KR19990014188A - Record carrier and disc cartridge - Google Patents

Abstract

According to the present invention, the signal recording medium can be strongly fixed to a rotating part such as a disk table even at high speed rotation. The floppy disk has a hub at the center thereof, and further includes a disk body having a circular opening serving as a mounting portion of the hub in the disk-shaped main portion and a signal recording surface on the disk-shaped main portion. The hub comprises a contact surface that contacts the disk table that rotates with the floppy disk, and an opposite suction surface that is spaced apart from the suction magnet provided in the rim of the disk table when the contact surface contacts the hub setting surface of the disk table.

Description

Record carrier and disc cartridge

The present invention relates to a recording medium for recording an information signal, and a disc cartridge for storing the recording medium.

Up to now, recording media for recording the information signal on the main surface of the flexible disk base, which is the signal recording surface on which the information signal is recorded, have been used.

Magnetic disks having a diameter of 3.5 inches and using a flexible disk gas have been used. Such a magnetic disk is provided with a center hub for chucking the magnetic disk to a disk drive device. This magnetic disk, which has been widely used so far, has a recording capacity of 2 MB (megabytes).

The magnetic disk 200, which has been widely used so far, is composed of a flexible disk base 201, which is a synthetic resin, as shown in Figs. 1 and 2, and the main surface of the disk base serving as a signal recording surface. It is comprised. A circular central opening 201a is formed at the center of the disk body 201, and a hub 202 is provided to block the central opening 201a.

The hub 202 is made of a magnetic material such as iron, and fits the tubular protrusion 202a to the central opening 201a and also the flange 202b on the outer rim of the protrusion to the rim of the central opening 201a. Is attached onto the disk base 201 so as to be fixed to the disk base 201. In the center of the hub 202, a rectangular spindle passage opening 202b into which the spindle 221 provided on the disk drive side is inserted is formed. In the slightly biased portion at the center, a rectangular chuck pin insertion hole 202c is formed to which the chuck pins 223 provided in the disc drive device are coupled.

The distal end face of the protrusion 202a of the hub 202 in which the spindle passage opening 202b and the chuck pin insertion hole 202c are formed is set against the disk support surface 222a of the disk table 222 provided in the drive unit. Function as 202e. The outer rim of the setting surface 202e acts as a suction by the magnet 224 provided on the outer rim of the disk support surface 222a.

The magnetic disk 200 of the above-described configuration is rotated together with the disk table since the hub 202 is chucked and centered with respect to the disk table of the disk rotating unit 220 provided on the disk drive side. By executing the magnetic disk 200 by the magnetic head, the information signal is recorded and / or reproduced.

The disk rotating unit 220, which is installed at the disk drive unit and the magnetic disk 200 is loaded, is installed at one end of the spindle 221 which is rotated by the spindle motor, not shown. It is configured with. The upper side of the disk table 222 supported at the distal end of the spindle 221 functions as a disk support surface 222a for setting the hub 202 of the magnetic disk 200. The chuck pins 223 are installed at positions that are off the spindle 221 on the disk table 222. The chuck pins 223 are installed to protrude from the disk support surface 222a or to sink into the support surface and to move in a direction toward or away from the spindle 221. The chuck pins 223 are biased in a direction away from the spindle 221 by biasing means (not shown).

On the disk support surface 222a of the disk table 222, a magnet 224 made of, for example, an annular rubber magnet is installed to surround the disk support surface 222a. The magnet 224 is installed on the disk table 222 so that the hub 202 is lower than the disk support surface 222a of the magnetic disk 200 to which the hub 202 is set. As shown in FIG. 4, a predetermined distance H ₀ is maintained between the magnet and the setting surface 202e of the hub 202 on the disk support surface 222a.

As shown in FIG. 4, the spindle 221 is inserted into the spindle passage opening 202b, the chuck pin 223 is coupled to the chuck pin insertion opening 202c, and the setting surface 202e is the disk of the disk table 222. By setting on the support surface 222a, the magnetic disk 200 is chucked to the disk table 222, and the hub 202 is attracted by the magnet.

A state in which the magnetic disk 200 is mounted on the disk table 222 will be described.

In the initial state in which the magnetic disk 200 is set in the disk table 222, the spindle 221 is inserted into the spindle passage opening 202b, the chuck pin 223 is coupled to the chuck pin insertion opening 202c, and these spindles ( The 221 and the chuck pins 223 are inserted into or coupled to the spindle passage opening 202b and the chuck pin insertion hole 202c, usually without touching the inner surfaces of these openings. At this time, the distance F between the centers between the spindle 221 and the chuck pins 223 is a distance in an initial state in which the chuck pins 223 are not moved toward the outer rim of the magnetic disk 200.

The spindle passage opening 202b has a length D on one side and has a rectangular shape with four corners rounded. The spindle 221 inserted into the spindle passage opening 202b has a columnar shape having a diameter? E shorter than one length D of the spindle passage opening 202b. Chuck pin insertion hole 202c is rectangular with long and short lengths, such as A and B, respectively, as shown in FIG. The chuck pin 223 inserted into the chuck pin insertion hole 202c has a columnar shape having a diameter ψC shorter than the length B of the short side of the chuck pin insertion hole 202c.

If the magnetic disk 200 is set in the disk table 222 so that the spindle 221 is inserted into the spindle passage opening 202b and the chuck pin 223 is inserted into the chuck pin insertion opening 202c, When the disk table 222 is rotated in the direction of the arrow R of FIG. 5, the chuck pin 223 is pressed against the outer corner of the chuck pin insertion hole 202c in the direction of rotation of the disk table 222, as shown in FIG. 6. As shown, the magnetic disk 200 is moved toward the outer rim of the spindle 221. The magnetic disk 200 is moved toward the rim by the chuck pin 223 so that the spindle 221 is farthest from the corner of the chuck pin insertion hole 202c into which the chuck pin 223 is inserted, as shown in FIG. 6. Pressing at the corner of the spindle passage opening 202b thus centers the hub 202 of the magnetic disk 200 with respect to the disk table 222.

