JP3641060B2 - Disc clamp device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a disk clamping device for clamping a disk-shaped recording medium such as an optical disk housed in a disk cartridge and rotationally driving it with a spindle motor, and in particular, a current CD-ROM and a next-generation SD-ROM, A plurality of types of standard disks such as an optical disk with a diameter of 120 mm called SD-RAM and a next-generation compact optical disk called 3.5 inch type are alternately chucked and driven by the same mechanism. The present invention relates to a disc clamping device for the above.
[0002]
[Prior art]
There are various product forms of optical discs on which information can be optically recorded / reproduced by a light beam such as a laser beam. One of the typical optical discs is a CD-ROM as a read-only disc. Any of the current optical disk drive devices for driving the CD-ROM is a dedicated drive for driving only the CD-ROM.
[0003]
On the other hand, development of a next-generation compact optical disk called a 3.5-inch type has been promoted in recent years. In parallel with this, various types of optical disk drive devices for 3.5-inch type optical disks have been sought, but this is also a dedicated drive for driving only 3.5-inch type optical disks.
[0004]
The reason why the optical disk drive has been developed as a dedicated drive for a specific optical disk in this way is that, for example, both CD-ROM and 3.5-inch type optical disks employ magnetic chucking. The clamp area (clamp radius, clamp height) is different according to the standard, and the turntable for CD-ROM is larger in diameter than the spindle hole of the cartridge in which the 3.5-inch type optical disk is stored, and is the same This is because it is substantially impossible to chuck the CD-ROM and the 3.5-inch type optical disk in the turntable of No. 1.
[0005]
Therefore, for example, as described in Japanese Patent Laid-Open No. 2-172054, in order to be able to drive two types of disc-shaped recording media having different sizes with the same spindle motor, each disc-shaped recording medium is mounted. There has been proposed a disk clamp device having two rotary table members for the purpose. However, this disc clamp device requires a mechanism for moving the turntable and a mechanism for identifying the disc for selecting the turntable. For this reason, there is a problem that not only the structure is complicated and it is difficult to reduce the size of the apparatus, but also the current consumption of the spindle motor increases because the rotating part becomes heavy.
[0006]
Further, in the disk clamp device disclosed in the above Japanese Patent Laid-Open No. 2-172054, a pin member that engages with the center hole of the center hub of the recording medium is provided on the motor shaft. Then, the pin member is screwed to the screw portion of the motor shaft, and the first rotary table member is screwed to the screw portion on the outer periphery of the pin member, and the rotation of the first rotary table member is rotated by the rotation suppression member. The first rotary table member and the pin member are shifted in the vertical direction by rotating the motor forward and backward in the inhibited state.
[0007]
Therefore, in this disk clamp device, when driving a disk-shaped recording medium in which two substrates recorded in a spiral in the same direction are driven in order to suppress eccentricity, two substrates are used for recording / reproducing information. In order to change the rotation direction of the spindle motor in correspondence with the front and back surfaces, the screw coupling portion may be loosened on either side, and the first rotary table member and the pin member may be lowered. In such a case, the disc-shaped recording medium is not held at a predetermined height position.
[0008]
On the other hand, Japanese Patent Application Laid-Open No. 61-54083 discloses a disc-shaped information recording medium storage case for allowing the same disc to be mounted on different playback devices. However, in this configuration, a holder 13 serving as an adapter for aligning the disc clamp height regardless of the playback device is provided outside the case formed by the upper lid and the housing 2 and is fitted to the case. As a result, the case is poorly sealed, and the holder 13 protrudes, so the stability and stowability when placed are poor.
[0009]
Furthermore, the 3.5-inch disk cartridge and the next-generation SD-ROM cartridge have a cartridge thickness different from the standard, and the next-generation CD-ROM cartridge thickness is larger than the 3.5-inch cartridge thickness. For this reason, when the turntable for mounting the next generation CD-ROM disc on the outside is fixed and the turntable for the inner 3.5 inch disc is moved, the central axis of the disc is 3.5 inch disc. And CD-ROM disc. In order to avoid this, it is necessary to move the optical head for recording / reproducing information in the height direction or to move the spindle motor in the vertical direction, and the movement mechanism for this is complicated. There is.
[0010]
[Problems to be solved by the invention]
As described above, in order to enable two types of disc-shaped recording media of different sizes to be driven by the same spindle motor, the conventional disc clamp device having two rotary table members has a large turntable moving mechanism. In the case where an adapter is provided outside the case so that the same disc can be used as a different playback device, the case is sealed and stable when placed. There was a problem of poor storage.
[0011]
Further, in the conventional disk clamp device, since the screw table is used to shift the rotary table member in the vertical direction with respect to the motor shaft, the rotation direction of the spindle motor when reading / writing information is limited to one direction. Further, there is a problem that it is not possible to drive a disk-shaped recording medium in which two substrates on which spiral recording in the same direction is bonded to suppress eccentricity.
[0012]
Furthermore, when the size of the disk-shaped recording medium is different, the thickness of the recording medium is also different. In this case, when reading and writing information on the disk-shaped recording medium, the height of the recording / reproducing optical head is also required, but the type is different because the moving distance of the optical head is limited. Even when the recording medium is loaded, it is necessary to determine the disk clamp position so that the center line in the thickness direction is as much as possible.
[0013]
SUMMARY OF THE INVENTION An object of the present invention is to provide a disc clamping device having a structure capable of rotating a spindle motor in either forward or reverse direction and capable of chucking and driving a plurality of types of disc-shaped media having different sizes by the same spindle motor and chucking mechanism. Is to provide.
[0014]
It is another object of the present invention to provide a disc clamping device in which the central axis of the disc-shaped medium hardly changes even when two types of disc-shaped recording media having different sizes are attached.
[0015]
[Means for Solving the Problems]
  This invention has a predetermined diameter.First 1 ofA first disk-shaped recording medium housed in a first disk cartridge having a spindle hole, and a diameter smaller than the spindle hole of the first disk cartridge;SecondIn a disk clamp device for rotationally driving a second disk-shaped recording medium housed in a second disk cartridge having a spindle hole with the same spindle motor,
  When the first disc-shaped recording medium is used, which is fixed to the output shaft of the spindle motorSaid 1 Through the spindle holeA first turntable carrying the first disk-shaped recording medium, and movable in the axial direction of the output shaft coaxially with the first turntable on the inner peripheral side of the first turntable And when the second disk-shaped recording medium is usedThrough the second spindle holeA second turntable carrying the second disc-shaped recording medium, and the second turntableThe upper part of the second turntable is pushed upward by pushing up the output shaft in the upper limit direction, 1 Make it protrude beyond the turntableA first compression coil spring and an inner peripheral side of the second turntable arranged coaxially with the first and second turntables and movable in the axial direction; A centering member for centering and the centering memberThe upper part of the output shaft is pushed upward, and the upper part of the centering member is protruded from the second turntable by urging.The second compression coil spring and the centering member are interlocked with each other,When the centering member is pressed against the second compression coil spring by the second disk-shaped recording medium, the second turntable and the output shaft are brought into a locked state, and the pressing is released. In this state, a lock member that locks the second turntable and the output shaft and an upper portion of the output shaft are disposed on the first turntable. 1 When the first disk cartridge is used. 1 The second turntable is pressed against the disc cartridge. 1 The disc-shaped recording medium presses, the centering member enters the spindle hole, and the 1 Along with the turntable 1 When the second disk cartridge is used, the second disk cartridge and the spindle motor come close to each other so that the centering member is moved to the second disk-shaped recording medium. When the second disk-shaped recording medium is carried on the second turntable, the center hub of the second disk-shaped recording medium is formed in conjunction with the pressing of the second disk-shaped recording medium. A permanent magnet provided around the tip side of the output shaft so as to generate a magnetic chucking force betweenIt comprises.
[0037]
Thus, the disk-shaped recording medium can be clamped without any problem when the disk-shaped recording medium having the chuck surface directly coupled to the output shaft of the spindle motor and the disk-shaped recording medium not having the chuck surface are driven to rotate. And the output shaft of the spindle motor are coupled. Therefore, with the same mechanism, for example, a current CD-ROM, a next-generation SD-ROM, an optical disk with a diameter of 120 mm called SD-RAM, and a next-generation compact optical disk called a 3.5-inch type Alternatively, it can be chucked and mounted on the optical disk drive.
[0038]
DETAILED DESCRIPTION OF THE INVENTION
(First embodiment)
The first embodiment will be described with reference to FIGS.
The disc clamping device of this embodiment includes a first optical disc 101 housed in a first disc cartridge 102 having a spindle hole of a predetermined diameter, and a spindle hole having a smaller diameter than the spindle hole of the first disc cartridge 102. This is a disk clamping device for rotationally driving the second optical disk 103 accommodated in the second disk cartridge 104 having the same spindle motor 112.
[0039]
  This disk clamp device is an output shaft of a spindle motor 112 (hereinafter referred to as a spindle motor output shaft).133A first turntable 125 that is fixed to the first optical disk 101 and carries the first optical disk 101 when the first optical disk 101 is used, and a spindle coaxial with the turntable 125 on the inner peripheral side of the first turntable 125 and a spindle. Motor output shaft133The second turntable 115 is disposed so as to be movable in the axial direction of the second optical disk 103 and carries the optical disk 103 when the second optical disk 103 is used, and the second turntable 115 is connected to the spindle motor output shaft.133The first compression coil spring 116 for holding the shaft movably in the axial direction, and the spindle motor output shaft coaxially with the first and second turntables 125 and 115 on the inner peripheral side of the second turntable 115133And a centering member 117 for centering the first optical disc 101, and the centering member 117 as a spindle motor output shaft.133The second compression coil spring 118, the second turntable 115, and the centering member 117, which are movably held in the axial direction, are respectively pressed by the second optical disk 103 when the second optical disk 103 is used. Spindle motor output shaft133At least one locking member for preventing rotation and axial movement of the second turntable 115 relative to119a, 119b, 121a, 121bAnd have.
