JPH0283875A - Method for assembling magnetic disk medium - Google Patents

Abstract

PURPOSE:To prevent a chip due to the contact at the time of assembling from generating by laying a resin type thin buffer between a magnetic disk medium and a spacer ring and the hub of a spindle. CONSTITUTION:A resin type thin buffer 11 is laid between the outer circumference of a hub 3 of a spindle and a magnetic disk medium 5 and a spacer ring 6. Thus, while the thin buffer 11 composed of a resin type low friction material is laid, the medium 5 and the ring 6 are alternately inserted and piled to the outer circumference of the hub 3. Thus, when the ring 6 is inserted into the outer circumference of the hub 3, the medium 5 and the ring 6 are not directly contacted with the hub 3. For this reason, two metals are rubbed, contacted and thus, the chip is not generated.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] A magnetic disk drive has a structure in which magnetic disk media and spacer rings are alternately stacked and fixed around the outer periphery of a spindle hub. The present invention relates to a method of mounting and assembling a magnetic disk medium and a spacer ring around the outer periphery of a spindle hub.

A gap is provided.

[Conventional technology]

FIG. 5 is a sectional view of the magnetic disk medium mounting section of the magnetic disk device. A hub 3 is fixed to the inner end of a spindle 2 inserted and supported by a casing l of a magnetic disk device, and a drive motor M is connected to the outer end.

On the outer periphery of the spindle hub 3, magnetic disk media 5 and spacer rings 6 are alternately stacked on a flange 4 at the lower end, and are screwed onto the hub 3 by a disc-shaped clamper 7.

A spindle 2 is driven by a motor M to rotate a magnetic disk medium at high speed, and a magnetic head 9 records/reproduces information.

By the way, in order to be able to mount the magnetic disk medium 5 and spacer ring 6 on the outer circumference of the hub 3, there is a microscopic gap of about 0.05 tm between the inner circumference of the magnetic disk medium 5 and spacer ring 6 and the outer circumference of the hub 3. [Problem to be Solved by the Invention] This gap is necessary for assembling the magnetic disk medium and spacer ring, and if it is too small, it will be difficult to insert the magnetic disk medium and spacer ring into the outer periphery of the hub 3. On the contrary, if it is too large, the misalignment of the magnetic disk medium and the spacer ring becomes large, and the dynamic balance during rotation of the magnetic disk medium is lost.

Therefore, this gap should be as small as possible, but as a result, the magnetic disk media and spacer ring should be kept close to the hub 3.
As shown in FIG. 6, when the magnetic disk medium and the inner peripheral edges 5a, 6a of the spacer ring rub against the outer peripheral surface of the hub 3, chips 10 are generated. The chips 10 accumulate on the magnetic disk medium 5 and the magnetic head 9
This may affect the levitation of the machine and cause head crashes, etc.

In particular, since a soft material such as aluminum is used as the material for the hub 3 in order to reduce weight, chips are likely to be generated.

To solve this problem, the gap between the magnetic disk medium and spacer ring and the hub 3 can be increased so that they do not come into contact with each other during insertion.

However, as mentioned above, problems arise in that the dynamic balance is disrupted, causing vibrations in the spindle and
This will cause problems such as deterioration of bearing life.

The technical problem of the present invention is to solve such problems when assembling magnetic disk media, and to prevent the generation of chips.
Another object of the present invention is to assemble a magnetic disk medium by a method that is easy to mount and does not cause misalignment of the magnetic disk medium and spacer ring.

[Means to solve the problem]

FIG. 1 is a cross-sectional view illustrating the basic principle of the method for assembling a magnetic disk medium according to the present invention. Reference numeral 3 designates a spindle hub, and a thin resin-based buffer 11 is interposed between its outer periphery and the magnetic disk medium 5 and spacer ring 6.

In this way, the thin buffer 1 made of resin-based low friction material
1 is interposed, on the outer periphery of the spindle hub 3,
The magnetic disk medium 5 and spacer ring 6 are inserted alternately and overlapped.

[Effect]

In this way, since the resin-based thin buffer 11 is interposed, when the magnetic disk medium 5 and spacer ring 6 are inserted into the outer periphery of the spindle hub 3, the magnetic disk medium 5 and spacer ring 6 are inserted into the spindle hub. There is no direct contact with 3.

Therefore, unlike in the past, metals do not rub against each other or come into contact with each other, causing chips to be generated. Further, since the buffer 11 is made of resin, it has elasticity, so even if the magnetic disk medium 5 or the spacer ring 6 comes into contact with the spindle hub 3, the impact is alleviated.