When the hub 202 of the magnetic disk 200 is centered on the disk table 222, a difference occurs between the rotational speed of the disk table 222 and the rotational speed of the magnetic disk 200. That is, the disk table 222 is rotated before the magnetic disk, so that the chuck pin 223 is pressed against the outer corner of the chuck pin insertion hole 202c disposed in the rotation direction of the disk table 222. When the chuck pins 223 are pressed against the chuck pin insertion holes 202c, the magnetic disk 200 results in a spindle from the center due to the bias of the chuck pins 223 biased in the direction of the outer rim of the disk table 222. Moved toward the outer rim of 221, the spindle 221 is pressed against the corner of the spindle passage opening 202b to center the hub 202 relative to the disk table 222. At this time, the chuck pin 223, as shown in Figure 5, in order to reduce the distance (G) between the center of the spindle 221 and the chuck pin 223 to be shorter than the distance (F) of the initial state, the hub It is moved to face the inner rim of 202.

Magnetic disk 200 is attracted by magnet 224 on disk table 222 for centering. In this state, the magnetic disk 200 is rotated together with the disk table 222. In order to record and / or reproduce the information signal, the signal recording surface of the magnetic disk 200 is scanned by the magnetic head.

The magnetic disk 200 is configured as a disk cartridge housed in the main cartridge body portion. The magnetic disk 200 is loaded into the disk drive in this state and chucked by the disk table 222 for centering on the disk table 222.

Tracking, which is positioning of the magnetic head with respect to each recording track circumferentially formed on the signal recording surface of the magnetic disk 200, is performed by a stepping motor along the radial direction of the magnetic disk 200. By moving it radially. The feed amount of the magnetic head according to the radius corresponding to each step of the stepping motor is the track pitch.

On the other hand, the rotational torque balance between the magnetic disk 200 and the disk table 222 generated when the disk table 222 rotates determines whether the magnetic disk is centered with respect to the disk table 222. Decide

That is, it is a torque recording surface T (h) generated by the contact between the magnetic head and the magnetic disk 200, and the signal recording surface of the magnetic disk 200 provided in the main cartridge main body for accommodating the magnetic disk 200. By the balance between the torque T (h + s) and the rotation torque r, which is the sum of the torque T (s) generated by the contact with the magnetic disk 200 of a protective sheet such as a nonwoven fabric for Is determined. The rotation torque r is used for the magnetic disk 200 by the magnet 224 on the disk table 222 when the magnetic disk 200 is set on the disk table 222 to rotate the disk table 222. The torque generated by the suction force to rotate the disk table 222 and the magnetic disk 200 simultaneously by the contact portion of the disk table 222 and the magnetic disk 200.

That is, when the level ratio of the rotational torque T (h + s) to the torque T (r) is smaller than the optimum value, the magnetic disk is not centered with respect to the disk table 222, and as shown in FIG. Is rotated.

A 3.5-inch diameter magnetic disk, which is widely used now, has a recording capacity of 2.5 MB. In order to process program software and a large amount of data, there is an increasing demand for a magnetic disk having a larger recording capacity.

On the other hand, a magnetic disk of 3.5 inches in diameter, which is widely used as a recording medium for an information processing apparatus such as a computer, is preferably used interchangeably in a disk drive device having a larger capacity magnetic disk as a recording medium.

Moreover, the 3.5-inch diameter magnetic disks used so far are rotated at 300 rpm for recording and / or reproducing information signals, which has a disadvantage of low data transmission speed.

Therefore, it is an object of the present invention to provide a disc type recording medium which can be used interchangeably with a conventional disc type recording medium in a common disc drive device constituting a disc drive device having a high data transfer rate. Another object of the present invention is to provide a disc cartridge for storing such a disc-shaped recording medium.

1 is a cross-sectional view showing a conventional magnetic disk.

FIG. 2 is a bottom view of the magnetic disk shown in FIG. 1.

3 is a perspective view showing a disk rotating portion which is loaded thereon and which is suitable for rotationally driving the magnetic disk.

4 is a side view showing a state in which a conventional magnetic disk is loaded on a disk rotating part.

5 is a plan view showing an initial state in which a conventional magnetic disk is set on a disk table.

6 is a plan view showing that a conventional magnetic disk is loaded centered with respect to a disk table.

Fig. 7 is an exploded perspective view showing a disc drive device loaded with a disc cartridge of the present invention which houses a magnetic disc according to the present invention.

8 is a sectional view showing a magnetic disk according to the present invention.

9 is a plan view showing a magnetic disk according to the present invention.

10 is a schematic diagram showing a recording state of servo information recorded on a magnetic disk according to the present invention.

11 is a plan view showing a disk cartridge for storing a magnetic disk according to the present invention.

Fig. 12 is an exploded perspective view showing a disc cartridge for storing a magnetic disc according to the present invention.

Fig. 13 is a plan view showing the top surface of a disc cartridge according to the present invention.

Fig. 14 is a bottom view showing the bottom of the disc cartridge according to the present invention.

Fig. 15 is a side view showing a state when the magnetic disk according to the present invention is mounted on the disk rotating portion of the disk drive device.

16 is a side view showing a state when the magnetic disk according to the present invention is loaded on the disk rotating portion of the disk drive device.

17 is a plan view showing an initial state in which a magnetic disk according to the present invention is loaded onto a disk rotating section of the disk drive apparatus.

18 is a graph showing the relationship between the distance between the magnet and the hub sucked by the magnet and the attraction force of the hub by the magnet.

Fig. 19 is a side view showing a relationship in which the magnetic disk according to the present invention is loaded on the disk rotating part in a state where the amount of protrusion of the suction surface of the outer rim of the hub from the setting surface on the disk table is 0.25 mm.