[0040]
  When the first optical disk 101 is used, the second turntable 115 is moved in the axial direction to the same position as the carrying surface of the first turntable 125 by the first optical disk 101, and the centering member 117 is the first. By centering the optical disc 101, the first optical disc 101 is supported by the first turntable 125. When the second optical disk 103 is used, a lock member is used.119a, 119b, 121a, 121bIs pressed in the axial direction by the second optical disk 103, and the spindle motor output shaft133The second optical disk 103 is carried by the second turntable 115 by preventing the second turntable 115 from rotating and moving in the axial direction.
[0041]
First, drawings used in this embodiment will be described.
FIG. 1 is a simplified diagram showing a state of an optical disk drive device including a first optical disk cartridge (optical disk cartridge having a disk diameter of 120 mm) 102 and a disk clamping device before the first optical disk (optical disk having a disk diameter of 120 mm) 101 is clamped. FIG. FIG. 2 is a cross-sectional view of the disk clamp device, and FIG. 3 is an enlarged cross-sectional view of the main part of the disk clamp device.
[0042]
FIG. 4 is a simplified diagram showing the state of the optical disk drive device including the first optical disk cartridge (optical disk cartridge with a disk diameter of 120 mm) 102 and the disk clamping device when the first optical disk (optical disk with a disk diameter of 120 mm) 101 is clamped. FIG. FIG. 5 is a cross-sectional view of the disk clamp device, and FIG. 6 is an enlarged cross-sectional view of the main part of the disk clamp device.
[0043]
FIG. 7 includes a second optical disk cartridge (3.5-inch type optical disk cartridge) 104, a cartridge adapter 105, and a disk clamping device before the second optical disk (3.5-inch type optical disk) 103 is clamped. It is the simplified sectional view showing the state of an optical disk drive. FIG. 8 is a cross-sectional view of the disk clamp device, and FIG. 9 is an enlarged cross-sectional view of the main part of the disk clamp device.
[0044]
FIG. 10 shows a second optical disk cartridge (3.5-inch type optical disk cartridge) 104 housed in the cartridge adapter 5 and a disk clamp when the second optical disk (3.5-inch type optical disk) 103 is clamped. It is the simplified sectional view showing the state of the optical disk drive containing a device. FIG. 11 is a cross-sectional view of the disk clamp device, and FIG. 12 is an enlarged cross-sectional view of the main part of the disk clamp device.
[0045]
In FIG. 1, a first optical disc 101 is rotatably accommodated in a first optical disc cartridge 102. The first optical disk 101 is an optical disk having a disk diameter of 120 mm, which may be either a bonded / double-sided type or a single-sided single-sided type. A center hole 106 for center positioning is formed in the center of the first optical disc 101. Spindle holes 107a and 107b are provided on both surfaces of the central portion of the optical disk cartridge 102, and information recording / reproducing laser beams are irradiated onto the first optical disk 101 from a recording / reproducing optical system (not shown). An access window for performing reproduction and a shutter that is slidable in the radial direction (both not shown) are provided. This shutter closes the spindle holes 107a and 107b and an access window (not shown) by a shutter spring (not shown) when the optical disk cartridge 102 is not used, and opens them only when the optical disc cartridge 102 is used.
[0046]
On the other hand, in FIG. 7, the second optical disk 103 is rotatably accommodated in the second optical disk cartridge 104. The second optical disk 103 is, for example, a bonded / double-sided 3.5 inch optical disk. Center hubs 108a and 108b made of a thin metal plate are provided on both surfaces of the center portion of the second optical disk 103, and center holes 109a and 109b for center positioning are formed in these center hubs 108a and 108b. Yes.
[0047]
Spindle holes 110 a and 110 b are provided on both surfaces of the center portion of the second optical disk cartridge 104. The entire second optical disk cartridge 104 is accommodated in a cartridge adapter 105. The cartridge adapter 105 is provided with spindle holes 111a and 111b communicating with the spindle holes 110a and 110b of the second optical disk cartridge 104.
[0048]
The second optical disk cartridge 104 and the cartridge adapter 105 communicate with each other for recording / reproducing information by irradiating the second optical disk 103 with an information recording / reproducing laser beam from a recording / reproducing optical system (not shown). And a shutter (none of which is shown) slidable in the radial direction. This shutter closes the spindle holes 110a and 110b and an access window (not shown) by a shutter spring (not shown) when the second optical disc cartridge 104 is not used, and opens them only when the second optical disc cartridge 104 is used.
[0049]
The cartridge adapter 105 has the same shape and size as the first optical disc cartridge 102 described above, that is, the thickness and the vertical and horizontal dimensions are the same.
[0050]
  Next, the clamp mechanisms corresponding to the first and second optical disks 101 and 103 will be described in detail.
  First, a clamp mechanism corresponding to the first optical disc 101 will be described with reference to FIGS.
  In FIG. 1, until the first optical disk cartridge 102 is loaded to a predetermined position, the spindle motor 112, the clamp member 113, and the position regulating member 114 are in positions that do not physically interfere with the first optical disk cartridge 102. . At this time, the spindle motor 112 is in the state shown in FIG. That is, in FIG. 3, the second turntable 115 is at the upper limit position in the axial direction of the spindle motor output shaft 133 by the first compression coil spring 116. The centering member 117 is driven by the spindle motor output by the second compression coil spring 118.axisThe upper limit position in the axial direction is 133. Since the first lock pins 119a and 119b disposed across the centering member 117 and the second turntable 115 are in a free state, the second lock pins 121a and 121b disposed on the second turntable 115 are free. Is in the unlocked position by the spring force of the third compression coil springs 123a and 123b. Here, it goes without saying that the location and number of the first lock pins 119a and 119b, the second lock pins 121a and 121b, and the third compression coil springs 123a and 123b can be arbitrarily selected as necessary.
[0051]
Next, as shown in FIG. 4, after the first optical disc cartridge 102 is loaded to a predetermined position, the clamp member 113 and the position regulating member 114 are moved in the direction of the spindle motor 112 to the predetermined position, and the spindle motor 112. Move to a predetermined position in the direction of the clamp member 113 by a moving mechanism (not shown). Note that instead of the spindle motor 112 moving in the direction of the clamp member 113 to a predetermined position, the first optical disk cartridge 102 may be moved in the direction of the spindle motor 112 to a predetermined position by a moving mechanism (not shown). Needless to say. Then, the first optical disk 101 is rotatable and the first turntable 125 and the clamp member by the magnetic chucking force by the permanent magnet 130 fixed to the spindle motor output shaft 133 and the magnetic body 129 fixed to the clamp member 113. Clamped by 113. The clamping operation at this time will be described with reference to FIG.
[0052]
The second turntable 115 supported by the first compression coil spring 116 so as to be movable in the axial direction of the spindle motor output shaft 133 is pressed against the first optical disc 101 to the same position as the clamp surface of the first turntable 125. Is done. At the same time, the centering member 117 supported by the second compression coil spring 118 so as to be movable in the axial direction of the spindle motor output shaft 133 performs the spindle motor output by the first optical disc 101 while centering the first optical disc 101. It is pressed in the axial direction of the shaft 133. Then, the center pin hole 131 provided in the clamp member 113 and the center pin 127 are fitted, and the first optical disc 101 is clamped rotatably.
[0053]
Next, a clamp mechanism corresponding to the second optical disc 103 will be described with reference to FIGS.
In FIG. 7, until the second optical disk cartridge 104 is loaded to a predetermined position, the spindle motor 112, the clamp member 113, and the position restricting portion 114 are in positions that do not physically interfere with the second optical disk cartridge 104. . At this time, the spindle motor 112 is in the state shown in FIG. That is, in FIG. 9, the second turntable 115 is at the upper limit position in the axial direction of the spindle motor output shaft 133 by the first compression coil spring 116. The centering member 117 is at the upper limit position in the axial direction of the spindle motor output shaft 133 by the second compression coil spring 118. Since the first lock pins 119a and 119b disposed across the centering member 117 and the second turntable 115 are in a free state, the second lock pins 121a and 121b disposed on the second turntable 115 are free. Is in the unlocked position by the spring force of the third compression coil springs 123a and 123b. Here, it is needless to say that the first lock pins 119a and 119b, the second lock pins 121a and 121b, and the third compression coil springs 123a and 123b may be arbitrarily arranged as necessary. .
[0054]
  Next, FIG. 10 shows a second optical disk cartridge (3.5 inch type optical disk cartridge) 104 housed in a cartridge adapter 105 when the second optical disk (3.5 inch type optical disk) 103 is clamped. It is the simplified sectional view showing the state of a disc clamp device. Second optical disk cartridge104Is loaded to a predetermined position, the spindle motor 112 moves to the predetermined position in the direction of the clamp member 113 by a moving mechanism (not shown). Instead of moving the spindle motor 112 in the direction of the clamp member 113 to a predetermined position, the cartridge adapter105However, it is needless to say that the moving mechanism (not shown) may move in the direction of the spindle motor 112 to a predetermined position. The permanent magnet 130 fixed to the spindle motor output shaft 133 and the center hub108a, 108bThe second optical disk 103 is rotatably clamped on the second turntable 125 by the magnetic chucking force generated by. The clamping operation at this time will be described with reference to FIGS.
