JPH04134629A - Transfer method for magnetic disk - Google Patents

Abstract

PURPOSE:To transfer a distance from the rotation center of a master magnetic disk to each magnetic information to a slave magnetic disk by positioning the master magnetic disk and the slave magnetic disk using the same chucking mechanism. CONSTITUTION:After chucking a first master magnetic disk 301 to a chucking mechanism 171 and rotating until an engaging pin 177 turns to a prescribed position, the magnetic disk 301 is arranged and fixed on a magnetic disk holding surface 113 of a first supporting part 111 by an adjustment mechanism 191. A second master magnetic disk 401 is fixed similarly. After that, a slave magnetic disk 501 is also chucked similarly, adjusted at the same position, and fixed to be lowered so that the magnetic disk 301 and the slave magnetic disk 501 are slightly contacted by the adjustment mechanism 191. Next, a supporting part 151 is lowered to the supporting part 111 side so as to make an air packing 121 and projected part 161 completely contact, air is removed from an air hole 157, and the atmospheric pressure in a space 201 is reduced. Thus, after making the completely contacting state of the master magnetic disks 301 and 401 and the slave magnetic disk 501, and by impressing a biased magnetic field, it is possible to transfer the magnetic information of the master magnetic disk to the slave magnetic disk accurately.

Description

DETAILED DESCRIPTION OF THE INVENTION [Object of the Invention] (Industrial Application Field) The present invention relates to a method for transferring magnetic disks, typified by floppy disks.

(Prior Art) Magnetic disks, represented by floppy disks, are widely used in various fields as a convenient means of recording external information. Discs are starting to appear on the market.

Therefore, similar to magnetic tapes, magnetic disks can be supplied to the market at low cost by recording information using transfer technology.
Development is underway.

As a transfer method for such a magnetic disk, there is a bias transfer method in which the magnetic information of the master magnetic disk is transferred to the budding magnetic disk by bringing the magnetic disk into pressure contact and applying a bias magnetic field for transfer. The method is a thermomagnetic transfer method in which the master magnetic disk and the secondary magnetic disk are brought into pressure contact and transferred by heating.

(Problems to be Solved by the Invention) Incidentally, in recent years, the recording density of magnetic disks has been significantly improved, and strict positional accuracy is now required for the above-mentioned magnetic disk transfer.

For example, if the positional accuracy of the master magnetic disk and the slave magnetic disk deviates even slightly during transfer, each track of the slave magnetic disk to be transferred will no longer have the same radius from the center of rotation. For this reason, on a slave magnetic disk to which magnetic information has been transferred, the magnetic head may not be able to accurately follow each track, and alignment with the magnetic disk becomes extremely important.

The object of the present invention is to provide a method for transferring a magnetic disk to a magnetic disk.

[Structure of the Invention] (Means for Solving the Problems) The magnetic disk transfer method of the present invention is a magnetic disk transfer method for transferring magnetic information of a master magnetic disk to a slave magnetic disk, and includes a chucking mechanism. a step of fixing the master magnetic disk after chucking and removing it from the chucking mechanism; a step of causing the chucking mechanism to chuck the slave magnetic disk;
The method includes the steps of aligning the index position of the slave magnetic disk to the index position of the master magnetic disk, bringing the master magnetic disk and the slave magnetic disk into close contact with each other, and transferring the magnetic information of the master magnetic disk to the slave magnetic disk. It is characterized by this.

(Function) As described above, the magnetic disk transfer method of the present invention performs transfer by bringing the master magnetic disk and slave magnetic disk into close contact with each other using the same chucking mechanism. Information recorded at a certain distance from the center of rotation is also recorded at the same distance from the center of rotation on the slave magnetic disk, that is, the track positions are made to match.

Furthermore, by performing transfer after aligning the index positions of the master magnetic disk and the slave magnetic disk using the same chucking mechanism, it is possible to easily obtain a slave magnetic disk that is exactly the same as the master magnetic disk.

(Embodiment) Hereinafter, a magnetic disk transfer method according to an embodiment of the present invention will be described in detail with reference to the drawings.