* Explanation of symbols on the main parts of the drawings

1. Magnetic disk 2. Hub

3. Disc substrate 10. Disc cartridge

11,12. Upper and lower half 13. Main cartridge body

14. Shutter member 15. Center opening

16,17,18. Annular rib 19,20. Arched rib

23,24. Protective sheet 31. Anti-wrong opening

32,33. Disc discrimination opening 100. Disc rotation part

101. Disk Table 102. Magnet

103. Spindle 150. Disc drive

151. Base 158. Electronic Circuit Board

159. Cartridge holder 160. Uplifting / lowering plate

200. Magnetic disk 201. Disk body

202. Hub 220. Disk Rotator

221. Spindle 222. Disk Table

222a. Disk support surface 223. Chuck pin

224. Magnet

In one aspect, the present invention provides a disk body having a major surface as a recording surface and having a substantially circular central opening, and a hub fixed to the disk body to prevent the central opening of the disk body. Provided is a disk-type recording medium comprising a). The hub comprises an inner rim having a central spindle opening into which the spindle of the drive is fitted. The hub further comprises an outer rim which is formed to protrude in a step shape from the inner rim toward the spindle insertion side.

Tracking servo information is recorded on the recording surface of the disk body. The hub is made of magnetic material.

In another aspect, the present invention provides a main cartridge body portion comprising a pair of halfs in which a spindle opening into which a spindle of a drive device is inserted is formed, and housed rotatably in the main cartridge body portion. Provided is a disc cartridge comprising a disc-shaped recording medium.

The disc-shaped recording medium has a main body serving as a recording surface and is provided with a disc body having a substantially circular center opening and a hub fixed to the disc body to prevent the center opening of the disc body. The hub comprises an inner rim having a center spindle opening into which the spindle of the drive device is fitted, and an outer rim formed to protrude in a step form from the inner rim toward the spindle insertion side.

In the case of a disc-shaped recording medium according to the present invention and a disc cartridge for storing the recording medium therein, a hub provided at the center of the disc body of the disc-shaped recording medium has a central spindle opening into which the spindle of the drive device is fitted. The inner rim portion is provided, and the hub further includes an outer rim portion formed to protrude in a step form from the spindle inner rim toward the insertion side. Therefore, when the disc-shaped recording medium or disc cartridge is loaded on the disc rotating portion of the disc drive, the outer rim of the hub can access the magnets provided in the disc rotating portion, so that the disc-shaped recording medium or disc cartridge is A larger suction force can be used to load the disc rotating part, so that the disc-shaped recording medium or the disc cartridge can be reliably integrated with the disc rotating part.

Moreover, since the disc-shaped recording medium or the disc cartridge can be loaded into the disc drive device in which the conventional magnetic disc is loaded, the disc drive device using the disc-shaped recording medium according to the present invention is configured to use the conventional magnetic disc. You may be.

Hereinafter, a disc-shaped recording medium according to the present invention and a disc cartridge containing the disc-shaped recording medium will be described.

In the following description, the present invention is applied to a magnetic disk with a flexible disk body.

Before describing the magnetic disk according to the present invention, the disk drive device 150 using the magnetic disk according to the present invention will be described.

This disk drive apparatus is configured to record and / or reproduce information signals for both a conventional magnetic disk having a recording capacity of 2 MB and the magnetic disk according to the present invention.

As shown in FIG. 7, the disc drive device 150 includes a base 151 having a substantially flat plate shape, and a disc rotating part positioned at the center of the base 151 to rotatably drive the magnetic disc. It is equipped with 100. This disk rotation part 100 is comprised including the spindle motor 111 and the disk table 101 provided in the one end side of the spindle 103 which functions as a drive shaft of this spindle motor 111. As shown in FIG. The disk rotating part 100 inserts the spindle motor 111 into the opening 152 formed in the center of the base 151 so that the spindle 103 protrudes toward the upper side of the base 151 and inserts the spindle motor 111. It is provided on the base 151 by fixing the stator base 110 which comprises this to the lower surface of the base 151.

The upper side of the disk table 101, which is installed at the end of the spindle 103 to be rotated with the spindle 103, places the disk support surface 101a on the upper surface to set the hub of the magnetic disk thereon. It is comprised. The disk table 101 is formed with a chuck pin 104 at a position away from the spindle 103. The chuck pin 104 is installed to protrude from the disk support surface 101a or to sink into the support surface and to move in a direction toward or away from the spindle 103. The chuck pin 104 is biased in a direction away from the spindle 103 by biasing means (not shown).

On the disk support surface 101a of the disk table 101, a magnet 102 such as an annular rubber magnet is provided to surround the disk support surface 101a. The magnet 102 is provided on the disk table 101 at a level lower than the height of the disk support surface 101a.

The lower surface of the base 151 supports the electronic circuit board 158 on which various electronic circuits and a plurality of detection circuits are provided. A lower cover 162 is provided on the lower surface of the base 151 to cover the lower surface of the electronic circuit board 158.

On the upper side of the base 151 supporting the disk table 101, a cartridge holder 159 for holding a disk cartridge for loading the magnetic disk in the disk cartridge into the disk table 101 is provided. The cartridge holder 159 holds a disc cartridge inserted from the front side of the disc drive device, moves it downward toward the base 151, and loads the disc cartridge held therein on the disc table 101. The cartridge holder 159 has a thin case shape in which the front and bottom surfaces are open, and the size of the cartridge holder 159 can hold the disc cartridge inserted in the front side of the disc drive unit.

On the upper side of the base 151 is disposed between the base 151 and the cartridge holder 159 to lower the cartridge holder 159 toward and away from the disk rotating portion 110 installed in the base 151. An uplifting / lowering plate 160 is installed. The lifting plate 160 is set with vertical cams 160a and 160b having inclined surfaces on opposite side surfaces thereof. On the cam plates 160a and 160b, support pins 159a are set on both sides of the cartridge holder 159. When the elevating plate 160 is moved toward the rear surface of the base 151 in the direction of the arrow X1 of FIG. 7, the cartridge holder 159 is supported by the support pins supported on the upper surfaces of the cam plates 160a and 160b. 159a) is held at an upper position spaced apart from the disk table 101. FIG. At this time, the disc cartridge held by the cartridge holder 159 may be ejected or the disc cartridge may be inserted into the cartridge holder 159. If the elevating plate 160 is moved toward the front of the base 151 in the direction of the arrow X2 shown in FIG. 7, the support pin 159a is moved along the inclined surfaces of the cam plates 160a and 160b, whereby the cartridge holder 159 is lowered to the disk table 101 in the direction of the arrow J in FIG. 7 from the side of the base 151, as a result, the disk cartridge held by the cartridge holder 159 to the base 151. It loads in the position of the cartridge loading part provided, and the magnetic disk accommodated in the disk cartridge is loaded in the disk table 101. FIG.