[0055]
  The centering member 117 supported by the second compression coil spring 118 so as to be movable in the axial direction of the spindle motor output shaft 133 is pressed by the second optical disk 103 to a predetermined position. At this time, the first lock pins 119 a and 119 b are pressed by the second optical disk 103 in the axial direction of the switch motor output shaft 133. As a result, the first lock pins 119a and 119b press the second lock pins 121a and 121b in a direction perpendicular to the spindle motor output shaft 133, and the lock pin holes 132a and 132b provided in the spindle motor output shaft 133, respectively. Mating. At this time, the second lock pins 121a and 121b and the lock pin holes 132a and 132b can be easily fitted by rotating the spindle motor output shaft 133 at a low speed. Therefore, the second turntable 115 is securely locked so as not to move in all directions as well as the axial direction and the rotational direction of the spindle motor output shaft 133. Then, a central hole provided in the second optical disc 103109a, 109bAnd the center pin 127 are fitted, and the second optical disc 103 is rotatably clamped.
[0056]
As described above, in the disk clamp device according to the present embodiment, when the first optical disk 101 is used, the second turntable 115 is held by the first compression coil spring 116 so as to be movable in the axial direction of the spindle motor output shaft 133. Is moved in the axial direction of the spindle motor output shaft 133 to the same position as the carrying surface of the first turntable 125 by the first optical disk 101 and moved in the axial direction of the spindle motor output shaft 133 by the second compression coil spring 118. The centering member 117 held so as to perform centering of the first optical disk 101 carries the first optical disk 101 by the first turntable 125.
[0057]
  On the other hand, when the second optical disk 103 is used, the lock member119a, 119b, 121a, 121bIs pressed in the axial direction of the spindle motor output shaft 133 by the second optical disk 103, the second turntable 115 is locked to the spindle motor output shaft 133, and the second optical disk 103 is locked by the second turntable 115. Is carried.
[0058]
Therefore, there is no problem when the spindle motor is rotated in either the forward or reverse direction, and the same mechanism, for example, a current CD-ROM, a next-generation SD-ROM, and a disk diameter of 120 mm called SD-RAM are used. An optical disk and a next-generation small-sized optical disk called a 3.5-inch type can be selectively chucked and mounted on the optical disk drive.
[0059]
(Second Embodiment)
A second embodiment will be described with reference to FIGS.
The disk clamp device according to the present embodiment includes a first optical disk 201 accommodated in a first disk cartridge 202 having a spindle hole with a predetermined diameter, and a spindle hole having a smaller diameter than the spindle hole of the first disk cartridge 202. This is a disk clamping device for rotationally driving the second optical disk 203 accommodated in the second disk cartridge 205 having the same spindle motor 212.
[0060]
The disc clamping device includes first and second circumferentially extending upper and lower positions spaced apart by a predetermined distance in the axial direction of the peripheral surface of the output shaft of the spindle motor 212 (hereinafter referred to as the spindle motor output shaft) 215. The second notch grooves 223a and 223b are formed, and the first turntable 216 which is disposed so as to be movable in the axial direction and carries the first optical disc 201, and the inner peripheral side of the first turntable 216 The second turntable 217, which is fixed to the spindle motor output shaft 215 and coaxially with the first turntable 216 and carries the second optical disk 203, and the first and second optical disks 201, 203 The first and second centering members 218 and 227 for performing centering, and the first turntable 216, respectively. At least one solid ball 222 having a diameter smaller than the diameter of the spindle motor output shaft 215 and at least one for pressing the solid ball 222 against one of the first and second cutout grooves 223a and 223b. A locking member that includes two preload spring members 220 and 221 and prevents rotation and axial movement of the first turntable 216 relative to the output shaft 215, and the solid ball 222 is the first when the first optical disc 210 is used. The moving mechanism that moves the first turntable 216 in the axial direction so that the solid ball 222 is pressed against the second notch groove 223b when the second optical disc 203 is used, pressed against the notch groove 223a. (Not shown).
[0061]
FIG. 13 is a simplified optical disk drive device including a first optical disk cartridge (optical disk cartridge having a disk diameter of 120 mm) 202 and a disk clamping device showing a state in which the first optical disk (optical disk having a disk diameter of 120 mm) 201 is clamped. It is sectional drawing. FIG. 14 is a cross-sectional view of the disk clamp device.
[0062]
In FIG. 13, a first optical disk 201 is rotatably accommodated in the first optical disk cartridge 2. The first optical disc 201 is an optical disc having a disc diameter of 120 mm, which may be either a bonded / double-sided type or a single-sided single-sided type. A central hole 206 for center positioning is provided at the center of the optical disk cartridge 202. Spindle holes 207a and 207b are provided on both surfaces of the central portion of the optical disk cartridge 202, and information recording / reproducing laser beams are applied to the first optical disk 201 from a recording / reproducing optical system (not shown) to record information. / An access window for performing reproduction and a shutter slidable in the radial direction (both not shown) are provided. When the optical disk cartridge 202 is not used, this shutter closes the spindle holes 207a and 207b and the access window (not shown) by a shutter spring (not shown), and releases them only when the optical disk cartridge 202 is used.
[0063]
FIG. 15 is a simplified diagram of an optical disc drive apparatus including a disc clamp device showing a state in which a second optical disc (3.5-inch type optical disc) 203 and a second optical disc cartridge (3.5-inch type optical disc) 204 are clamped. FIG. FIG. 16 is a cross-sectional view of the disk clamp device.
[0064]
In FIG. 15, the second optical disk 203 is rotatably accommodated in the second optical disk cartridge 204. The second optical disk cartridge 203 is, for example, a bonded / double-sided 3.5 inch optical disk. Center hubs 208a and 208b made of a thin metal plate are provided at the center of the second optical disc 203, and center holes 209a and 209b for center positioning are formed in these center hubs 208a and 208b. . Spindle holes 210a and 210b are provided on both surfaces of the central portion of the second optical disk cartridge 204. The optical disc cartridge 204 is accessed for recording / reproducing information not shown by irradiating the second optical disc 203 with an information recording / reproducing laser beam from a recording / reproducing optical system not shown. A window (not shown) that is slidable in the radial direction is provided. When the second optical disk cartridge 204 is not used, this shutter closes a shutter spring (not shown), spindle holes 210a and 210b, and an access window (not shown), and releases them only when the second optical disk cartridge 204 is used.
[0065]
Next, the clamp mechanisms corresponding to the first and second optical disks 201 and 203 will be described in detail.
First, a clamp mechanism corresponding to the first optical disc 201 will be described with reference to FIGS.
In FIG. 13, after the first optical disk cartridge 202 is loaded to a predetermined position, the clamp member 213 and the position regulating member 214 are moved to a predetermined position in the direction of the spindle motor 212 by a moving mechanism (not shown). Here, the first optical disc (optical disc having a disc diameter of 120 mm) 201 is placed on the first turntable 216. At this time, the preload spring members 220 and 221 in which the fixing ball 222 is in the first turntable 216 in the first notch groove 223a formed on the entire circumference of the spindle motor output shaft 215. The first turntable 216 is fixed by being pressed from the outer peripheral side to the inner peripheral side.
[0066]
The notched grooves 223a and 223b may be formed over the entire circumference of the spindle motor output shaft 215, but may be divided into the same number as the fixing balls 222. As a method for this division, a method may be adopted in which the groove is notched all around and then divided by pins or the like.
[0067]
Thus, the first optical disk 201 is placed on the first turntable 216, and the first optical disk 201 is moved by the separation force between the magnet 219 in the first turntable 216 and the magnet 226 in the clamp member 213. 1 turntable 216 is fixed. Further, the center of the first optical disc 201 coincides with the axis of the spindle motor output shaft 215 by the centering member 218 supported by the spring member 225 at this time.
[0068]
In this way, the first optical disc 201 is clamped rotatably.
[0069]
Next, a clamp mechanism corresponding to the second optical disk (3.5-inch type optical disk) 203 will be described with reference to FIGS.
In FIG. 15, after the second optical disk cartridge 204 is loaded to a predetermined position, the clamp member 213 moves to a position where it does not interfere with the optical disk cartridge 204 in a direction opposite to the spindle motor 212 by a moving mechanism (not shown).
[0070]
When the second optical disk cartridge 204 is inserted, the fixing balls 222 in the first turntable 216 move in the direction of the second notch groove 223b on the peripheral surface of the spindle motor output shaft 215, and the first The second optical disk cartridge 204 and the first turntable 216 are fixed at a position where they do not interfere with each other by the spring member 225 in the turntable 216. Then, the second optical disk 203 is placed on the second turntable 217 fixed to the spindle motor output shaft 215, and a thin plate-like iron piece 208a or 208b (in the case of the back surface) on the second optical disk 203. Fixed by a magnet 228. At this time, the center positioning portion 227 on the spindle motor output shaft 215 and the axis of the second optical disc 203 coincide. In this way, the second optical disk 202 is clamped rotatably.
[0071]
As described above, in the disk clamp device of the present embodiment, when the first optical disk 201 is used, the solid balls 222 on the first turntable 216 are preloaded in the first notch groove 223a on the upper side of the spindle motor output shaft 215. The first turntable 216 is fixed by being pressed by the spring member 220. As a result, the first turntable 216 holds the first optical disc 201.
[0072]
When using the second optical disk 203 smaller than the outer diameter of the first optical disk 201, the first turntable 216 is inserted into the second notch groove 223b below the spindle motor output shaft 215. Similarly, the solid balls 222 on one turntable 216 are fixed by being pressed by the preload spring members 220 and 221. As a result, a clearance is formed between the second disk cartridge 204 and the first turntable 216, and the second optical disk 203 can be fixed by the second turntable 217.
