JPH01151065A - Magnetic disk device - Google Patents

Abstract

PURPOSE:To realize the rotation driving of a magnetic disk rotating body at the critical temperature of a superconductor by mounting a strong magnet between magnetic disks and arranging the superconductor around it. CONSTITUTION:Magnets 12-13 and superconductors 9 and 10 are arranged at the cavity part between magnetic disk media and a magnetic disk rotating body is supported non-contactly with an enclosure 7 of a head disk assembly. Consequently, when an atmosphere temperature arrives at the temperature to display the function of the superconductors 9 and 10, namely, a critical temperature, the rotating body composed of a magnetic disk 1, a clamp ring 2, a hub 3', a disk lamp 4 and a rotor 14b of a motor 14 floats by the repulsive force to occur between respective magnets 12 and 13 and the superconductors 9 and 10 corresponding to respective ones and is supported non-contactly with the enclosure of a head disk assembly. Thus, at the very low temperature conditions, namely, the critical temperature of the superconductor, the rotation driving of the magnetic disk rotating body can be realized.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to a magnetic disk device, and particularly to a magnetic disk device in which a spindle portion (rotating portion) is configured by utilizing the Meissner effect of a superconductor.

[Conventional technology]

A conventional magnetic disk device uses a shaft as its rotating portion, and this shaft is rotatably supported by a housing using a ball bearing or a fluid bearing.

FIG. 2 is a sectional view of a conventional magnetic disk device A. In the figure, reference numeral 1 denotes a plurality of stacked magnetic disks (magnetic disk media), which are attached to a hub 3 via a clamp ring 2. Reference numeral 4 indicates a disk clamp attached to the hub 3 to firmly fix the attachment, 5 indicates a shaft to which the hub 3 is attached, and 6 indicates upper and lower bearings that rotatably hold the shaft 5. Further, 7 is a housing of a closed type head/disk assembly, and 71
is its base, and 72 is its cover, to which the bearing 6 is attached.

Furthermore, 8 is a magnetic disk rotating body (shaft 5, hub 3
, disk clamp 4, clamp ring 2, magnetic disk 1, etc.), and is composed of a rotor 8a and a stator 8b.The rotor 8a is fixed to one end of the shaft 5, and the stator 8b is fixed to the rotor 8a. It is fixed to the base 71 in a contact state.

As described above, the conventional magnetic disk device A generally has a structure in which the magnetic disk 1 is supported together with the shaft 5 by the housing 7 via the bearing 6.

[Problem that the invention seeks to solve]

However, in recent years, attention has been paid to the superconducting phenomenon, and its application to magnetic disk drives is also being considered. However, the critical temperature of currently available superconductors is the liquid nitrogen temperature, so ball bearings and fluid bearings used to support magnetic disk rotating bodies cannot be used at such low temperatures. In other words, in ball bearings, the lubricant grease is
Furthermore, in hydrodynamic bearings, the lubricating oil used as the working fluid no longer performs its original function.

On the other hand, it is possible to apply a gas bearing that can be used even at extremely low temperatures to the magnetic disk rotating body, but since the rotational speed of the magnetic disk is one order of magnitude lower than the rotational speed to which a gas bearing is applied, the gas bearing is The disadvantage is that the load capacity of the bearing is low, making it impractical.

Furthermore, it is possible to consider a configuration in which the magnetic disk rotating body can be rotated without contact by using the repulsive force between magnets without using ball bearings or fluid bearings, but this combination allows the magnetic disk rotating body to have high performance. In order to support the magnetic disk, a powerful magnet is required, and a new problem arises in that the leakage magnetic field from the magnet makes it impossible to record on or read from the magnetic disk.

The present invention has been made in view of the above circumstances, and its first purpose is to provide an environment in which the temperature is so low that ball bearings, oil-lubricated fluid bearings, etc. that rotatably support the magnetic disk rotating body cannot be used. , To be able to rotatably support a magnetic disk rotating body without giving a leakage magnetic field to the magnetic disk, and secondly, to be able to support bearings such as ball bearings and shafts etc. that supported the hub of the rotating body. The purpose of the present invention is to enable removal of the central portion of the hub and to rotate the center portion of the hub with an inside hub motor.

[Means for solving problems]

To this end, the present invention provides a magnetic disk rotating body in which a plurality of magnetic disk media are stacked on a hub, and a positioner mechanism that positions a head for recording and reproducing the magnetic disk medium on the surface of the magnetic disk medium in a closed type. In a magnetic disk device mounted in a head/disk assembly, a magnet and a superconductor are arranged in the gap between the magnetic disk media, and the magnetic disk rotating body is connected to the head/disk assembly.
It was designed to be supported without contacting the housing of the disc assembly.