The lifting plate 160 is biased so as to be moved in the direction of arrow X2 in FIG. 7 by bias means (not shown). On the rear side of the base 151, a lock lever for locking the elevating plate 160 in the position moved to the rear side when the elevating plate 160 is moved toward the rear surface in the direction of arrow X1 of FIG. 169) is installed.

On the front end side of the base 151, a front panel 164 is provided which is provided with a cartridge insertion / detachment opening 165 for inserting, pulling out, and removing a disk cartridge. The front panel 164 is provided with a discharge button opening 167a for causing the discharge button 166 to protrude toward the front side and a display light opening 167b in which the display light 168 is located. When the discharge button 166 is pressed on the front side of the front panel 164, the movement execution plate 161 moves in the direction of the arrow X1 in Fig. 7 to lock the lifting plate 160 with the lock lever 169. In order to move the steel plate 160, it moves in the direction of the arrow X1 of FIG.

On the rear side of the base 151 of the disc drive device 150, a pair of head arms 163 and 163 constituting the magnetic head device are arranged. At the distal end of these head arms, a pair of opposing magnetic heads 191 and 191 is provided. These head arms 163 and 163 are provided with a pair of opposing magnetic heads 191 and 191. These head arms 163, 163 are biased so as to be rotatable by bias means, not shown, in the direction of approaching their distal ends, as shown by arrow I in FIG. These head arms 163 and 163 are moved in the front-rear direction of the base 151 in the direction of the arrow J of FIG. 7 corresponding to the radial direction of the magnetic disk mounted on the disk table 101.

The disc cartridge is inserted into the cartridge holder 159 by being inserted through the cartridge insertion / separation opening 165 formed in the front panel 164. At this time, the shutter provided in the disc cartridge is moved to open the recording and / or reproducing openings formed in each of the upper and lower surfaces of the disc cartridge. Through these openings, the magnetic heads 191 and 191 provided at the distal ends of the head arms 163 and 163 are inserted into the main cartridge main body portion, and the magnetic disk housed in the main cartridge main body portion is the magnetic head ( It is clinched between 191 and 191.

When the disc cartridge is inserted into the cartridge holder 159, the lock lever 169 is pushed by the disc cartridge to unlock the lifting plate 160 from the lock lever 169. The lifting plate 160 unlocked from the lock lever 169 is moved toward the front side of the disc drive device 150 in the direction of arrow X2 of FIG. 7 by the bias of the biasing member. As the lifting plate 160 moves in the direction of the arrow X2 of FIG. 7, the cartridge holder 159 is lowered in the direction of the arrow J of FIG. 7. If the cartridge holder 159 is lowered in the direction of the arrow J in Fig. 7, the disc cartridge accommodated by the cartridge holder 159 is not shown and is installed on the cartridge loading portion provided on the base 151. It is supported by a positioning pin, which is loaded into the cartridge loading section.

On the electronic circuit board 158 arranged on the lower side of the base 151, a disk-in detection switch 178 for detecting the possible presence of the disk cartridge and a disk-in detection switch 178 are installed in the disk cartridge. The write protection detection switch 179 for detecting the state of the write protection determination hole 179 for detecting the state of the discriminating hole is provided. When loading the disc cartridge on the cartridge loading portion, the disc cartridge is pressed by the disc cartridge to detect that the disc cartridge is loaded in the cartridge loading portion. When the disc cartridge is loaded on the cartridge loading portion, the write protection detection hole 179 detects the possibility of the existence of the write protection discrimination opening to determine whether or not the information signal can be recorded on the magnetic disk housed in the disc cartridge. Determine.

As shown in FIG. 7, the electronic circuit board 158 is provided with disk capacity detecting switches 180a and 180b for detecting the disk capacity discriminating opening provided in the disk cartridge. These detection switches 180a and 180b are provided so as to correspond to the disc capacity discrimination opening in the disc cartridge loaded in the cartridge loading section. By detecting the position and the possibility of the disc capacity discrimination opening in the disc cartridge loaded in the cartridge loading portion, the capacity of the magnetic disc accommodated in the disc cartridge can be detected.

When the disc cartridge is loaded in the cartridge loading portion, the magnetic disc contained in the disc cartridge is configured with a hub which is attracted by the magnet 102 installed in the disc table 101, and thus the disc is placed on the disc table 101. Is set. At this time, the spindle 103 is inserted into the spindle passage opening formed in the hub. After the disk table 101 is set to rotate, the chuck pin 104 is inserted into the chuck pin insertion hole 2d.

The following describes a large capacity magnetic disk, which is a disk-type recording medium according to the present invention, which is loaded into the above-described disk drive apparatus, and a disk cartridge containing the magnetic disk.

As shown in FIG. 8, the large-capacity magnetic disk 1 according to the present invention comprises a disk body 3 made of a flexible synthetic resin film as in the conventional magnetic disk. On both main surfaces of the disk body 3, a magnetic medium providing a signal recording surface is attached. The disc body 3 is formed into a circle having a diameter of 3.5 inches. A circular central opening 3a is formed in the central portion of the disk body 3, and a hub 2 is provided to block the opening 3a. The hub 2 is attached to the disc body 3 so that the flange portion 2e provided on the outer rim of the center side is engaged with the rim of the central opening 3a so as to be inserted into the central opening 3a. do.

