clamper 25 with the turntable 24 interposed therebetween.
Therefore, the pedestal spring elastic force F4 for urging the turntable 24 in the direction substantially opposite to the clamper spring elastic force F3 can be applied to a position substantially equal to the position urged by the clamper spring elastic force F3. The pedestal 21 can be efficiently pushed back without increasing the biasing force of the pedestal spring elastic force F4.

(3) As the first and second urging means of the present invention, a clamper spring 81 and a pedestal spring 83 which are generally inexpensive and simple in configuration are applied.
For this reason, it is possible to easily reduce the cost of the disk device 100 and improve the assemblability.

[Other Embodiments]
The present invention is not limited to the above-described embodiment, but includes modifications and improvements as long as the object of the present invention can be achieved.

That is, the pedestal spring 83 is provided in contact with the motor support plate 212. However, the pedestal spring 83 may be provided in contact with the pedestal 21 directly. You may provide in the position which does not oppose the clamper 25 substantially.
Moreover, it is good also as a structure as shown in FIGS.

In the configuration shown in FIG. 7, a pedestal leaf spring 84 </ b> A as two second urging means is provided instead of the pedestal spring 83. The pedestal leaf spring 84A has one end fixed to the float base bottom surface 223, the other end abutted against the motor support plate 212, and pushes back the pedestal 21 when the pedestal 21 is pushed.
In the configuration shown in FIG. 8, instead of the clamper plate 252 and the clamper spring 81, a clamper plate 253A as a second magnetic body and ten clamper springs 85A as first urging means are provided. On one surface of the clamper plate 253A, there is provided a spring engaging portion 253A1 with which ten clamper springs 85A are engaged. The clamper spring 85A biases the clamper 25 in the direction of the turntable 24 when the disk is mounted.

In the configuration shown in FIG. 9, a clamper leaf spring 85 </ b> B as a first urging means is provided instead of the clamper spring 81. On one end side of the clamper leaf spring 85B, a substantially hemispherical spring protrusion 85B1 that engages with the recess 251F at the substantially center of the clamper main body 251 is provided. The clamper leaf spring 85B has a spring protrusion 85B1 at one end rotatably engaged with the recess 251F, and the other end is fixed to the cover pressing member 14, and the clamper 25 is directed toward the turntable 24 when the disk is mounted. Energize.
In the configuration shown in FIG. 10, a clamper spring 85C as a first urging means is provided instead of the clamper leaf spring 85B shown in FIG. One end of the clamper spring 85C is provided with a substantially spherical spring spherical engagement portion 85C1 that engages with the recess 251F. The clamper spring 85C has a spring spherical engagement portion 85C1 on one end side rotatably engaged with the concave portion 251F, and the other end side is fixed to the cover pressing member 14, and the clamper 25 is directed to the turntable 24 when the disc is mounted. Energize to.

  In addition, the specific structure and procedure for carrying out the present invention can be appropriately changed to other structures and the like within a range in which the object of the present invention can be achieved.

[Effects of Embodiment]
As described above, the clamper spring 81 that urges the clamper 25 in the direction of the turntable 24 when the disc is mounted and the pedestal 21 when the pedestal 21 is pushed by the urging force of the clamper spring 81 when the disc is mounted. And a pedestal spring 83 that pushes back 21.
For this reason, the clamper 25 is pressed against the turntable 24 by the magnet attractive force F2 and the clamper spring elastic force F3, and the pedestal 21 is pushed back by the pedestal spring elastic force F4. The optical disk 1 can be clamped with a clamping force that combines the force F3 and the magnet attractive force F2. Therefore, it is possible to obtain a clamping force necessary for high-speed rotation while maintaining the anti-vibration performance for the turntable 24. In addition, since the clamper spring elastic force F3 is used as a clamping force, the magnet attractive force F2 can be reduced as compared with the configuration in which the clamping force is obtained only by the magnet attractive force, and the clamp sound and unclamp when the disc is not installed. Sound can be reduced.

1 is an exploded perspective view showing an overall schematic configuration of a disk device according to an embodiment of the present invention. It is sectional drawing which shows schematic structure of the principal part of the disc apparatus in the disc non-mounted state in the said one Embodiment. It is sectional drawing which shows schematic structure of the principal part of the disc apparatus in the disc mounting state in the said one Embodiment. It is explanatory drawing which shows the experimental method for confirming the effect of the disc apparatus in the said one Embodiment. It is a graph which shows the relationship between the operation time in the clamper of Example 1, 2 and a comparative example, and the volume of a clamp sound. It is a graph which shows the relationship between the operation time in the clamper of Example 1, 2 and a comparative example, and the volume of an unclamp sound. It is sectional drawing which shows schematic structure of the principal part of the disc apparatus concerning other embodiment of this invention. It is a disassembled perspective view which shows schematic structure of the principal part of the disc apparatus based on further another embodiment of this invention. It is sectional drawing which shows schematic structure of the principal part of the disc apparatus which concerns on further another embodiment of this invention. It is sectional drawing which shows schematic structure of the principal part of the disc apparatus which concerns on further another embodiment of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Optical disk as a disk-shaped recording medium 1A ... Shaft hole 15 ... Frame body which comprises chassis 21 ... Base part 22 ... Float base which comprises chassis 24 ... Turntable 25 ... Clamper 60 ... Opening / closing drive means as base distance means 81, 85A, 85C: clamper spring as first urging means 83 ... pedestal spring as second urging means 84A ... pedestal leaf spring as second urging means 85B: clamper leaf spring as first urging means DESCRIPTION OF SYMBOLS 100 ... Disk apparatus 211 ... Float rubber as a vibration isolator 241 ... Insertion part 243 ... Magnet as 1st magnetic body 251 ... Clamper main-body part 251A ... Insertion part 252,253A ... Clamper plate as 2nd magnetic body

Claims (2)

The chassis,
A pedestal portion attached to the chassis via an elastically deformable vibration isolating member;
A turntable mounted on the pedestal portion and on which a disk-shaped recording medium having a shaft hole is placed;
A clamper that is detachably attached to the turntable, and clamps the disc-shaped recording medium with the turntable;
A pedestal distance means for engaging and disengaging the turntable with the clamper by moving the pedestal portion away from the clamper;
The turntable includes a substantially columnar insertion portion that can be inserted into and removed from the shaft hole of the disc-shaped recording medium, and a first magnetic body provided in the insertion portion.
The clamper includes a second magnetic body that generates a magnetic force with the first magnetic body, and a second insertion portion formed in a concave shape that can be engaged and disengaged at one axial end portion of the fitting insertion portion. A clamper body holding a magnetic body, and a disk device comprising:
First biasing means for biasing the clamper in the direction of the turntable when a disc-shaped recording medium is sandwiched between the turntable and the clamper;
Second urging means for urging the pedestal portion substantially opposite to the urging direction when the pedestal portion is urged by the urging force of the first urging means;
A disk apparatus comprising: The disk device according to claim 1,
The disk device, wherein the second urging means is provided at a position substantially opposite to the clamper with the turntable interposed therebetween.

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