[0073]
Even if different optical disks are mounted in this manner, the first or second optical disks 201 and 203 are fixed to the desired turntables 216 and 217 without changing the center position of the optical disk. There is no problem when the motor 212 is rotated in either the forward or reverse direction, and the same mechanism, for example, a current CD-ROM, a next-generation SD-ROM, and a disk diameter of 120 mm called SD-RAM are used. This optical disc medium and the next-generation compact optical disc medium called 3.5-inch type can be selectively chucked and mounted on the optical disc drive.
[0074]
(Third embodiment)
A third embodiment will be described with reference to FIGS.
The disc clamp device of this embodiment shows a specific example of the moving mechanism in the second embodiment. This moving mechanism identifies which of the first and second disk cartridges 202 and 204 is a disk cartridge mounted on the disk clamping device, and based on the identification result, the first turntable 216 is connected to the spindle motor output shaft 215. It is comprised so that it may move in either direction of the axial direction.
[0075]
First, a clamp mechanism corresponding to the first optical disc 201 will be described.
[0076]
FIG. 17 is a simplified optical disk drive device including a disk clamp device showing a state in which a first optical disk (optical disk having a disk diameter of 120 mm) 201 and a first optical disk cartridge (optical disk cartridge having a disk diameter of 120 mm) 202 are clamped. It is sectional drawing. FIG. 18 is a cross-sectional view of the disk clamp device.
[0077]
After the first optical disk cartridge 202 is loaded to a predetermined position, the clamp member 213 and the position regulating member 214 are moved to a predetermined position in the direction of the spindle motor 212 by a moving mechanism (not shown). When the first optical disk cartridge 202 is loaded, the type of the disk cartridge is identified by identifying the shape of the disk cartridge by the optical sensors 231a and 231b, and the identification result is the case of the first optical disk cartridge 202. First, the direct acting solenoid 233 moves in the upward direction (arrow direction in the figure) in the drawing, and the rod 235 around the rotation center 234 rotates in the clockwise direction (arrow direction in the figure). When the rod 235 moves clockwise, the claw portion 236 provided on the entire circumference of the first turntable 216 is hooked, and the first turntable 216 is moved to the clamp member 213 side. After this movement, the first turntable 216 has a first notch groove 223a on the spindle motor output shaft 215 by the solid ball 222 in the turntable 216 being pressed against the preload spring members 220 and 221. It is fixed with. In this way, the first optical disc 201 is fixed by the first turntable 216 and the clamp member 213 and clamped so as to be rotationally driven by the spindle motor 212.
Next, a clamp mechanism corresponding to the second optical disc 203 will be described.
[0078]
FIG. 19 is a simplified diagram of an optical disk drive device including a disk clamp device showing a state where a second optical disk (3.5-inch type optical disk) 203 and a second optical disk cartridge (3.5-inch type optical disk) 204 are clamped. FIG. FIG. 20 is a sectional view of the disk clamp device.
[0079]
After the second optical disk cartridge 204 is loaded to a predetermined position, the clamp member 213 moves to a position where it does not interfere with the optical disk cartridge 204 by a moving mechanism (not shown) in the direction opposite to the spindle motor 212.
[0080]
At the same time as the second optical disk cartridge 204 is loaded, since there is no shielding between the optical sensors 231a and 231b, it is identified that the second optical disk cartridge 204 is inserted. Based on this identification result, the direct acting solenoid 233 moves in the vertical direction (arrow direction in the figure) in the figure, and the rod 235 around the rotation center 234 rotates in the counterclockwise direction (arrow direction in the figure). To do. By moving the rod 235 counterclockwise, the claw portion 236 provided on the entire circumference of the first turntable 216 is hooked, and the first turntable 216 is moved to the spindle motor 212 side. After this movement, the first turntable 216 is fixed by the second notch groove 223b on the spindle shaft 215 by pressing the solid ball 222 inside the first turntable 216 against the preload spring members 220 and 221. . As a result, the second optical disk 203 is placed on the second turntable 217 without the second optical disk cartridge 204 interfering with the first turntable 216. Then, due to the magnetic attractive force between the iron pieces 208 a and 208 b on the second optical disc 203 and the magnet 228 on the second turntable 217, the center shaft 227 of the spindle motor output shaft 215 and the center of the second optical disc 203 are further increased. By fitting the holes, the second optical disc 203 is fixed to the second turntable 217 and clamped so as to be rotationally driven by the spindle motor 212.
[0081]
In this embodiment, the case where an optical sensor is used for disc cartridge identification has been described. However, it is apparent that a mechanical sensor such as a mechanical switch may be used.
[0082]
As described above, in the disc clamp device of this embodiment, the disc cartridge 202 or 204 is mounted on the disc clamp device, and at the same time, the disc cartridge shape difference is discriminated by an optical or mechanical switch, and this discrimination result is used. Thus, for example, by turning on or off the direct acting solenoid, the side surface of the first turntable 216 is moved in either the vertical direction, and either one of the first and second cutout grooves 223a and 223b is moved. The solid table ball 222 in the first turntable 216 is pressed by the spring force of the preload spring members 220 and 221 to fix the turntable 216 at an accurate position, and the first or second optical disk 201 or 203. Is held by the first to second turntables 216 and 217 It can be.
[0083]
(Fourth embodiment)
A fourth embodiment will be described with reference to FIGS.
The disk clamp device of this embodiment shows another specific example of the moving mechanism in the second embodiment. The moving mechanism is disposed between the first centering member 218 and the first turntable 216, and preloads the first centering member 218 to the upper side in the axial direction of the spindle motor output shaft 215. 225 and a second spring member 241 that is disposed in the gap between the first turntable 216 and the spindle motor 212 and preloads the first turntable 216 to the lower side in the axial direction of the spindle motor output shaft 215. .
[0084]
When the first optical disc 201 is used, the first centering member 218 is pushed up by the first spring member 225, and the first turntable 216 is pushed up by the second spring member 241. The ball 222 is pressed against the first notch groove 223a, and when the second optical disc 203 is used, the first turntable 216 and the first centering are respectively made by the outer shape portion of the second disc cartridge 202 and the disc-shaped hub portion. When the member 218 is pushed down against the first and second spring members 225 and 241, the solid ball 222 is pressed against the second notch groove 223 b.
[0085]
First, a clamp mechanism corresponding to the second optical disc 203 will be described.
[0086]
FIG. 21 is a simplified optical disk drive device including a disk clamp device showing a state in which a first optical disk (optical disk with a disk diameter of 120 mm) 201 and a first optical disk cartridge (optical disk cartridge with a disk diameter of 120 mm) 202 are clamped. It is sectional drawing. FIG. 22 is a sectional view of the disk clamp device.
[0087]
After the second optical disc cartridge 204 is loaded to a predetermined position, the clamp member 213 moves to a position where it does not interfere with the optical disc cartridge 204 by a moving mechanism (not shown) in the direction opposite to the spindle motor 212. When the second optical disc 203 is loaded in this way, the first centering member 218 is brought into contact with the metal piece 208a (208b in the case of the back side) on the second optical disc 203. As loading progresses, the centering member 218 is moved in the direction of the spindle motor 212. When the centering member 218 moves to the spindle motor 212 side, the rod 242 in the centering member 218 starts to press the first turntable 216 downward, and the first turntable 216 moves to the first of the spindle motor output shaft 215. The lock fixed to the notch groove 223a is removed.
[0088]
The unlocked first turntable 216 is further pressed toward the spindle motor 212 by the centering member rod 242 and fixed to the second notch groove 223b of the spindle motor output shaft 215. At this time, there is a second spring member 241 between the turntable of the spindle motor 212 and the first turntable 216, and a force that always pushes up the first turntable 216 acts. However, the first spring member 225 in the centering member 218 is caused by the magnetic attraction force by the metal pieces 208a and 208b on the second optical disc 203 and the magnet on the spindle motor output shaft 215 for fixing the second optical disc 203. Is always applied to the spindle motor 212 side. For this reason, the solid balls 222 in the first turntable 216 are stably locked in the second notch groove 223b of the spindle motor output shaft 215. In this way, the second optical disk 203 is clamped by the second turntable without interfering with the first turntable 216, and can rotate freely.
[0089]
Next, an operation when the second optical disc 203 is unloaded will be described. When the second optical disk 203 is unloaded, the force of the spring member 225 in the first centering member 218 that has been acting on the spindle motor 212 until then is released, and the spindle motor 212 and the first turntable 216 are released. The compression force by the second spring member 241 in the gap between the first turntable 216 and the first turntable 216 is moved to the clamp member 213 side. Then, the solid ball 222 in the first turntable 216 moves from the position of the second notch groove 223b on the spindle motor output shaft 215 to the position of the first notch groove 223a, and is newly cut. The first turntable 216 is fixed at the position of the notch groove 223a.
[0090]
In this way, the first turntable 216 can move toward the spindle motor 212 only when the second optical disk 203 is loaded.
[0091]
Next, a clamp mechanism corresponding to the first optical disk 202 will be briefly described.
FIG. 23 is a simplified diagram of an optical disc drive apparatus including a disc clamp device showing a state in which a second optical disc (3.5-inch type optical disc) 203 and a second optical disc cartridge (3.5-inch type optical disc) 204 are clamped. FIG. FIG. 24 is a sectional view of the disk clamp device.