The hub 2 provided on the disk body 3 is formed on the inner rim 2f having a circular side surface and the outer rim side of the inner rim 2f as shown in Figs. The outer rim part 2g which has a circular side surface, the connection part 2h which connects the inner rim part 2f and the outer rim part 2g mutually, and the flange part 2e formed in the outer rim part of the outer rim part 2g are comprised do. The hub 2 inserts the inner rim portion 2f and the outer rim portion 2g into the central opening 3a formed in the disk body 3, and the flange portion 2e is formed by the rim portion of the central opening 3a. It is supported on the disk base 3 by being supported and fixing the support with an adhesive.

The outer rim 2g of the hub 2 is formed to protrude from the main surface of the disk base 3 by the distance L from the inner rim 2f. The amount of protrusion that the outer rim 2g protrudes from the inner rim 2f is selected, for example, 0.25 mm.

In the central part of the hub 2, when the magnetic disk 1 supporting the hub 2 is loaded on the disk rotation part 100, the spindle passage opening through which the spindle 103 provided in the disk rotation part 100 is inserted is inserted. (2c) is formed. The hub 2 is formed with a chuck pin insertion opening 2d at a position that is combed from a central position and spaced apart from the spindle passage opening 2c by a predetermined distance. A ring-shaped double-sided adhesive sheet which is substantially the same plane as the flange portion 2e is bonded to the surface of the flange portion 2e facing the disk body 3. The hub 2 is adhered to the disk base 3 by a double-sided adhesive sheet.

The outer surface of the inner rim 2f of the hub 2 protruding from the disk body 3 and installed in the disk body is set at the hub support surface 101a provided on the disk table 101 of the disk rotating part 100. It functions as the surface 2a. The outer surface of the outer rim 2g protruding from the inner rim 2f functions as a suction surface 2b facing the magnet 102 provided on the disk table 101.

The inner rim 2f and the outer rim 2g form the main surface of the hub 2.

Techniques for increasing the capacity of the magnetic disk 1 will be described below. In order to increase the capacity of the magnetic disk 1 while having the same size as a conventional magnetic disk, it is necessary to record the information signal with high density. In order to record the information signal with high density, it is necessary to reduce the track pitch of the recording track. The track pitch cannot be reduced by tracking the magnetic head for each recording track based on the step feed of the stepping motor used to transport the magnetic head.

Therefore, in the case of the magnetic disk 1 having an increased capacity by the present invention, as shown in Fig. 10, a tracking servo which is pre-recorded with servo information and is routinely executed in a hard disk drive is an example. For example, as shown in Fig. 10, execution is performed based on previously recorded servo information. As shown in Fig. 10, the magnetic disk 1 of the present invention comprises a servo area SA and a data area DA. The servo area SA includes an area SA1 in which an automatic gain control (AGC) signal, a servo timing mark (STM) signal, and a gray code area are recorded, and a burst pattern for tracking servo BP _A and BP. _B , BP _C and BP _D ) are included, including the area SA2 on which they are recorded.

The AGC signal is used to control the AGC amplifier with respect to the signal reproduced by the magnetic heads 191 and 191 in the disc drive device 150 configured as shown in FIG. The servo timing mark STM is used to detect the timing of the burst pattern.

The gray code area G _A has a track number indicating the track position recorded therein. The gray code area G _A enables reading even in the case of an unstable tracking servo or in the absence of a tracking servo. This allows for quick access to the target track.

Burst patterns BP _A , BP _B , BP _C , BP _D are each recorded with a proprietary frequency. Burst patterns BP _A , BP _B , BP _C , BP _D are each recorded with one width Tp (track pitch) along the central axis of the track. The tracking servo can be executed based on the reproduction results of these burst patterns BP _A , BP _B , BP _C , and BP _D.

When the magnetic disk 1 of the present invention is used, since the tracking servo burst patterns BP _A , BP _B , BP _C , and BP _D are previously recorded on the magnetic disk, the magnetic disk 1 is used as in the case of the conventional magnetic disk. Relative insertion between the chuck pin and the chuck pin insert eliminates the need for centering the spindle. Therefore, the magnetic disk of the present invention does not require the centering of the spindle as is conventionally performed, and therefore it is not necessary to provide the chuck pin insertion hole 2d.

Since the high-capacity magnetic disk 1 of the present invention can be loaded in the above-described disk drive device 150, which may use the above-described conventional magnetic disk 200, it is loaded in the disk drive device 150. In order to enable the chuck pin insertion hole (2d) for the insertion of the chuck pin 104 in order to center the conventional magnetic disk 200 is installed.

The spindle passage opening 2c of the magnetic disk 1 according to the present invention, which is used to insert the spindle 103 of the disk drive 150, is in the form of a rectangle, but with the conventional magnetic disk 200. Likewise, the spindle passage opening 2c may be circular in order to be in contact with the columnar spindle 103. That is, since the spindle 103 does not need to be pressed into the spindle passage opening 2c at a predetermined position, the spindle passage opening 2c may be circular. When the circular spindle passage opening 2c is formed, it is not necessary to consider the positioning of the spindle passage opening 2c as compared with the rectangular chuck pin insertion opening 2d, thus facilitating the manufacture of the hub 2. .

As can be seen from the above description, by inserting the chuck pin 104 into the chuck pin insertion hole 2d, the magnetic disk 1 is biased to face the outer rim so that the spindle passage opening 2c is turned into the spindle ( Even in the case of the conventional magnetic disk in which the centering pushed against 103 is not used, the magnetic head can be tracked for each recording track by performing tracking servo based on the servo information recorded on the magnetic disk 1. .

The magnetic disk 1 according to the present invention is made by using the flexible disk body 3 as in the conventional magnetic disk 200, and is therefore easily damaged. Therefore, similar to the conventional magnetic disk 200, the magnetic disk 1 of the present invention is housed in the main cartridge body 13 formed as the disk cartridge 10, and the magnetic disk 1 is the disk cartridge 10 ) Is loaded into the cartridge loading portion in the disc drive device 150 in a state of being housed in the cartridge. The magnetic disk 1 housed in the disc cartridge is loaded into the disc table 101 of the disc rotating unit 100 with it housed in the disc cartridge 10.

