JPH11120551A - Rotary driving device and inspecting device for flexible storage medium - Google Patents

Abstract

PROBLEM TO BE SOLVED: To stably operate a storage medium rotatively by providing a rotational operation mechanism rotation-operating the storage medium and a disk stabilizing mechanism having a stabilizing plate arranged opposite to one main surface of the storage medium and constituting the stabilizing plate with fragile material. SOLUTION: The stabilizing plate 21 for stably rotating a magnetic disk 6 is arranged on the lower side of the magnetic disk 6 loaded on a disk rotation operational mechanism 3. The stabilizing plate 21 is used with the fragile material with ductility less than metal, etc., particularly black granite. The stabilizing plate 21 consisting of the black granite is formed flatly without occurring projections, etc., when the surface opposite to the magnetic disk 6 is polished, and further, the projection doesn't occur on the magnetic disk side even when a shock is applied to the surface opposite to the magnetic disk 6, and the disk 6 is chipped. Thus, the matter damaging the magnetic disk 6 is prevented.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a flexible recording medium rotation drive for rotating a flexible recording medium and a flexible recording medium inspection apparatus for inspecting the surface condition of the flexible recording medium.

[0002]

2. Description of the Related Art A flexible magnetic disk (hereinafter, simply referred to as a magnetic disk) having a recording capacity as high as several hundred megabytes is a disk rotating mechanism for rotating the magnetic disk when recording and reproducing information signals. , And the recording / reproducing head is levitated by the airflow generated between the recording / reproducing head and the magnetic disk. In this state,
As for the magnetic disk, the recording / reproducing head is moved in the radial direction of the magnetic disk to record / reproduce the information signal.

[0003] Such a magnetic disk has a characteristic of having a low Young's modulus due to its flexibility. For this reason, the magnetic disk may cause surface runout or the like during the rotation operation, and in such a case, the distance between the recording / reproducing head and the magnetic disk changes, and it may be impossible to reliably record and reproduce the information signal. Occurs. Therefore, when used in a computer system or the like, the magnetic disk is rotatably housed in a cartridge and used as a disk cartridge.

In this disk cartridge, the magnetic disk accommodated in the cartridge is rotated in a stable state without causing run-out, so that the magnetic disk is stabilized on the surface facing the main surface of the magnetic disk in the cartridge. A stabilizing plate for rotating in the state is provided. This stabilizing plate is formed by mirror-finishing a metal plate. When the magnetic disk is rotated, a stable airflow is generated between the magnetic disk and the stabilizing plate to lift the magnetic disk and rotate in a stable state. Let it.

In such a magnetic disk, the flying height of the recording / reproducing head during recording / reproducing is extremely small. Therefore, when there are irregularities such as coating unevenness of the magnetic layer of the magnetic disk, the distance between the recording / reproducing head and the magnetic disk changes, and the recording / reproducing head does not float in a stable state, so that accurate recording / reproduction of information signals can be performed. In some cases, it is not possible. Therefore, there is an inspection apparatus that inspects the surface of a magnetic disk by measuring the electromagnetic conversion characteristics of the magnetic disk.

This inspection apparatus has a rotary operation mechanism for rotating a magnetic disk, and a recording / reproducing head for recording an information signal such as an inspection signal on the magnetic disk and reproducing the information signal recorded on the magnetic disk. A reproduction mechanism. Further, the inspection apparatus is provided with a stabilizing plate for stably rotating the magnetic disk on a side opposite to one main surface of the magnetic disk mounted on the rotation operation mechanism. This stabilizing plate is formed by mirror-finishing a metal plate, and is formed to have a very good surface roughness.

In such an inspection apparatus, when the magnetic disk is mounted on the rotary operation mechanism, the magnetic disk is floated by an air flow generated between the stabilizing plate and the magnetic disk, and is stable without running. Is rotated. When the magnetic disk is rotated, the recording / reproducing head is levitated by an air flow generated between the recording / reproducing head and the magnetic disk, and recording / reproducing of an information signal such as a test signal is performed. The electromagnetic conversion characteristics are measured by comparing the input waveform and the output waveform of the signal, and the surface of the magnetic disk is inspected.