[0092]
After the first optical disk cartridge 202 is loaded to a predetermined position, the clamp member 213 and the position regulating member 214 are moved to the predetermined position in the direction of the spindle motor 212 by a moving mechanism (not shown).
[0093]
As described above, in the first turntable 216, the solid balls 222 are always locked by the first notch groove 223a on the spindle motor output shaft 215 unless the second optical disk 203 is loaded. For this reason, the first optical disk 201 is clamped on the first turntable 216 by the clamp member 213 so as to be rotationally driven by the spindle motor 212.
[0094]
Further, a centering member 218 provided for aligning the axis of the first optical disc 201 and the axis of the spindle motor output shaft 215 and a preload first spring member for always preloading the centering member 218 upward. 225, and a second spring member 241 for preload provided between the first turntable 216 and the lower part of the spindle motor output shaft 215. When the second optical disc 203 is mounted, the centering member A force that moves 218 downward works, and the solid ball 222 in the first turntable 216 fixed by the first notch groove 223a on the upper surface of the spindle motor output shaft 215 is detached from the groove 223a. Thus, the first turntable 216 starts to move downward. When the second optical disk 203 further approaches the second turntable 216, the solid ball 222 of the first turntable 216 is inserted into the second notch groove 223b on the lower surface of the spindle motor output shaft 215. The solid ball 222 is fixed at an accurate groove position, and a preload is applied to the inner peripheral side by the preload spring members 220 and 221 in the first turntable 216. As a result, the second optical disk 203 is held on the second turntable 217, and at the same time, a clearance is formed between the second disk cartridge 204 and the first turntable 216.
[0095]
When the second optical disc 203 is detached, the centering member 218 for aligning the axis of the first optical disc 203 is released upward, and at the same time, the spring force of the first spring member 225 is released. . At the same time, the force to press downward is lost, and at the same time, the spring force of the second spring member 241 between the first turntable 216 and the spindle motor output shaft 215 acts in the upward direction, so that the bottom of the spindle motor output shaft 215 The first turntable 216 fixed by the second notch groove 223b on the side moves upward and is fixed by the first notch groove 223a on the upper side. That is, in a state where no optical disc is loaded, the first turntable 216 is always fixed on the upper side.
[0096]
In this way, the clamping operation of the disc clamping device described in the second embodiment can be realized.
[0097]
(Fifth embodiment)
The fifth embodiment will be described with reference to FIGS.
The disc clamp device of this embodiment includes a first optical disc 301 accommodated in a first disc cartridge 302 having a spindle hole of a predetermined diameter, and a spindle hole having a smaller diameter than the spindle hole of the first disc cartridge 302. This is a disk clamping device for rotationally driving the second optical disk 303 housed in the second disk cartridge 304 having the same spindle motor 312.
[0098]
The disk clamp device is arranged so as to be movable in the axial direction of an output shaft of a spindle motor 312 (hereinafter referred to as a spindle motor output shaft) 333, and includes a first turntable 315 carrying a first optical disk 301, and the first turntable 315. A second turntable 325 which is located on the inner peripheral side of the first turntable 315 and is coaxially fixed to the spindle motor output shaft 333 and carrying the second optical disk 303, and the first turntable 315; The first optical disk 301 is centered on the inner peripheral side of the second turntable 325 so as to be coaxial with the first and second turntables 315 and 325 and movable in the axial direction of the spindle motor output shaft 333. For supporting the centering member 317 and the second optical disk 303 of the second turntable 325 A first magnetic chucking mechanism (magnetic body) 329 that magnetically chucks the first turntable 315, and a centering member 317. A second magnetic chucking mechanism 319 that magnetically chucks the center hub, and a first urging mechanism (tensile coil spring) that applies an axial tensile force between the first turntable 315 and the spindle motor output shaft 333 316, and a second urging mechanism (compression coil spring) 318 that applies a separation force in the axial direction of the spindle motor output shaft 333 between the second turntable 325 and the centering member 317.
[0099]
The first or second optical disk 301 or 303 is provided with a mechanism for moving the first turntable 315 in the axial direction of the spindle motor output shaft 333 when the first or second optical disk 301 or 303 is released from the disk clamp device. The clamp surface of the first turntable 315 protrudes from the clamp surface of the second turntable 325 when the disc clamp devices 301 and 303 are not mounted.
[0100]
First, drawings used in this embodiment will be described.
[0101]
FIG. 25 is a simplified diagram showing a state of an optical disk drive device including a first optical disk cartridge (optical disk cartridge having a disk diameter of 120 mm) 302 and a disk clamping device before the first optical disk (optical disk having a disk diameter of 120 mm) 301 is clamped. FIG. FIG. 26 is a sectional view of the disk clamp device.
[0102]
FIG. 27 is a simplified diagram showing a state of an optical disk drive device including a first optical disk cartridge (an optical disk cartridge with a disk diameter of 120 mm) 302 and a disk clamp device when the first optical disk (an optical disk with a disk diameter of 120 mm) 301 is clamped. FIG. FIG. 28 is a sectional view of the disk clamp device.
[0103]
FIG. 29 shows an optical disk drive device including a second optical disk cartridge (3.5-inch type optical disk cartridge) 304 and a disk clamping device when the second optical disk (3.5-inch type optical disk) 303 is clamped. It is the simplified sectional view showing a state. FIG. 30 is a cross-sectional view of the disk clamp device.
[0104]
In FIG. 25, the first optical disc 301 is rotatably accommodated in the first optical disc cartridge 302. The first optical disc 301 is an optical disc having a disc diameter of 120 mm, which may be either a bonded / double-sided type or a single-sided single-sided type. A central hole 306 for center positioning is formed in the center of the first optical disc 301. Spindle holes 307a and 307b are provided on both surfaces of the central portion of the optical disk cartridge 302, and an information recording / reproducing laser beam is applied to the first optical disk 301 from a recording / reproducing optical system (not shown) to record / record information. An access window for performing reproduction and a shutter that is slidable in the radial direction (both not shown) are provided. This shutter closes the spindle holes 307a and 307b and an access window (not shown) by a shutter spring (not shown) when the optical disc cartridge 302 is not used, and opens them only when the optical disc cartridge 302 is used.
[0105]
In FIG. 29, the second optical disk 303 is rotatably accommodated in the second optical disk cartridge 304. The second optical disk 303 is, for example, a bonded / double-sided 3.5 inch optical disk. Center hubs 308a and 308b made of a thin metal plate are provided on both surfaces of the center portion of the second optical disk 303, and center holes 309 for center positioning are formed in these center hubs 308a and 308b. Spindle holes 310a and 310b are provided on both surfaces of the center portion of the second optical disk cartridge 304. The second optical disc cartridge 304 has a communication access window and a radius for recording / reproducing information by irradiating the second optical disc 303 with an information recording / reproducing laser beam from a recording / reproducing optical system (not shown). A shutter (none of which is shown) that is slidable in the direction is provided. When the second optical disk cartridge 4 is not in use, the shutter closes the spindle holes 310a and 310b and the access window (not shown) by a shutter spring (not shown), and opens them only when the second optical disk cartridge 304 is used.
[0106]
Next, the clamp mechanisms corresponding to the first and second optical disks 301 and 303 will be described in detail.
First, a clamp mechanism corresponding to the first optical disc 301 will be described with reference to FIGS.
In FIG. 25, until the first optical disk cartridge 302 is loaded to a predetermined position, the spindle motor 312, the clamp member 313, and the position restricting member 314 are in positions that do not physically interfere with the first optical disk cartridge 302. . At this time, the spindle motor 312 is in the state shown in FIG. That is, in FIG. 26, the first turntable 315 is pulled by the tension coil spring 316 that applies the second urging force from the tension plate 321 fixed to the spindle motor output shaft 333, and then the second magnetic chucking mechanism 319. And is at the upper limit position in the output shaft direction. The centering member 317 is pressed from the second turntable 325 by a compression coil spring 318 that applies a first urging force to be pressed against the stopper 320 and is at the upper limit position in the direction of the spindle motor output shaft 333. As a result, the first turntable 315 and the second turntable 325 are in a coupled state, and the clamp surface 315a of the first turntable 315 protrudes from the clamp surface 325a of the second turntable 325. It is in a state.
[0107]
Next, as shown in FIG. 27, after the first optical disk cartridge 302 is loaded to a predetermined position, the clamp member 313 and the position regulating member 314 are moved in the direction of the spindle motor 312 to the predetermined position and the spindle motor 312. Move to a predetermined position in the direction of the clamp member 313 by a moving mechanism (not shown). Here, instead of the spindle motor 312 moving in the direction of the clamp member 313 to a predetermined position, the first optical disc cartridge 302 may be moved in the direction of the spindle motor 312 to a predetermined position by a moving mechanism (not shown). Needless to say.
[0108]
Then, the first optical disk 301 is rotatable and the first turntable 315 and the clamp member by the magnetic chucking force by the permanent magnet 330 fixed to the spindle motor output shaft 333 and the magnetic body 329 fixed to the clamp member 313. Clamped by 313. A center pin 327 is fitted into a center pin hole 331 provided in the clamp member 313, and the first optical disc 301 is rotatably clamped. At this time, the centering member 317 enters the center hole 306 for center positioning at the center of the first optical disc 301, and the optical disc 301 is precisely positioned.
[0109]
Next, a clamp mechanism corresponding to the second optical disk 303 will be described.