〔Example〕

In the following, a magnetic disk device according to an embodiment of the present invention will be described. In the present invention, in order to rotatably support a magnetic disk rotating body, magnets and superconducting We adopted a structure that provides high rigidity and non-contact support between the body and the body.

That is, focusing on the Meissner effect, which is a characteristic of superconductors,
This takes advantage of the property that if the relationship between the magnet and superconductor is properly placed, the magnet and superconductor will repel each other, making it impossible for the magnetic field of the magnet to pass through the inside of the superconductor. In other words, by mounting a strong magnet between magnetic disks and arranging a superconductor around it, the magnetic field of the magnet is prevented from leaking to the magnetic disk, and it is configured so that it does not affect recording and playback. ing.

FIG. 1 is a sectional view of a magnetic disk device B according to an embodiment of the present invention. Note that the same reference numerals are used for the same components as in the conventional magnetic disk device A, and the explanation thereof will be omitted.

Reference numeral 9 indicates a first superconductor for radial support that is integrally attached to the clamp ring 2, and reference numeral 10 indicates a second superconductor for thrust support that is disposed on the magnetic disk 1. These superconductors 9 and 10 include a first radially compatible magnet 12 which is magnetized in the radial direction and which is disposed on a bearing stand 11, and a second thrust compatible magnet 12 which is magnetized orthogonally to the superconductor 10. It is arranged so as to surround the magnet 13. Bearing stand 11
is fixed to the base 71 of the housing body 7.

An inside hub motor 14 is mounted inside the hub 3', and its rotor 14a is fixed to the inner surface of the hub 3', and its stator 14b is fixed to the base 71 of the body 7.

Although not shown, a magnetic head positioned by a positioner mechanism is provided on one surface of the magnetic disk.

Now, the magnetic disk device of this example is configured as follows,
The temperature at which the ambient temperature exhibits the function of superconductor 9.10,
That is, when the critical temperature is reached, the rotating body composed of the magnetic disk 1, the clamp ring 2, the hub 3', the disk clamp 4, and the rotor 14b of the motor 14 rotates around each magnet 12.
．． 13 and the corresponding superconductors 9 and 10, the superconductors float up and are supported without contacting the housing of the head/disk assembly.

〔Effect of the invention〕

As explained above, in the present invention, the support mechanism for the magnetic disk rotating body is composed of a magnet and a superconductor.
The magnetic disk rotating body is now supported without contact. Therefore, it is possible to realize rotational driving of the magnetic disk rotating body under extremely low temperature conditions, that is, at the critical temperature of the superconductor.

Furthermore, since it is supported in a non-contact manner, the structure of shafts, bearings, etc. in conventional devices is unnecessary, and the concern of grease scattering from bearings is completely eliminated. Moreover, it becomes possible to arrange the bearing portion at the center of gravity of the rotating body. Also,
The inside hub motor can be placed approximately in the center of the rotating body. Furthermore, it is also excellent in preventing the generation of dust in the rotating part and suppressing rotational vibration.

[Brief explanation of the drawing]

FIG. 1 is a sectional view of a magnetic disk device according to an embodiment of the present invention, and FIG. 2 is a sectional view of a conventional magnetic disk device. B...Magnetic disk device of this embodiment, 1...Magnetic disk, 2...Clamp ring, 3'...Hub, 4
... Disk clamp, 7... Enclosed type head/disk assembly housing, 71... Base, 72
... cover, 9 ... first superconductor, 10 ... second superconductor, 11 ... bearing stand, 12 ... first magnet, 13 ... second magnet, 14... Inside hub motor, 14a... Rotor, 14b... Stator.

Claims (2)

[Claims] (1) A magnetic disk rotating body in which a plurality of magnetic disk media are stacked on a hub, and a positioner mechanism that positions a head for recording and reproducing the magnetic disk medium on the surface of the magnetic disk medium are combined into a closed type head. In a magnetic disk device mounted in a disk assembly, a magnet and a superconductor are arranged in the gap between the magnetic disk media to support the magnetic disk rotating body without contacting the housing of the head disk assembly. A magnetic disk device characterized by: (2) The magnetic disk device according to claim 1, wherein the hub has an inside hub motor for rotationally driving the magnetic disk rotating body inside the hub.