[0008]

However, the stabilizing plate provided opposite to the magnetic disk which is rotated by the rotary operating mechanism has a small concave portion on the surface of the stabilizing plate which faces the magnetic disk. When the magnetic disk is rotated, lubricant scattered from the surface of the magnetic disk adheres and is laminated. Therefore, the stabilizing plate may have an increased apparent contact area with the magnetic disk, and the magnetic disk may be attracted. In such a case, the rotation operation of the magnetic disk by the rotation operation mechanism becomes impossible, and if the rotation operation is forcibly performed, the magnetic disk may be damaged.

If the surface of the stabilizing plate facing the magnetic disk is scratched and a recess is formed, a protrusion is formed around the recess by turning over. In such a case, the projection may come into contact with the signal recording surface of the magnetic disk that is rotated to damage the magnetic disk.

In order to solve such a problem, there is an inspection apparatus in which a nonwoven fabric for protecting a disk is stuck on a metal plate to reduce a contact area with a magnetic disk. According to such an inspection device, the lubricant scattered from the rotating magnetic disk to the nonwoven fabric is absorbed by the nonwoven fabric, and the above-described problem of increasing the contact area with the magnetic disk can be avoided. Further, according to such an inspection apparatus, it is possible to prevent the magnetic disk from being damaged by the projection. However, the inspection device that stuck the nonwoven fabric to the stabilizing plate is a fibrous material,
The surface of the non-woven fabric is not uniform, and has a fuzz peculiar to the fiber material. Therefore, the degree of smoothness of the nonwoven fabric with respect to the magnetic disk cannot be quantified. further,
Since the nonwoven fabric has properties such as easy absorption of the lubricant applied to the surface of the magnetic disk and deformation when the magnetic disk comes into contact with the nonwoven fabric, it must be replaced at appropriate intervals. Further, when the nonwoven fabric is replaced, it cannot be made completely the same as the nonwoven fabric before the replacement. Therefore, when the nonwoven fabric is stuck to the stabilizing plate, the reproducibility of the stabilizing plate stuck to the nonwoven fabric is deteriorated.

Accordingly, the present invention provides a rotation device for a flexible recording medium capable of rotating the flexible recording medium in a stable state, and inspecting the surface state of the flexible recording medium by rotating the flexible recording medium in a stable state. It is an object of the present invention to provide a flexible recording medium inspection apparatus that can perform the inspection.

[0012]

SUMMARY OF THE INVENTION In order to solve the above-mentioned problems, a rotary driving device for a flexible recording medium according to the present invention includes a rotary operating mechanism for rotating a flexible recording medium and a flexible recording medium for rotating the flexible recording medium. A disk stabilizing mechanism having a stabilizing plate disposed opposite to one main surface of the medium. The stabilizing plate is made of a brittle material.

According to another aspect of the present invention, there is provided an apparatus for inspecting a flexible recording medium, comprising: a rotating operation mechanism for rotating the flexible recording medium; A recording / reproducing mechanism for performing reproduction and moving in the radial direction of the flexible recording medium; and a disk stabilizing mechanism having a stabilizing plate disposed opposite to one main surface of the flexible recording medium to be rotated. . The stabilizing plate is made of a brittle material.

[0014]

BEST MODE FOR CARRYING OUT THE INVENTION A flexible disk inspection apparatus to which a flexible recording medium rotation drive device according to the present invention is applied is a method for inspecting a surface state of a magnetic disk such as unevenness caused by uneven coating of a magnetic layer of a magnetic disk. The inspection is performed by measuring the electromagnetic conversion characteristics. Hereinafter, this inspection apparatus will be described with reference to the drawings.