The disc cartridge 10 in which the magnetic disk 1 of the present invention is housed will be described with reference to Figs.

The disc cartridge 10 according to the present invention, as shown in FIG. 12, is formed of a synthetic resin material such as an ABS resin containing an antistatic material and has a substantially rectangular upper half 11 and lower half 12. It includes a main cartridge body portion 13 obtained by adhering each other. In the main cartridge body 13, the magnetic disk 1 is housed so as to be rotatable. The upper half and the lower half 11 and 12 form the main cartridge main body 13 by contacting the weld lugs 24 and 25 with the vertical walls, which are upright, and adhere the contact portions by ultrasonic welding. The main cartridge body 13 is formed.

At the central portion of the lower half 12 constituting the lower side of the main cartridge body 13, a circular central opening 15 is formed, as shown in FIG. An annular rib 16 is formed on the rim of the inner side of the central opening 15. The magnetic disk 1 has a portion corresponding to the flange 2e of the hub 2 supported by the annular rib 16 and is accommodated in the main cartridge body 13. As seen from the side of the central opening 15 at the lower side of the main cartridge body 13, the outer rim 2g of the hub 2 provided in the magnetic disk 1 protrudes more than the inner rim 2f so that the main cartridge It protrudes toward the lower side of the main body 13.

An annular rib 17 engaged with the inner rim of the hub 2 provided on the magnetic disk 1 is located at the center of the inner side of the upper half 11 constituting the upper side of the main cartridge body 13. Is formed. Since the magnetic disk 1 housed in the main cartridge main body 13 has an annular rib 17 engaged with the hub 2, the magnetic disk is in a limited state in movement in a direction parallel to the main surface. It is accommodated in the main cartridge main body 13. On the outer surface of the annular rib 17, an annular rib 18 constituting a protective sheet mounting portion is formed as described below.

On the inner surfaces of the upper half 11 and the lower half 12, four arcuate ribs 19 and 20 are formed to fix the upper half 11 and the lower half 12. As shown in FIG. The magnetic disk 1 is housed in the main cartridge body portion 13 so as to be located in the disk housing portion constituted by the ribs 19 and 20.

Since the distance from the center of the center opening 15 of the lower half 12 to the ribs 19, 20 is slightly larger than the radius of the magnetic disk 1, the hub 2 has a certain tolerance and the center opening 15 If the magnetic disk 1 is slightly moved in a direction parallel to its main surface, there is a risk that the rim of the magnetic disk 1 will come into contact with the ribs 19 and 20.

Rectangular openings 21 and 22 for magnetic heads are formed in the center opposing portions of the upper half 11 and the lower half 12 constituting the main cartridge body 13. The openings 21 and 22 extend from the vicinity of the center to the side of the main cartridge body 13. The magnetic disk 1 housed in the main cartridge body 13 has a recording surface exposed to the outside across the inner and outer rims of the disk.

On the inner side of the main cartridge body portion 13, substantially ring-shaped protective sheets 23, 24 made of, for example, nonwoven fabric are attached. These protective sheets 23 and 24 function to prevent damage caused by the recording surface of the magnetic disk 1 coming into contact with the inner surface of the main cartridge body 13 made of synthetic resin. Radial cuts 24a are formed in portions of the protective sheets 23 and 24 corresponding to the openings 21 and 22 so as not to block the openings 21 and 22.

As shown in Figs. 13 and 14, the main cartridge main body 13 indicates whether or not the information signal recorded on the magnetic disk 1 housed therein can be erased by overwriting or erasing. And a disc discrimination opening 32 that designates the type of magnetic disk housed in the main cartridge body 13, and a miswrite prevention opening 31 that functions as a discriminating hole. On the other hand, when the main cartridge main body 13 is stored in the magnetic disk 1 having a high recording capacity capable of recording an information signal at a high recording density, the disc housed in the main cartridge main body 13 is In order to indicate that the information signal is a magnetic disk having a high recording capacity capable of recording at a high recording density, a disc discrimination opening 33 is also formed at the corner side having the openings 21 and 22 for the magnetic head. These disc discrimination openings 32 and 33 can discriminate magnetic disks having different recording densities.

The disc cartridge 10 of the present invention is provided with a shutter opening and closing shutter member 14 for opening and closing the openings 21 and 22 for the magnetic head. The shutter member 14 is formed of a metal sheet made of aluminum or stainless steel or a synthetic resin, and is formed to have a U-shaped cross section. The shutter member 14 is fitted to one side of the main cartridge body 13 so as to cover the openings 21 and 22 and is mounted to move in the direction of opening and closing the openings 21 and 22. In the shutter portions 14a and 14b of the shutter member 14 covering the openings 21 and 22, the openings 21 and 22 are moved when the shutter portions 14a and 14b are moved to a position in which the openings 21 and 22 are opened. The opening 34 corresponding to this is formed.

As described above, the magnetic disk 1 of the present invention rotatably housed in the disc cartridge 10 is inserted into the disc drive device 150 while the disc is accommodated in the disc cartridge 10. It is loaded in the disk table 101 of the disk rotating part 100 in the accommodated state.

Next, with reference to FIG. 15 and FIG. 16, the state which loaded the magnetic disk in the disk table 101 of the disk rotating part 100 is demonstrated.

16 and 17, the magnetic disk 1 is shown, but the main cartridge body portion 13 is omitted.

The magnetic disk is inserted into the disk drive device in a state of being accommodated in the disk cartridge 10. The disc cartridge 10 inserted into the disc drive is held by the cartridge holder 159. When the disc cartridge 10 is inserted, the cartridge holder 159 is lowered toward the disc rotating portion 1000 and set at a position on the cartridge rod portion installed in the base 151. The disc cartridge 10 is loaded with the cartridge. When loaded to the unit, the magnetic disk 1 accommodated in the disk cartridge 10 is lowered in the direction of the arrow Z of FIG. 15 to face the disk rotating part 100, thereby forming a disk table constituting the disk rotating part 100 ( 101).