[0110]
In FIG. 29, after the second optical disk cartridge 304 is loaded to a predetermined position, the spindle motor 312 moves to the predetermined position in the direction of the clamp member 313 by a moving mechanism (not shown). Here, it goes without saying that instead of the spindle motor 312 moving in the direction of the clamp member 313 to a predetermined position, the cartridge 4 may be moved in the direction of the spindle motor 312 to a predetermined position by a moving mechanism (not shown). Then, the second optical disk 303 is rotatably clamped to the second turntable 325 by the magnetic chucking force by the permanent magnet 330 fixed to the output shaft 333 of the spindle motor 312 and the center hubs 308a and 308b. The clamping operation at this time will be described with reference to FIG.
[0111]
The centering member 317, which is pushed by the compression coil spring 318 that gives the first biasing force from the second turntable 325 and is pressed against the stopper 320, is located at the upper limit position in the output shaft direction, is applied to the second optical disk 303 with a force greater than the biasing force. It is pushed by force and pushed under the center hub 308. Further, when the first turntable 315 is pushed by the second optical disk cartridge 304 and a force greater than the attraction force of the second magnetic chucking mechanism 319 is applied, the first turntable 315 becomes the second turntable 325. And is pulled by the tension coil spring 316 that applies the second urging force until it hits the second stopper 322 in the direction of the tension plate 319. As a result, the first turntable 315 moves below the second optical disk cartridge 304. Then, the center pin 327 is fitted into the center hole 30 provided in the second optical disc 303, and the second optical disc 303 is clamped rotatably.
[0112]
When releasing the second optical disk 303, the first turntable 315 is moved to the second magnetic chucking position by the lever 323 interlocked with the releasing operation, and the first turntable 315 and the second turntable are moved. 325 are combined. With this operation, any of the first optical disc 301 and the second optical disc 303 can be inserted thereafter.
[0113]
As described above, in the disc clamp apparatus of the present embodiment, when the first optical disc 301 is used, the centering member 317 held so as to be movable in the axial direction of the spindle motor output shaft 333 performs the centering of the first optical disc 301. The first optical disk 301 is carried by the clamp surface of the first turntable 315 protruding from the clamp surface of the second turntable 325, and moves in the axial direction of the spindle motor output shaft 33 when the second optical disk 303 is used. The first turntable 315 and the centering member 317 held so as to be moved in the axial direction of the spindle motor output shaft 333 to the position below the carrying surface of the second turntable 325 by the second optical disk 303, On the clamping surface of the turntable 325 and the magnetic chucking mechanism 328 Ri carries a second optical disk 303 in the second turntable 325. As a result, there is no problem when the spindle motor 312 is rotated in either the forward or reverse direction, and the same mechanism, for example, a disc called a current CD-ROM, a next-generation SD-ROM, or an SD-RAM is used. An optical disk having a diameter of 120 mm and a next-generation small-sized optical disk called a 3.5-inch type can be selectively chucked and mounted on the optical disk drive.
[0114]
(Sixth embodiment)
A sixth embodiment will be described with reference to FIGS.
The disc clamp device of this embodiment has a first optical disc 401 housed in a first disc cartridge having a spindle hole of a predetermined diameter, and a spindle hole having a smaller diameter than the spindle hole of the first disc cartridge. This is a disk clamp device for rotationally driving the second optical disk 402 accommodated in the second disk cartridge by the same spindle motor 413.
[0115]
The first optical disc 401 can be rotated around an axis along the circumferential direction of the optical disc 401, 402, and the first disc support surface A that supports the first optical disc 401 at the first rotational position and the second rotational position. A plurality of disk support members 409 each having a second disk support surface B for supporting the second optical disk 402 are disposed around the output shaft 416 so as to rotate together with the spindle motor output shaft 416.
[0116]
First, the drawings used in the present embodiment will be described. FIG. 31 shows an optical disc drive apparatus including a first optical disc 401 and a disc clamping device before the first optical disc (optical disc having a disc diameter of 120 mm) 401 is clamped. It is the simplified sectional view showing a state.
[0117]
FIG. 32 is a simplified cross-sectional view showing the state of the optical disk drive device including the first optical disk 401 and the disk clamp device when the first optical disk (optical disk having a disk diameter of 120 mm) 401 is clamped.
[0118]
FIG. 33 is a simplified cross-sectional view showing the state of the optical disk drive device including the second optical disk 402 and the disk clamping device before the second optical disk (3.5-inch type optical disk) 402 is clamped.
[0119]
FIG. 34 is a simplified cross-sectional view showing the state of the optical disk drive device including the second optical disk 402 and the disk clamping device when the second optical disk (3.5-inch type optical disk) 402 is clamped.
[0120]
31 and 32, the first optical disc 401 is rotatably stored in an optical disc cartridge (not shown). The first optical disc 401 is an optical disc having a disc diameter of 120 mm, which may be either a bonded / double-sided type or a single-sided single-sided type. A central hole 403 for center positioning is formed in the center of the first optical disc 401.
[0121]
In FIGS. 33 and 34, the second optical disk 402 is rotatably housed in an optical disk cartridge (not shown). The second optical disk 402 is, for example, a bonded / double-sided 3.5 inch optical disk. Center hubs 404a and 404b made of a thin metal plate are provided on both surfaces of the central portion of the second optical disk 402, and center holes 405 for center positioning are formed in these center hubs 404a and 404b.
[0122]
Next, the clamp mechanisms corresponding to the first and second optical discs 401 and 402 will be described in detail.
First, a clamp mechanism corresponding to the first optical disc 401 will be described.
[0123]
In FIG. 31, the centering member 406 is pressed against the position restricting member 408 by the compression coil spring 407 and is at the upper limit position in the spindle axial direction. The disk support member 409 is fixed to a turntable 410 indicated by a broken line in the drawing by a fixing pin 411 so as to be freely rotatable in the axial direction of the fixing pin 411 (a direction perpendicular to the paper surface). Note that at least three or more of the disk support members 409 are arranged on the circumference of the disk, and are positioned by means such as a leaf spring (not shown) so that the state shown by the broken line in FIG. The support member presser 412 fixed to the centering member 406 is positioned at a position indicated by a solid line in the drawing.
[0124]
Therefore, after an optical disk cartridge (not shown) is loaded to a predetermined position, the spindle motor 413 moves to a predetermined position in the direction of the clamp member 414 by a moving mechanism (not shown). Thus, as shown in FIG. 32, the first optical disc 401 (the optical disc having a disc diameter of 120 mm) is centered by the center hole 403 and the centering member 406, and the permanent magnet 417 and the clamp member fixed to the output shaft 416 of the spindle motor 413. The first optical disk 401 is rotatably clamped by the first disk support surface A of the disk support member 40 and the clamp member 414 by the magnetic chucking force by the magnetic body 418 fixed to the 414. Needless to say, instead of the spindle motor 413 moving to a predetermined position, the optical disk cartridge may move in the direction of the spindle motor 413 to a predetermined position.
[0125]
Next, a clamp mechanism corresponding to the second optical disk 402 will be described.
[0126]
In FIG. 33, as in FIG. 31, the centering member 406 is pressed against the position restricting member 408 by the compression coil spring 407 and is at the upper limit position in the spindle motor output shaft direction. The disk support member 409 is fixed to a turntable 410 indicated by a broken line in the drawing by a fixing pin 411 so as to be freely rotatable in the axial direction of the fixing pin 411 (a direction perpendicular to the paper surface). Note that at least three or more of the disk support members 409 are arranged on the circumference of the disk, and are positioned by means such as a leaf spring (not shown) so that the state shown by the broken line in FIG. The support member presser 412 fixed to the centering member 406 is positioned at a position indicated by a solid line in the drawing.
[0127]
Therefore, after the optical disk cartridge (not shown) is loaded to a predetermined position, the spindle motor 13 moves to the predetermined position in the direction of the clamp member 414 by a moving mechanism (not shown). Here, it goes without saying that the optical disk cartridge may move in the direction of the spindle motor 413 to a predetermined position instead of the spindle motor 413 to move to a predetermined position. With this movement, as shown in FIG. 34, the centering member 406 is pushed by the center hub 404a of the second optical disc 402 and pushed down in the direction of the output shaft 416 of the spindle motor 413. Accordingly, the support member pressing member 412 fixed to the centering member 406 is also pushed down, and the disk support member 409 is positioned at a position as shown by a solid line in FIG. Then, the center pin 419 is fitted into the center hole 405 provided in the second optical disk 402, and the magnetic chucking force by the permanent magnet 417 and the center hub 404a fixed to the output shaft 416 of the spindle motor 413 is used. The second optical disk 402 is rotatably clamped on the second disk support surface B of the disk support member 409.
[0128]
As described above, in the disc clamp apparatus of the present embodiment, when the first optical disc 401 is used, the first optical disc 401 is carried by the first disc support surface A of the disc support member 409, and the second optical disc 402 is In use, the clamp member 409 rotates to carry the second optical disk 403 by the second disk support surface B, so that, for example, the current CD-ROM and the next-generation SD-ROM are used by the same mechanism. The optical disk with a diameter of 120 mm called SD-RAM and the next generation type small optical disk called 3.5 inch type can be selectively chucked and mounted on the optical disk drive. Become.
[0129]
(Seventh embodiment)
The seventh embodiment will be described with reference to FIGS. 35 to 40.
[0130]
In the present embodiment, a disc cartridge having a chuck member 505 coupled to an output shaft of a spindle motor, and a fixing member 504 that couples the chuck member 505 and the optical disc 501 and is rotatably constrained to a cartridge case is provided. To do.