As shown in FIG. 1, the inspection apparatus 1 has a disk rotation operation mechanism 3 for rotating a magnetic disk on a base 2 and a recording device for recording and reproducing information signals such as inspection signals on the rotating magnetic disk. A pair of magnetic head devices 4 and 5 constituting a reproducing mechanism are provided.

The magnetic disk 6 used in the inspection apparatus 1 has a diameter of 3.5 inches and a recording capacity of several hundred megabytes. The magnetic disk 6 is formed by forming a magnetic layer serving as a signal recording layer on both sides of a flexible disk substrate, and applying a lubricant to an upper layer of the magnetic layer. In the magnetic disk 6, a center hole is formed in the center, and a signal recording area is formed on the outer peripheral side of the center hole. A clamping plate 7 made of a magnetic material such as a metal plate is attached to such a magnetic disk 6 so as to close a center hole formed in the center. The clamping plate 7 is provided with a substantially square engaging hole 8 at the center thereof, into which the spindle of the disk rotating mechanism 3 is engaged. Although not shown, a substantially rectangular drive pin insertion hole is formed in the clamping plate 7 at a position offset from the engagement hole 8 by a predetermined distance, in which the drive pin of the disk rotation operation mechanism 3 is engaged. .

The disk rotation operating mechanism 3 on which the magnetic disk 6 is mounted includes a drive motor 9 serving as a drive source for rotating the magnetic disk 6, and a drive motor 9.
And a disk table 11 that is rotated and driven to rotate the magnetic disk 6. The disk table 11 and the drive motor 9 are connected to the disk table 11
Are connected by an air spindle 12 in order to eliminate eccentricity during rotation. The disk table 11 is formed in a disk shape, and has a spindle 13 which is engaged with the engagement hole 8 of the clamping plate 7 at the center, and a drive pin which is provided at a position deviated from the spindle 13 by a predetermined distance. A drive pin (not shown) engaged with the insertion hole and a magnet 14 for magnetically attracting the clamping plate 7 are provided on the outer peripheral side of the spindle 13.

When the magnetic disk 6 is placed on the disk table 11, the disk rotation operating mechanism 3 engages the spindle 13 in the engagement hole 8 and the drive pin in the drive pin insertion hole, and performs clamping. The plate 7 is attracted to the disk table 11 by the magnet 14. When the disk table 11 is driven to rotate, the drive pins provided on the disk table 11 urge the magnetic disk 6 in the outer circumferential direction of the magnetic disk 6 and in the direction of rotation of the magnetic disk 6, and the urging force of the drive pins. By pressing the spindle 13 against one side surface of the engaging hole 8, the magnetic disk 6 is positioned and the magnetic disk 6 is rotated integrally with the disk table 11.

As shown in FIG. 1, magnetic head devices 4 and 5 constituting a recording / reproducing mechanism for recording / reproducing an information signal such as an inspection signal on / from the magnetic disk 6 are provided on both sides of the magnetic disk 6. A pair is provided so as to face the designated signal recording area. These magnetic head devices 4 and 5 are a recording magnetic head for recording an information signal such as a predetermined inspection signal in a signal recording area of the magnetic disk 6 and a reproducing for reproducing an information signal recorded in the signal recording area of the magnetic disk 6. Magnetic heads 15, 15 comprising magnetic heads for
And a magnetic head support plate 16 having a resiliently displaceable leaf spring supporting the magnetic head 15 on the distal end side.

The magnetic head devices 4 and 5 have mounting members 17 on which the magnetic head devices 4 and 5 are mounted and supported.
17, the magnetic head units 15, 15 are connected to the magnetic disk 6
The magnetic head operating mechanism 20 moves between a recording / reproducing position close to the signal recording surface and a standby position separated from the signal recording surface of the magnetic disk 6. The magnetic head operating mechanism 20 is provided so that the magnetic head units 15 and 15 do not contact the magnetic disk 6 when, for example, replacing the magnetic disk 6 mounted on the disk rotation operating mechanism 3.
The magnetic head devices 4 and 5 are rotated from a recording / reproducing position close to the magnetic disk 6 to a standby position separated from the magnetic disk 6.