The distal end portion of the spindle 103, which is the drive shaft of the spindle motor of the disk rotating portion 100 on which the magnetic disk 1 is loaded, integrally supports the disk table 101. On the surface of the upper surface of the disk table 101, a disk support surface 101a is formed on which the hub 2 of the magnetic disk 1 is to be set. The chuck pin 104 is installed at a position away from the spindle 103 on the disk table 101. The chuck pin 104 is installed to move in the direction of protruding or sinking from the disk support surface 101a and toward or away from the spindle 103. The chuck pins 104 are biased in a direction away from the spindle 103 by bias means, not shown.

On the disk support surface 101a of the disk table 101, a magnet 102 such as an annular rubber magnet or the like is provided to surround the disk support surface 101a. The magnet 102 is provided on the disk table 101 lower than the disk support surface 101a.

Referring to FIG. 16, the magnetic disk 1 includes an installation rim 2f on the inner rim 2f of the hub 2 supported on the hub supporting surface 101a of the disk table 101. The suction surface 2b of the outer rim 2g, which forms a step difference over the outer rim of the head, faces the opposing surface 102a of the magnet 102 with a predetermined distance H therebetween. Do it.

At this time, as shown in FIG. 17, the spindle 103 is inserted into the spindle passage opening 2c of the hub 2 together with the chuck hub 104 fastened to the hub insertion opening 2d.

As shown in FIG. 1, the hub 202 mounted on the conventional magnetic disk 200 has a disk support in which a setting surface 222e on the disk support surface 222a of the disk table 222 faces the magnet 224. The distance between the hub face towards the magnet 224 and the face of the magnet 224 when the hub is set on the disc table 222 so that it contacts the outer rim face of the face 222a is the disc support face 222a and the magnet 224. The distance between the planes is approximately equal to H ₀ .

On the other hand, in the magnetic disk 1 of the present invention, the suction surface 2b of the outer rim 2g of the hub 2 protrudes downward from the hub support surface 101a of the inner rim 2f by a distance L. The suction surface of the hub approaches the distance L by the protruding distance projecting downward toward the opposing surface 102a of the magnet 102, and the suction force by the magnet 102 is reduced to that of the conventional magnetic disk ( Larger than 200, and thus the bearing capacity of the magnetic disk 1 on the disk table 101 also increases.

The magnetic disk 1 mounted on the disk table 101 rotates at a higher speed than the conventional magnetic disk 200. However, since the suction force of the magnet 102 is sufficiently larger than that of the conventional magnetic disk 200, the relative rotation between the magnetic disk and the disk table does not occur due to the high speed rotation. Since the suction force on the disk table 101 is increased by using the hub 2 used in the magnetic disk 1 of the present invention in the conventional magnetic disk 202, the magnetic disk 200 is applied to the disk table 101. More centered.

The magnetic disk 1 of the present invention can have a large capacity of 200 MB. The magnetic disk 1 of the present invention can also have a recording capacity of 2 MB equal to the recording capacity of the conventional magnetic disk 200. If the recording capacity is 200 MB, the optical disc 1 of the present invention rotates at about 3600 rpm for recording and / or reproducing information with respect to the conventional magnetic disc 200. FIG. If the recording capacity is 2 MB, the optical disk rotates at 300 rpm as in the case of recording and / or reproducing information for the conventional magnetic disk 200.

The above-described disk drive device 150 which functions the magnetic disk 1 according to the present invention and the conventional magnetic disk 200 selectively used is based on the above-mentioned servo information previously recorded on the magnetic disk 1. Configured to perform servo tracking. That is, when the magnetic disk 1 of the present invention is mounted on the disk drive device 150, the tracking servo is performed based on the servo information recorded on the magnetic disk 1. When the conventional magnetic disk 200 is mounted on the disk drive device 150, the disk is inserted into the chuck pin insertion opening 202c for recording and / or reproducing the information signal by an operation similar to that performed in the conventional disk drive device. Is centered on the chuck pin 104 inserted into it. That is, the magnetic disk 200 which centers the magnetic disk 200 with respect to the rotational speed of the disk table 101 and the spindle 103 as the disk table 101 rotates in the direction indicated by the arrow R in FIG. 17. Due to the difference in the rotational speed of the chuck pin 104 presses the chuck pin insertion hole (202c) in the hub (202).

The relationship between the suction surface 2b of the outer rim 2g of the hub 2 and the amount of protrusion protruding from the setting surface 2a on the disk table 101 will be described with reference to FIGS. 18 and 19.

In FIG. 18, the horizontal axis represents the distance H between the suction surface 2b of the outer rim 2g of the hub 2 and the opposing surface 102a of the magnet 102 provided on the disk table 101, and the vertical axis represents A suction force P (gf) by the magnet 102 is shown. In Fig. 18, the theoretical and experimental values of the variables are indicated by a straight line and a dotted line, respectively. In Fig. 19, the magnetic disk 1 of the present invention is shown to be installed on the disk table 101 by the magnet 102 protruding from the setting surface 2a at a distance equivalent to the amount of protrusion L. As shown in Figs.

In the results shown in FIG. 18, the distance H _t between the opposing face 102a of the magnet 102 with respect to the hub 2 and the support face 2a of the inner rim 2g of the hub 2 is shown in FIG. It is set to 0.5 mm as shown in 19. 18 shows when the distance H between the opposing face 102a of the magnet 102 to the hub 2 and the suction face 2b of the outer rim 2g of the hub 2 is 0.5 mm, i.e., the disc. When the support surface on the table and the suction surface of the hub are in contact with each other, the magnet 102 is applied when the amount of suction force P of the hub by the magnet 102 obtained is 30, 35, 40, 45, 50, 55, 60 gf. The relation between the suction force P and the distance H between the opposing surface 102a of the magnet 102 and the suction surface 2b of the hub 2 is shown.