[0131]
Further, the disk clamp device of this embodiment includes a chuck member 505 coupled to the output shaft of the spindle motor, and a fixing member 504 that couples the chuck member 505 and the optical disk 501 and is rotatably constrained to the cartridge case. The same spindle motor 509 connects the first optical disk 501 housed in the first disk cartridge 502 and the optical disk 511 or 541 having a chuck surface (center hub 514a, 514b) coupled to the output shaft of the spindle motor 509. The spindle motor 509 has a rotor portion 509a configured to be magnetically coupled to a chuck member 505 or a chuck surface (center hubs 514a and 514b). In use Chuck member 505 and the rotor portion 509a is magnetically coupled to the chuck surface when using the second optical disc 511 or 541 (center hub 514a, 514b) and the rotor portion 509a is magnetically coupled.
[0132]
Another disk clamping device of this embodiment includes a first optical disk 531 in which a chuck member 505 coupled to an output shaft of a spindle motor 509 is coupled via a fixing member 504 that couples the chuck member 505 and the optical disk 531. A disk clamping device for rotating and driving a second optical disk 541 having a chuck surface (center hubs 514a, 514b) coupled to an output shaft of the spindle motor by the same spindle motor, and the spindle motor 509 is a chuck. The rotor 509a (output shaft) is configured to be magnetically coupled to the member 505 or the chuck surface (center hubs 514a and 514b). When the first optical disk 531 is used, the chuck member 505 and the rotor 509a are magnetic. Use of the second optical disc 541 Chucking surface (center hub 514a, 514b) in the rotor portion 509a is magnetically coupled.
[0133]
First, the drawings used in this embodiment will be described. FIG. 35 shows the first optical disk cartridge (optical disk cartridge having a disk diameter of 120 mm) 502 before the first optical disk (optical disk having a disk diameter of 120 mm) 501 is clamped. It is the simplified sectional view showing a state.
[0134]
FIG. 36 is a perspective view of the first optical disc (optical disc having a disc diameter of 120 mm) cartridge 502. FIG.
[0135]
FIG. 37 is a cross-sectional view of the first optical disk cartridge 502 with the shutter opened.
[0136]
FIG. 38 shows the state of the second optical disk (3.5-inch type optical disk) 511 and the disk clamp device 509 housed in the cartridge when the second optical disk (3.5-inch type optical disk) 503 is clamped. It is the simplified sectional view showing.
[0137]
FIG. 39 is a simplified cross-sectional view showing a coupled state of the optical disk 531 and the disk clamp device 509 when the third optical disk 531 (an optical disk not having a cartridge with a disk diameter of 120 mm) is clamped.
[0138]
FIG. 40 is a simplified cross-sectional view showing a coupled state of the optical disc 541 and the disc clamp device 509 when the fourth optical disc (optical disc not having a 3.5 inch type cartridge) 541 is clamped.
[0139]
In FIG. 35, the first optical disk 501 is rotatably accommodated in the first optical disk cartridge 502. The first optical disc 501 is an optical disc having a disc diameter of 120 mm, which may be bonded, double-sided, or single-sided single-sided. A center hole 501 a for center positioning is formed in the center of the first optical disc 501. The first optical disk 501 is sandwiched between a chuck member 505 that is a coupling member with a spindle motor, and a fixing member 504 for coupling the chuck member 505 and the optical disk 501. In the state shown in the drawing, the permanent magnet which is a component of the fixing member 504 forms a magnetic path with the chuck member 505, and the optical disk 501 is magnetically coupled to the 504 and 505. For this reason, when the chuck member 505 is coupled to the motor, the optical disc 501, the fixing member 504, and the chuck member 505 can rotate together. Further, the position regulating members 506a and 506b are provided in the cartridge 502 so that the fixing member 504 and the chuck member 505 do not move even when there is no disk.
[0140]
Spindle holes 507a and 507b are provided on both surfaces of the central portion of the optical disk cartridge 502, and an information recording / reproducing laser beam is irradiated to the first optical disk 501 from a recording / reproducing optical system (not shown). An access window for reproduction and a shutter 508 slidable in the radial direction are provided. The shutter 508 closes the spindle holes 507a and 507b and the access windows 503a and 503b by a shutter spring (not shown) when the optical disk cartridge 502 is not used, and opens them only when the optical disk cartridge 502 is used.
[0141]
In FIG. 37, a disk clamping device (spindle motor) 509 is composed of a spindle rotor 509a (spindle motor output shaft) having a coupling surface and a spindle stator 509b that rotatably supports the spindle rotor 509a. The rotor 509a is provided with a permanent magnet (not shown), and the first optical disk 501 centered by the spindle hole can be driven to rotate by magnetic coupling between the chuck member 505 and the rotor 509a. Further, the chuck member 505 may be provided with a permanent magnet, and the rotor 509a may be configured not to have a disk coupling permanent magnet. Further, the chuck member 505 and the rotor 509a may be integrated by screw screws or other mechanical / mechanical connection methods.
[0142]
Next, in FIG. 38, the second optical disk 511 is rotatably accommodated in the second optical disk cartridge 512. The second optical disk 511 is, for example, a bonded or double-sided 3.5 inch optical disk. Center hubs 514a and 514b made of a thin metal plate are provided on both surfaces of the central portion of the second optical disk 511, and center holes 515a and 515b for center positioning are formed in these center hubs 514a and 514b. Yes. Spindle holes 517a and 517b are provided on both surfaces of the central portion of the second optical disk cartridge 504.
[0143]
The second optical disc cartridge 511 is slidable in the radial direction with an access window for recording / reproducing information by irradiating the second optical disc 511 with a laser beam for recording / reproducing information from the recording / reproducing optical system. A simple shutter (both not shown) is provided. This shutter closes the access window by a shutter spring (not shown) when the second optical disk cartridge 512 is not in use, and opens them only when the second optical disk cartridge 504 is used.
[0144]
The disk clamp device (spindle motor) 509 includes a spindle rotor 509a (spindle motor output shaft) having a coupling surface and a spindle stator 509b that rotatably supports the spindle rotor 509a. The rotor 509a is provided with a permanent magnet (not shown), and the optical disk 511 centered by the spindle hole 515b can be rotationally driven by the magnetic coupling between the center hub 514b made of a metal member and the rotor 509a. In addition, the center hub 514b may be provided with a permanent magnet, and the rotor 509a may be configured not to have a disk coupling permanent magnet.
[0145]
As described above, in the disk clamp device of this embodiment, the optical disk is clamped without any problem when rotating either an optical disk having a chuck surface directly coupled to the output shaft of the spindle motor or an optical disk not having the chuck surface. And the output shaft of the spindle motor are coupled.
[0146]
Therefore, with the same mechanism, for example, a current CD-ROM, a next-generation SD-ROM, an optical disk with a diameter of 120 mm called SD-RAM, and a next-generation small-sized optical disk called a 3.5 inch type are used. Alternatively, it can be chucked and mounted on the optical disk drive.
[0147]
【The invention's effect】
As described above, according to the present invention, the spindle motor can be rotated in both forward and reverse directions, and a plurality of types of disc-shaped media having different sizes can be chucked by the same spindle motor and chucking mechanism. An object of the present invention is to provide a disc clamp device that can be driven.
[0148]
Further, according to the present invention, it is possible to provide a disc clamping device in which the central axis of the disc-shaped medium is hardly changed even when two types of disc-shaped recording media having different sizes are attached.
[Brief description of the drawings]
FIG. 1 is a simplified cross-sectional view showing a state of a first optical disc cartridge (an optical disc cartridge having a disc diameter of 120 mm) and a disc clamping device before the first optical disc (an optical disc having a disc diameter of 120 mm) is clamped.
FIG. 2 is a cross-sectional view of a main part corresponding to FIG.
FIG. 3 is a cross-sectional view of a spindle motor unit corresponding to FIG.
FIG. 4 is a simplified cross-sectional view showing a state of a first optical disk cartridge (an optical disk cartridge having a disk diameter of 120 mm) and a disk clamping device when the first optical disk (an optical disk having a disk diameter of 120 mm) is clamped.
FIG. 5 is a cross-sectional view of the main part corresponding to FIG.
6 is a sectional view of a spindle motor unit corresponding to FIG.
FIG. 7 is a simplified diagram showing a state of a second optical disc cartridge (3.5 inch type optical disc cartridge), a cartridge adapter, and a disc clamping device before the second optical disc (3.5 inch type optical disc) is clamped. Sectional view
8 is a cross-sectional view of the main part corresponding to FIG.
9 is a cross-sectional view of a spindle motor unit corresponding to FIG.
FIG. 10 shows the state of the second optical disk cartridge (3.5-inch type optical disk cartridge) housed in the cartridge adapter and the disk clamping device when the second optical disk (3.5-inch type optical disk) is clamped. Simplified cross-sectional view showing
11 is a cross-sectional view of the main part corresponding to FIG. 10;
12 is a sectional view of a spindle motor unit corresponding to FIG.
FIG. 13 is a cross-sectional view showing a state of a first optical disk cartridge (disk diameter 120 mm) and a disk clamp device in a state where a first optical disk (disk diameter 120 mm) according to a second embodiment of the present invention is clamped.
14 is a cross-sectional view of the main part corresponding to FIG.
FIG. 15 shows a second optical disk cartridge (3.5 inch disk) in a state where a second optical disk (3.5 inch disk) according to a second embodiment of the present invention is clamped and a disk clamped state. Cross section
16 is a cross-sectional view of the main part corresponding to FIG. 14;
FIG. 17 is a cross-sectional view showing the state of the first optical disk cartridge (disk diameter 120 mm) and the disk clamp device in a state where the first optical disk (disk diameter 120 mm) according to the third embodiment of the present invention is clamped.
18 is a cross-sectional view of the main part corresponding to FIG.