Such a magnetic head operating mechanism 20 is connected to a first position adjusting mechanism 18 for adjusting the height of the magnetic head devices 4 and 5. This first position adjustment mechanism 1
8, for example, a hydraulic mechanism or the like, the magnetic head unit 1 in the range of, for example, ± 3 mm in the arrow A ₁ or A ₂ direction in FIG. 1
The height adjustment of 5, 15 is performed.

Further, in the first position adjustment mechanism 18, the radial direction of the magnetic head 4 and 5 the magnetic disk 6, i.e. in Figures 1 and 2 the arrows B ₁ or B ₂ direction regulating the second performing of the The position adjusting mechanism 19 is connected. Second position adjusting mechanism 1
A drive source 9 is an ultrasonic motor or the like (not shown). The second position adjusting mechanism 19 is provided with the magnetic head unit 1.
5 and 15 are moved between an initial position located outside the magnetic disk 6 mounted on the disk rotation operation mechanism 3 and a recordable / reproducible position located on a signal recording area of the magnetic disk 6.

That is, the second position adjusting mechanism 19 controls the magnetic head 1 when recording / reproducing the magnetic disk 6.
The predetermined information signal is recorded or the information signal recorded on the magnetic disk 6 is read by moving the disks 5 and 15 on the signal recording area of the magnetic disk 6 in the radial direction of the magnetic disk 6. The second position adjusting mechanism 19
When the magnetic disk 6 mounted on the disk rotation operation mechanism 3 is replaced, the magnetic head units 15 and 15 are retracted to the initial position.

A stabilizing plate 21 for rotating the magnetic disk 6 in a stable state is provided below the magnetic disk 6 mounted on the disk rotation operation mechanism 3.
As shown in FIGS. 1 and 2, the stabilizing plate 21 has a rectangular shape as a whole and is formed to be larger than the magnetic disk 6 mounted on the disk rotating operation mechanism 3. For the stabilizing plate 21, a brittle material having less ductility than metal or the like is used. In particular, black granite is used here.

Since such a stabilizing plate 21 made of black granite is made of a brittle material, when the surface facing the magnetic disk 6 is polished, as shown in FIG. The reference plane P can be formed flat without causing undulations and projections. This is because a brittle material has less ductility than a metal plate. Therefore, the stabilizing plate 21 generates a stable airflow between the magnetic disk 6 and the magnetic disk 6 when the magnetic disk 6 is rotated, and is stable without causing the magnetic disk 6 to run out. Can be rotated in the state.

Further, even when the stabilizing plate 21 is chipped due to an impact applied to the surface facing the magnetic disk 6, this surface is polished as in the case where the stabilizing plate is formed of a metal plate. In the initial state immediately after, that is, there is no projection formed on the magnetic disk 6 side from the reference plane P, and only a chip is formed below the reference plane P. Therefore, the stabilizing plate 21
Can prevent the magnetic disk rotated by the rotation operation mechanism 3 from being damaged.

Further, the stabilizing plate 21 made of black granite has porosity. Therefore, stabilizing plate 2
3, when the surface facing the magnetic disk 6 is polished, as shown in FIG. 3, the surface has a certain degree of surface roughness and is constituted by minute concave portions 22 having a depth D of 5 μm to 10 μm. . Therefore, even when the magnetic disk 6 is mounted on the rotary operation mechanism 3, the stabilizing plate 21
The contact area with the magnetic disk 6 can be appropriately secured to such an extent that the magnetic disk 6 does not stick to the stabilizing plate 21,
The magnetic disk 6 is prevented from sticking to the surface.