Since the distance H from FIG. 18 is inversely proportional to the attraction force P of the magnet (P = k / (1 / H), k is a constant), the opposing surface 102a of the magnet 102 and the hub 2 It can be seen that the suction force P caused by the magnet increases when the distance H between the suction surfaces 2b is decreased.

When the distance H between the opposing surface 102a of the magnet 102 and the suction surface 2b of the hub 2 is 0.5 mm, the suction force P of the hub 2 by the magnet 102 is 40 gf. The theoretical value (calculation result) Dx at the time will be described below. The reason why the theoretical value Dx is used is that when the suction force by the magnet 102 is about 40 gf, since the suction surface of the hub by the magnet and the support surface of the hub on the disk table are in contact with each other in the hub of the conventional magnetic disk, That is, the protrusion amount L which protrudes from the setting surface 2a of the disk table 101 of the outer rim part 2g of the hub 2 of the magnetic disk 1 of this invention is zero.

In the magnetic disk 1 according to the present invention, the suction property of the hub 2 by the magnet 102 should not be smaller than 55 gf because the impact properties are secured to a size of 5 G in the installation timing of the disk table 101. do.

From this, when the distance between the opposing surface 102a of the magnet 102 and the suction surface 2b of the hub 2 is 0.5 mm, the suction force P of the hub 2 by the magnet 102 is 40 gf. With respect to the result Dx, a suction force of 55 gf or more necessary for the magnetic disk 1 of the present invention can be obtained when the distance H is smaller than 0.36 mm. Therefore, if the distance between the opposing surface 102a of the magnet 102 and the suction surface 2b of the hub 2 is set to 0.25 mm, the suction surface 2b of the outer rim 2g of the hub 2 is the disk. The amount of protrusion protruding from the setting surface 2a on the table 101 is 0.5 mm-0.25 mm = 0.25 mm. As can be seen from the experimental result (dotted line) of FIG. 18, the suction force P of the hub 2 due to the magnet 102 having a diameter of 55 gf or more is determined by the suction surface (a) of the opposing surface 102a of the magnet 102 and the hub 2. It is realized when the distance H between 2b) is set to 0.25 mm.

As a result of the suction force P of the hub 2 by the magnet 102 shown in FIG. 18, the suction surface 2b of the outer rim 2g of the hub 2 is set on the disc table 101 2a. The amount of protrusion protruding from) is preferably set to 0.25 ± 0.1 mm, more preferably 0.25 ± 0.025 mm in consideration of the mechanical tolerance of the hub 2. In this case, the distance H from the opposing surface 102a of the magnet 102 to the hub 2 to the support surface 101a of the disk table 101 is preferably 0.5 ± 0.1 mm in view of the mechanical tolerance. Is set to. The attraction force of the hub 202 by the magnet 200 mounted on the conventional magnetic disk 102 is 40 ± 10 gf in consideration of the mechanical tolerance. The value is preferably an amount of protrusion (2) of the suction surface 2b of the outer rim 2g of the hub 2 provided on the magnetic disk 1 of the present invention protruding from the setting surface 2a on the disk table 101 ( Is considered in determining L).

When the suction surface 2b of the outer rim 2g of the hub 2 is set in the above manner, when the protrusion amount L protruding from the setting surface 2a on the disk table 101, the conventional magnetic disk 200 The suction force of the hub 202 by the magnet 102 mounted on the surface ensures 40 gf, while the suction force of the hub 202 by the magnet 102 mounted on the magnetic disk 1 of the present invention on the disk table 101 is secured. Suction force can be secured to 55gf or more.

In the case of a disc-shaped recording medium according to the present invention and a disc cartridge for storing the recording medium therein, a hub provided at the center of the disc body of the disc-shaped recording medium has a central spindle opening into which the spindle of the drive device is fitted. The inner rim portion is provided, and the hub further includes an outer rim portion formed to protrude in a step form from the spindle inner rim toward the insertion side. Therefore, when the disc-shaped recording medium or disc cartridge is loaded on the disc rotating portion of the disc drive, the outer rim of the hub can access the magnets provided in the disc rotating portion, so that the disc-shaped recording medium or disc cartridge is The larger suction force can be used to load the disc rotating part, so that the disc-shaped recording medium or the disc cartridge can be reliably absorbed with the disc rotating part even during the rotation operation.

Claims (12)

In the disc-shaped recording medium, A disk body including a main surface as a recording surface and having a substantially circular central opening; A hub fixed to the disk body to block the central opening of the disk body, The hub comprises an inner rim comprising a central spindle opening that is fitted to the spindle of the drive, and further comprising an outer rim which protrudes through a step from the inner rim toward the insertion surface of the spindle. Record carrier. The method of claim 1, The tracking servo information is recorded on the recording surface of the disk body. The method of claim 1, And the hub is formed of a magnetic material. The method of claim 1, And the hub includes a main surface portion formed by the inner rim portion, and the chuck member insertion hole into which the chuck member of the driving device is inserted is formed on the main surface. The method of claim 1, And said step of said hub is about 0.25 mm. The method of claim 1, And the recording surface is a magnetic signal recording surface. In the disc cartridge, A cartridge body portion comprising a pair of halves in which a spindle opening into which the spindle of the drive device is inserted is formed; A rotatable disc-shaped recording medium housed in the cartridge body portion, The disc-shaped recording medium, A disk body including a main surface portion as a recording surface and having a substantially circular center opening; A hub attached to the disk body to block the central opening of the disk body, The hub comprises an inner rim comprising a central spindle opening fitted to the spindle of the drive, and further comprising an outer rim formed by protruding through a step from the inner rim toward the insertion surface of the spindle. Disc cartridge. The method of claim 7, wherein Tracking servo information is recorded on the recording surface of the disk body. The method of claim 7, wherein And the hub is formed of a magnetic material. The method of claim 7, wherein And the hub includes a main surface portion formed by the inner rim portion, and the chuck member insertion hole into which the chuck member of the driving device is inserted is formed on the main surface. The method of claim 7, wherein And the step of the hub is about 0.25mm. The method of claim 7, wherein And the recording surface is a magnetic signal recording surface.