FIG. 19 shows a second optical disk cartridge (3.5 inch disk) in a state in which a second optical disk (3.5 inch disk) according to a third embodiment of the present invention is clamped and a disk clamped state. Cross section
20 is a cross-sectional view of the main part corresponding to FIG.
FIG. 21 is a sectional view showing a state of a first optical disk cartridge (disk diameter 120 mm) and a disk clamp device in a state where a first optical disk (disk diameter 120 mm) according to a fourth embodiment of the present invention is clamped;
22 is a cross-sectional view of the main part corresponding to FIG. 21.
FIG. 23 shows a second optical disk cartridge (3.5 inch disk) in a state in which a second optical disk (3.5 inch disk) according to a fourth embodiment of the present invention is clamped and a disk clamped state. Cross section
24 is a cross-sectional view of the main part corresponding to FIG.
FIG. 25 is a simplified cross-sectional view showing the state of the first optical disk cartridge (optical disk cartridge with a disk diameter of 120 mm) and the disk clamp device before the first optical disk (optical disk with a disk diameter of 120 mm) is clamped;
26 is a cross-sectional view of the main part corresponding to FIG.
FIG. 27 is a simplified cross-sectional view showing the state of the first optical disk cartridge (optical disk cartridge with a disk diameter of 120 mm) and the disk clamping device when the first optical disk (optical disk with a disk diameter of 120 mm) is clamped.
28 is a cross-sectional view of the main part corresponding to FIG. 27;
FIG. 29 is a simplified cross section showing the state of the second optical disc cartridge (3.5 inch type optical disc cartridge) and the disc clamp device when the second optical disc (3.5 inch type optical disc) is clamped. Figure
30 is a cross-sectional view of the main part corresponding to FIG. 29;
FIG. 31 is a simplified cross-sectional view showing the state of the first optical disc 1 and the disc clamping device before the first optical disc (optical disc having a disc diameter of 120 mm) 1 is clamped.
32 is a simplified cross-sectional view showing the state of the first optical disc 1 and the disc clamping device when the first optical disc (optical disc having a disc diameter of 120 mm) 1 is clamped. FIG.
FIG. 33 is a simplified cross-sectional view showing the state of the second optical disc 2 and the disc clamping device before the second optical disc (3.5-inch type optical disc) 2 is clamped.
FIG. 34 is a simplified cross-sectional view showing a state of the second optical disc 2 and the disc clamping device when the second optical disc (3.5-inch type optical disc) 2 is clamped.
FIG. 35 is a simplified cross-sectional view showing a state of a first optical disc cartridge (an optical disc cartridge having a disc diameter of 120 mm) before the first optical disc (an optical disc having a disc diameter of 120 mm) is clamped;
FIG. 36 is a perspective view of a first optical disk (optical disk having a disk diameter of 120 mm) cartridge.
FIG. 37 is a simplified cross-sectional view showing a state of a first optical disk cartridge (an optical disk cartridge with a disk diameter of 120 mm) and a disk clamping device before the first optical disk (an optical disk with a disk diameter of 120 mm) is clamped.
FIG. 38 is a cross-sectional view of the second optical disk cartridge (3.5-inch type optical disk cartridge) with the shutter opened before the second optical disk (3.5-inch type optical disk) is clamped, and the disk clamp; Simplified diagram showing device status
FIG. 39 is a simplified diagram showing a cross section of the third optical disc and the state of the disc clamp when the third optical disc (an optical disc having a disc diameter of 120 mm without a cartridge) is clamped.
FIG. 40 is a simplified diagram showing a fourth optical disc cross section and a disc clamp state when a fourth optical disc (3.5-inch type optical disc without a cartridge) is clamped.
[Explanation of symbols]
101: First optical disk
102: First optical disk cartridge
103 ... 2nd optical disk
104: Second optical disk cartridge
105 ... cartridge adapter
106 ... Center hole
107a, 107b ... spindle hole
108a, 108b ... Center hub
109a, 109b ... center hole
110a, 110b ... Spindle hole
111a, 111b ... spindle hole
112 ... Spindle motor
113 ... Clamp member
114 ... Position regulating member
115 ... second turntable
116: First compression coil spring
117 ... Centering member
118 ... Second compression coil spring
119a, 119b ... first lock pin
121a, 121b ... second lock pin
123a, 123b ... third compression coil spring
125 ... the first turntable
127 ... Center pin
129 ... Magnetic material
130: Permanent magnet
131 ... Center pin hole
132a, 132b ... Lock pin hole
133 ... Output shaft
201: First optical disk
202... First optical disk cartridge
203 ... second optical disk
204 ... Second optical disk cartridge
206 ... Center hole
207a, 207b ... Spindle hole
208a, 208b ... Center hub
209a, 209b ... center hole
210a, 210b ... spindle holes
212 ... Spindle motor
213 ... Clamp member
214 ... Position regulating member
215 ... Spindle shaft
216 ... First optical disk turntable
217 ... Second optical disk turntable
218 ... First optical disk centering member
219, 226 ... First optical disk clamping magnet
220, 221 ... Spring member for locking
222 ... Lock ball
223a, 223b ... Notch groove for locking
225 ... Spring member for centering
227 ... Second optical disk centering part
228 ... Second optical disk magnet
231a, 231b ... Optical disk cartridge detection sensor
233 ... Linear solenoid
234 ... Center of rotation
235 ... Rod
236 ... nail region
241 ... Spring member
242 ... First optical disc centering rod
301. First optical disk
302: First optical disk cartridge
303 ... second optical disk
304: Second optical disk cartridge
306 ... Center hole
307a, 307b ... Spindle hole
308a, 308b ... Center hub
309 ... Center hole
310a, 310b ... Spindle hole
312 ... Spindle motor
313: Clamp member
314 ... Position regulating member
315 ... First turntable
316 ... tension coil spring
317 ... Centering member
318 ... Compression coil spring
319 ... Second magnetic chucking mechanism
320 ... first stopper
321 ... tension plate
322 ... Second stopper
323 ... Lever
325 ... Second turntable
327 ... Center pin
329 ... Magnetic material (first magnetic chucking mechanism)
330 ... Permanent magnet
331 ... Center pin hole
333: Output shaft
401: first optical disk
402: Second optical disk
403 ... Center hole of the first optical disk
404 ... Center hub
405 ... the center hole of the second optical disk
406 ... Centering member
407 ... Coil spring
408 ... Position regulating member
409 ... Disc support member
410 ... Turntable
411 ... Fixing pin
412: Support member presser
413 ... Spindle motor
414 ... Clamp member
416 ... Output shaft
417 ... Permanent magnet
418 ... Magnetic material
419 ... Center pin
501: First optical disk
502... First optical disc cartridge
503a, 503b ... access window
504 ... Fixing member (disc clamp)
505 ... Chuck member (chuck clamp)
506a, 506b ... Position regulating member
507a, 507b ... spindle hole
508 ... Shutter
509a ... Spindle rotor
509b ... Spindle stator
510a, 510b ... spindle hole
511 ... Second optical disk
512 ... Second optical disk cartridge
514a, 514b ... Center hub
515a, 515b ... center hole
531 ... Third optical disk
541 ... Fourth optical disk

Claims (2)

Having a first and a disc-shaped recording medium, said first diameter than the spindle hole of the disk cartridge of the small second spindle hole which is accommodated in the first disc cartridge having a first spindle hole of predetermined diameter In a disk clamp device for rotationally driving a second disk-shaped recording medium housed in a second disk cartridge with the same spindle motor,
A first turntable fixed to the output shaft of the spindle motor and carrying the first disk-shaped recording medium through the first spindle hole when the first disk-shaped recording medium is used;
The first turntable is arranged on the inner peripheral side so as to be coaxial with the first turntable and movable in the axial direction of the output shaft, and the second disc-shaped recording medium is used when the second disc-shaped recording medium is used . A second turntable carrying the second disc-shaped recording medium via a spindle hole ;
A first compression coil spring that pushes up the second turntable in the upper limit direction of the output shaft and causes the upper portion of the second turntable to protrude from the first turntable by biasing ;
A centering member disposed on the inner peripheral side of the second turntable so as to be coaxial with the first and second turntables and movable in the axial direction, and for centering the first disc-shaped recording medium When,
A second compression coil spring that pushes up the centering member in the upper limit direction of the output shaft and causes the upper portion of the centering member to protrude from the second turntable by biasing ;
In conjunction with the centering member, and when the centering member is pressed against the second compression coil spring by the second disc-shaped recording medium, the second turntable, the output shaft, A locking member that locks the second turntable and the output shaft in a state where the pressing is released,
Intended to press the first disc cartridge is positioned on the top of the output shaft, in use of the first disk cartridge is intended to press the first disc cartridge, said second turntable a clamping mechanism wherein the first disc-shaped recording medium presses the centering member enters the spindle hole, carrying said first disc-shaped recording medium together with the first turntable,
When the second disk cartridge is in use, the second disk cartridge and the spindle motor come close to each other, so that the centering member is pressed against the center disk by the second disk-shaped recording medium. And a magnetic chucking force is generated between the second disk-shaped recording medium and the center hub of the second disk-shaped recording medium when the second disk-shaped recording medium is carried on the second turntable. , A permanent magnet provided around the front end side of the output shaft,
A disc clamping device comprising: The locking member is
A second lock pin provided on the second turntable;
A lock pin hole formed around the output shaft so that the lock pin can be locked and unlocked;
By pressing the second locking pin in conjunction with said centering member by the second disc-shaped recording medium is pressed against the second compression coil spring first to the locking state The disk clamp device according to claim 1, further comprising a lock pin .

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