The stabilizing plate 21 has a magnetic disk 6
When the magnetic disk 6 is rotated by the rotation operation mechanism 3,
The lubricant applied to the surface of the magnetic disk 6 scatters and adheres to the surface facing the magnetic disk 6. By the way, since the black granite used as the stabilizing plate 21 has porosity, it absorbs the lubricant adhering to the surface to some extent. Therefore, such a stabilizing plate 21
As in the case where the stabilizing plate is formed of a metal plate, a lubricant is laminated on minute concave portions on the surface to increase the apparent contact area between the magnetic disk 6 and the stabilizing plate, thereby preventing the magnetic disk 6 from adsorbing. Can be prevented.

As shown in FIG. 2, a center opening 23 for allowing the disk rotation operating mechanism 3 to face the mounting surface of the magnetic disk 6 is provided at the center of the stabilizing plate 21 as shown in FIG.
Is formed. Further, the stabilizing plate 21 is provided with a cutout 24 for allowing the magnetic head devices 4 and 5 to face from one side surface of the magnetic head operating mechanism 20 to the center. The notch 24 is formed in the stabilizing plate 2 when the magnetic disk 6 is rotated.
The magnetic disk 6 is formed with an interval that does not hinder the floating of the magnetic disk 6 due to the airflow between the magnetic disk 1 and the magnetic disk 6. Thus, the notch 24 allows the magnetic head devices 4 and 5 to move over the inner and outer circumferences of the magnetic disk 6. Further, the stabilizing plate 21 has a stabilizing plate 2 on the side opposite to one side of the magnetic head operating mechanism 20.
1 are provided with mounting holes 25.

Such a stabilizing plate 21 is fixedly attached to a position adjusting mechanism 26 of the stabilizing plate 21 disposed opposite to the magnetic head device 4 with the disk rotation operating mechanism 3 therebetween by a set screw or the like. Can be This position adjustment mechanism 26
The stabilizing plate 21 is disposed on the side facing the magnetic head devices 4 and 5, and the stabilizing plate 21 is rotated in the rotation axis direction of the magnetic disk 6, that is, in FIG.
And in Figure 2 is moved in the arrow C ₁ or C ₂ direction. When the magnetic disk 6 mounted on the disk rotation operation mechanism 3 is rotationally driven, the position adjusting mechanism 26 is floated in the most stable state by the air layer between the magnetic disk 6 and the stabilizing plate 21. Next, the gap between the magnetic disk 6 and the stabilizing plate 21 is adjusted.

Such an inspection apparatus 1 includes a magnetic disk 6
Is measured as follows when measuring the electromagnetic conversion characteristics of.
That is, when the inspection apparatus 1 mounts the magnetic disk 6 on the disk rotation operation mechanism 3, the magnetic head units 15, 15 of the magnetic head devices 4, 5 are mounted on the disk rotation operation mechanism 3 by the second position adjustment mechanism 19. Magnetic disk 6
It is in the initial position located outside of. When the magnetic disk 6 is mounted on the disk table 11 in this state, the spindle 13 and the drive pin provided on the disk table 11 are engaged with the engagement hole 8 and the drive shaft insertion hole.

[0032] The magnetic head part 15, 15 of the magnetic head device 4 and 5, the second position adjusting mechanism 19, in FIGS. 1 and 2 are moved in the arrow B ₁ direction, the magnetic disk 6
The signal is moved to a recordable / reproducible position located on the signal recording area, and fine adjustment in the height direction is performed by the first position adjusting mechanism 18. At this time, as shown in FIG. 2, the magnetic head unit 15 of the magnetic head device 5 located on the lower side in FIG. 1 enters through the notch 24 of the stabilizing plate 21, and the two magnetic head units 15, 15 Is brought into contact with the signal recording surface of the magnetic disk 6. The magnetic disk 6 comes into contact with the stabilizing plate 21, and the stabilizing plate 21 has a minute recess 22 formed on the surface facing the magnetic disk 6 from a porous brittle material. This prevents the magnetic disk 6 from being attracted to the stabilizing plate 21.