This embodiment will be described in detail by taking as an example a magnetic disk housed in a 3.5-inch size floppy disk, which has been widely available on the market in recent years.

Figure 1 shows a schematic perspective view of this magnetic disk.
A metal hub (21) is bonded to the center of a 3.5-inch disc-shaped magnetic disk (11) with an adhesive.

The hub (21) has a chucking part (23) for good chucking to a chucking mechanism (not shown), and 7 langes extending from the chucking part (23) to hold the magnetic disk (11). (29). In the center of the chucking part (23), there is a center hole (25) into which the center pin of the chucking mechanism can be inserted, and on the outer peripheral side of the center hole (25)', the engagement pin of the chucking mechanism is inserted. An insertable engagement hole (27) is formed.

FIG. 2 shows an example of a transfer device (IOI) for realizing the present invention, in which a first support part (IOI) having a smooth magnetic disk holding surface (113) is installed on a stage (105). 111) and a second support part (151) installed on the first support part (111), and the second support part (151) is installed on the first support part (111). It is movable in the vertical direction.

A chucking mechanism (171) for supporting a 3.5-inch magnetic disk (11) is installed in the center of the first support part (111), and this chucking mechanism (171) The adjustment mechanism (191) allows fine movement in the vertical direction like the second support part (151).

This chucking mechanism (171) includes a magnetic disk (1
It is equipped with a circular chucking surface (173) for chucking with the chucking surface (23) of the hub (21) of 1), and a center pin (175) is provided at the center of the chucking surface (R3), and a center pin (175) is provided on the outer peripheral side of the chucking surface (R3). An engagement pin (177) is installed. And this chucking mechanism (171
), the magnetic disk (11) is attached to the center pin (17
5) is rotatable around the center. The first support part (111) also has a first support part (111) and a second support part (111).
The space (201) formed by the supporting part (151) of
) is provided with an air hole (211) connected to a vacuum pump (not shown) for removing the air within. Furthermore,
The magnetic disk holding surface (113) of the first support part (111)
) An air packing (121) is continuously provided on the outer circumferential side for completely adhering to the second support part (151).

The second support part (151) has a convex part (161) formed along the outer circumferential side so as to be in close contact with the air packing (121) of the first support part (111). A ring-shaped first rib (153) on the slightly inner circumferential side;
A second rib (155) is located further inward from the rib (153).
) is provided. The heights of these first ribs (153) and second ribs (155) are the same as those of the first ribs (153).
) is formed slightly higher than the second rib (155). In addition, the first rib (153) and the second rib (15
A ventilation hole (157) is provided with a filter (159) to prevent foreign matter such as dust from entering from the outside.
) is formed.

The transfer method of this embodiment will be explained using such a transfer device (101).

First, the first master magnetic disk (301) is chucked by the chucking mechanism (171), and the engaging pin (
177) until it reaches a predetermined position, it is installed and fixed on the magnetic disk holding surface (113) of the first support part (111) by the adjustment mechanism (191). Then, the hub (not shown) of the first master magnetic disk (301) is separated from the first master magnetic disk (301), and the hub is removed from the chucking mechanism (171).

Next, a second master magnetic disk (401) similar to the first master magnetic disk (301) is chucked by the chucking mechanism (171), and the engaging pin (177)
), , until they are at the predetermined position, the adjustment mechanism (191) rotates the second master magnetic disk (401).
) on the installation surface and secure it.

In this way, the magnetic disks (301) and (401) on which master information is recorded are installed in the first support part (111) and the second support part (151).

After that, the slave magnetic disk (501) is chucked by the chucking mechanism (171), and the engaging pin (17
7) is each master magnetic disk (301), (401
), then turn the adjustment mechanism (1
91), the magnetic disk (301) and slave magnetic disk (501) on the installation surface of the first support part (ili)
Insert the slave magnetic disk (50
1), and then adjust the adjustment mechanism (191) to that height position.
) to be fixed.