When the disk table 11 is driven to rotate, the drive pins provided on the disk table 11 urge the magnetic disk 6 in the outer circumferential direction of the magnetic disk 6 and in the direction of rotation of the magnetic disk 6 and drive pins. By pressing the spindle 13 against one side surface of the engagement hole 8 by the urging force, the magnetic disk 6 is positioned and the magnetic disk 6 is rotated integrally with the disk table 11.

When the magnetic disk 6 is rotated at a high speed of, for example, 3600 rpm by the disk rotating mechanism 3, the magnetic heads 15, 15 are levitated by an air flow generated between the magnetic heads 15, 15 and the magnetic disk 6. The information signal is recorded in the signal recording area of the magnetic disk 6 by the recording magnetic head. The flying height H of the magnetic disk 6
Is, for example, about 5 μm as shown in FIG. Then, the magnetic head units 15 reproduce the information signals recorded in the signal recording area of the magnetic disk 6 by the reproducing magnetic head. That is, the inspection apparatus 1 measures the electromagnetic conversion characteristics by comparing the reproducibility of the output waveform with respect to the input waveform of the information signal, and is caused by the surface condition of the magnetic disk 6, for example, coating unevenness of the magnetic layer of the magnetic disk. Inspection for irregularities, pinholes where no magnetic layer is formed, etc.

In some cases, the lubricant applied to the surface of the magnetic disk 6 adheres to the surface of the stabilizing plate 21 facing the magnetic disk 6 from the rotating magnetic disk 6. 21 has porosity,
The lubricant adhering to the surface of the stabilizing plate 21 is absorbed. Therefore, the rotation of the magnetic disk 6 stops and the magnetic disk 6
Prevents the magnetic disk 6 from being attracted to the stabilizing plate 21 even when it comes into contact with the stabilizing plate 21, making it impossible to rotate the magnetic disk 6 and preventing the magnetic disk 6 from being damaged.

Such an inspection apparatus 1 includes a magnetic disk 6
Changes in the environment in which the rotating operation is performed, for example, even when the lubricant applied to the surface of the magnetic disk 6 adheres to the stabilizing plate 21 or when the stabilizing plate 21 is subjected to an impact and chipped, the surface is always run out. The magnetic disk 6 can be rotated in a stable state without causing the like. Therefore, the inspection device 1 can accurately measure the electromagnetic conversion characteristics of the magnetic disk 6.

Although the inspection apparatus 1 using the stabilizing plate 21 made of black granite has been described above, other brittle materials such as granite and ceramic can be used for the stabilizing plate 21.

Further, the inspection apparatus 1 for the flexible magnetic disk 6 having a higher capacity than the standard flexible magnetic disk to which the present invention is applied has been described. However, the present invention is not limited to this. The present invention can be applied to any flexible recording media such as a flexible magnetic disk and a flexible optical disk. For example, when an optical disk having flexibility is used as a recording medium, the recording / reproducing mechanism is constituted by an optical head.

The present invention is not limited to the inspection apparatus 1 described above, but can be applied to a recording / reproducing apparatus provided with a rotary drive for rotating a flexible recording medium.

[0040]

According to the present invention, since the stabilizing plate is made of a brittle material, the stabilizing plate can be formed without undulating or protruding the surface on the side facing the flexible recording medium. In addition, the stabilizing plate may be damaged even if the surface facing the flexible recording medium is shocked and chipped.
As in the case where the stabilizing plate is formed of a metal plate, no projection is formed on the flexible recording medium side from the initial state, which is the reference surface immediately after this surface is polished, and only the lower side of the reference surface is chipped. Therefore, the rotation driving device of the flexible recording medium can prevent the air flow between the flexible recording medium and the stabilizing plate from being disturbed when the flexible recording medium is rotated, and can perform flexible recording in a stable state. The medium can be rotated, and the flexible recording medium can be prevented from being damaged.

According to the inspection apparatus for a flexible recording medium, since the stabilizing plate is made of a brittle material, it can be formed without undulating or protruding the surface on the side facing the flexible recording medium. it can. In addition, even if the stabilizing plate is impacted and chipped on the surface facing the flexible recording medium, the stabilizing plate has a reference surface immediately after being polished, as in the case where the stabilizing plate is formed of a metal plate. No projection is formed on the flexible recording medium side from the initial state, and only the lower side from the reference plane is missing.
Therefore, the rotary drive of the flexible recording medium is
When the flexible recording medium is rotated, the air flow between the flexible recording medium and the stabilizing plate can be prevented from being disturbed, and the flexible recording medium can be rotated in a stable state, and the flexible recording medium can be rotated. Can be prevented from being damaged. Therefore, the flexible recording medium inspection apparatus can accurately measure the electromagnetic conversion characteristics of the flexible recording medium.

Further, according to the present invention, since the surface of the stabilizing plate on the side of the flexible recording medium is not protruded due to a curl such as a scratch or the like, the flying height of the head constituting the recording / reproducing mechanism during recording / reproducing is small. Particularly suitable for a capacity type flexible magnetic disk.

[Brief description of the drawings]

FIG. 1 is a side view of an inspection device for inspecting a surface state of a flexible magnetic disk described in an embodiment.

FIG. 2 is a perspective view of a stabilizer provided in the inspection apparatus.

FIG. 3 is an enlarged sectional view of a main part showing a relationship between a stabilizing plate and a magnetic disk that is rotated.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 Inspection device, 2 bases, 3 disk rotation operation mechanism, 4, 5 magnetic head device, 6 magnetic disk,
Clamping plate, 8 engagement holes, 9 drive motor,
11 disk table, 12 air spindle, 13
Spindle, 14 magnets, 15 magnetic head,
16 head support plate, 17 magnetic head operation mechanism, 18
First position adjusting mechanism, 19 second position adjusting mechanism, 2
0 magnetic head operating mechanism, 21 stabilizing plate, 22 recess, 23 central opening, 24 notch, 25 mounting hole, 26 position adjusting mechanism

 ──────────────────────────────────────────────────続 き Continued on the front page (72) Inventor Taisuke Ito 2-13-6 Shin-Yokohama, Kohoku-ku, Yokohama, Kanagawa Prefecture Inside Kyodo Electronic System Co., Ltd. (72) Inventor Nobuyuki Suzuki 2-13-, Shin-Yokohama, Kohoku-ku, Yokohama, Kanagawa 6 Kyodo Electronic System Co., Ltd.

Claims (5)

[Claims] 1. A rotating operation mechanism for rotating a flexible recording medium, and a disk stabilizing mechanism having a stabilizing plate disposed to face one principal surface of the rotating flexible recording medium. The rotation drive device for a flexible recording medium, wherein the stabilizing plate is made of a brittle material. 2. The apparatus according to claim 1, wherein the stabilizing plate is made of granite. 3. The rotation drive device for a flexible recording medium according to claim 1, wherein the disk stabilizing mechanism is provided with an adjusting mechanism for adjusting an interval between the flexible recording medium and the stabilizing plate. . 4. A rotation operation mechanism for rotating a flexible recording medium, a recording / reproduction mechanism for recording / reproducing an information signal to / from the rotating flexible recording medium and moving in a radial direction of the flexible recording medium, and a rotation operation. A disk stabilizing mechanism having a stabilizing plate disposed opposite to one main surface of the flexible recording medium, wherein the stabilizing plate is made of a brittle material. Inspection equipment. 5. The flexible recording medium according to claim 4, wherein the stabilizing plate is provided with a cutout for moving the recording / reproducing mechanism in a radial direction of the flexible recording medium. Inspection equipment.