Next, the air packing (121) of the first support part (111)
) and the convex part (161) of the second support part (151) are brought into close contact with each other, and the second support part (151) is lowered toward the first support part (111). In this state, the outer circumferential side of the slave magnetic disk (501) and the outer circumferential side of the second master magnetic disk (401) are located at the height of the first rib (153) and the second rib (155). Due to the difference in height, they are in a state of slight contact.

By operating a vacuum pump (not shown) in this state, air is removed from the vent hole (157), and the air is removed from the air vent (157). Decrease the atmospheric pressure within the space (201).

Then, the first master magnetic disk (301) and the second master magnetic disk (401) gradually come into close contact with the slave magnetic disk (501) from the outer peripheral side, and finally the first master magnetic disk (301) and the second
The master magnetic disk (401) and slave magnetic disk (501) are in complete contact with each other.

In this state, by applying a bias magnetic field from the outside, the magnetic information on the first master magnetic disk (301) and the second master magnetic disk (401) is transferred to the slave magnetic disk (501). Become.

By performing magnetic disk transfer as described above,
It becomes possible to transfer the magnetic disk easily and accurately.

In particular, the master magnetic disk (301), (401)
By performing the transfer with the slave magnetic disk (501) and the slave magnetic disk (501) chucked in the same chucking mechanism (171), the following effects are achieved.

That is, master magnetic disks (301), (401)
It is very easy to align the slave magnetic disk (501) and the slave magnetic disk (501).

Furthermore, since a slave magnetic disk (501) with a hub (21) installed in the center in advance is used, the positional accuracy from the center of rotation to each magnetic information is degraded compared to installing the hub (21) after transfer. Never.

In addition, for a 3.5-inch magnetic disk, the angle formed by the line formed by the center pin and the engagement pin determines the index, and as described above, using the same chucking mechanism (171), the engagement pin By making the master magnetic disk (301L (401) and slave magnetic disk (501) in the same position,
It is also possible to accurately match the index positions of the master magnetic disks (301), (401) and the slave magnetic disk (501).

Although this embodiment has been explained using a 3.5-inch magnetic disk as an example, there are also 5.25-inch and 8-inch magnetic disks that do not have a hub in the center of the magnetic disk. Also good. 5. Like this.
For 25-inch and 8-inch magnetic disks, the index position is determined by the index hole provided on the inner circumferential side of the magnetic disk, so the index hole positions of each master magnetic disk and slave magnetic disk are accurately aligned. Do I need to do it later?

[Effects of the Invention] The magnetic disk transfer method of the present invention aligns the master magnetic disk and the slave magnetic disk using the same chucking mechanism. The distance to each piece of magnetic information can be accurately transferred to the slave magnetic disk. Therefore, especially in the case of a magnetic disk that has a hub installed in the center for chucking with a chucking mechanism, the transfer is performed after the hub is installed, so misalignment of the magnetic information transfer position may occur due to misalignment of the hub installation. There's nothing to do.

Furthermore, since a magnetic disk equipped with a hub or the like or a slave magnetic disk with an index hole formed therein is used, it is possible to accurately align the index position during transfer. This sufficiently eliminates the problem that magnetic information cannot be read from the slave magnetic disk after transfer.

[Brief explanation of drawings]

FIG. 1 is a schematic perspective view of a 3.5-inch magnetic disk, and FIG. 2 is a schematic cross-sectional view of an embodiment of a transfer device. (11)...Magnetic disk (21)...Hub (IOI)...Transfer device (IIL)...First support part (151)...Second support part (301), ( 401)...Master magnetic disk (501)...Slave magnetic disk agent Patent attorney Nori Chika Ken Yudo Kikuo Takehana Diagram

Claims (1)

[Claims] A magnetic disk transfer method for transferring magnetic information from a master magnetic disk to a slave magnetic disk, including the steps of fixing the master magnetic disk after being chucked by a chucking mechanism and removing it from the chucking mechanism. chucking the slave magnetic disk in the chucking mechanism; aligning the index position of the slave magnetic disk with the index position of the master magnetic disk; and bringing the master magnetic disk and slave magnetic disk into close contact with each other. A method for transferring a magnetic disk, comprising: a step of transferring magnetic information from the master magnetic disk to the slave magnetic disk.