As shown in the diagram, the magnetic disk medium 5 and the spacer ring 6
Since there is no problem when inserting the magnetic disk medium 5 and the spacer, there is no need to pay careful attention to the details.
Workability when inserting the ring 6 is improved.

〔Example〕

Next, how the method for assembling a magnetic disk medium according to the present invention is actually implemented will be explained using examples. Second
The figure is a sectional view showing a first embodiment of the method for assembling a magnetic disk medium according to the present invention.

A synthetic resin ring I2 is placed on the spindle hub 3. The outer diameter of this ring 12 is preferably the same as or slightly smaller than the outer diameter of the hub 3. Further, by fitting the upper end 2a of the spindle into the hole in the center of the ring 12, the ring 12 can be stably positioned on the hub 3.

A thin resin film lla is wrapped around the outer peripheries of the hub 3 and the ring 12, and the upper end is bonded only to the ring 12. It is preferable to wrap the film lla around the outer periphery of the ring 12 and the hub 3 about once, but even if it is not enough to wrap around the outer circumference of the ring 12 and the hub 3,
On the contrary, there is no problem even if there is some overlap.

In this state, from above the ring 12, the spacer ring 6
and magnetic disk media 5 are inserted alternately and stacked on the outer periphery of the hub 3. After the insertion is completed, the ring 12 is pulled up to remove the film 11a. lastly,
As shown in FIG. 5, it is tightened and fixed using a clamper 7.

The side wall of the hub 3 usually has air holes for ventilation, so after inserting the magnetic disk medium, the film lla
By removing the air holes, the air holes are not blocked.

By providing the ring 12 on the hub 3, this ring 1
2 serves as a guide when inserting a magnetic disk medium and a spacer ring, and also serves as a support for the film Ila. Further, by making the ring 12 made of synthetic resin, even if a magnetic disk medium or a spacer ring collides with the ring 12 during insertion, the impact is reliably alleviated, and workability is greatly improved.

Note that Teflon or the like is suitable for the material -C of the film lla.

FIG. 3 is a diagram showing a second embodiment of the method of the present invention. (
a) As shown in the figure, several radially extending tape-like pieces 11b are formed using a thin resin film, and (b) as shown in the figure, each tape-like piece 11b is placed over the hub 3.・・・
・Let it hang around the outer periphery of the hub 3.

After inserting the magnetic disk medium and spacer ring, they are removed in the same manner as in the first embodiment.

FIG. 4 is a perspective view showing a third embodiment. (As shown in Figure 81, the spindle hub 3 usually has several protrusions 13 on the outer peripheral wall, and in the area where there are no protrusions 13,
It has the air hole 14 mentioned above. In this embodiment, a thin resin tape 11C is pasted on the protrusions 13. Tape Ilc with adhesive attached in advance has excellent workability.

A magnetic disk medium and a spacer are placed on the outside of the tape LLC.
Insert the rings alternately. In this case, there is no particular problem even if the tape LLC remains, so you can remove the tape LLC later.
There is no need to remove it. In addition, the upper end l of each tape llc
By bending and pasting the ID on the top surface of the hub 3, it is possible to prevent the ID from hitting the corners of the hub 3 when inserting the magnetic disk medium and spacer ring.

In addition to the above embodiments, at least the portion of the outer periphery of the hub 3 that is in contact with the magnetic disk medium or the spacer ring,
It can also be used as a buffer by coating it with resin. It is also possible to provide a buffer made of a film or coating on the inner circumferential side of the magnetic disk medium and the spacer ring.

〔Effect of the invention〕

As described above, according to the present invention, the magnetic disk medium and the spacer ring are interposed between the magnetic disk medium and the spacer ring, and the low friction material made of a thin resin buffer is interposed between the spindle hub 3 and the spindle hub 3. Since the ring is inserted, the magnetic disk=10 medium and the spacer ring do not come into direct contact with the spindle hub 3 and generate chips. As a result, there is no fear that the flying stability of the magnetic head will be impaired or that recording/reproduction will be hindered, and a magnetic disk device with high reliability can be obtained. Furthermore, since it is no longer necessary to pay close attention to the generation of chips, workability during assembly is improved and work efficiency is also improved.

[Brief explanation of the drawing]

FIG. 1 is a sectional view explaining the basic principle of the magnetic disk medium assembly method according to the present invention, FIGS. 2 to 4 are diagrams showing various embodiments of the method of the present invention, and FIG. FIG. 6 is a cross-sectional view showing the disk medium mounting section, and FIG. 6 is a cross-sectional view showing the locations where chips are generated when assembling the magnetic disk medium. In the figure, 2 is the spindle, 3 is the hub of the spindle,
4 is a flange, 5 is a magnetic disk medium, 6 is a spacer.
ring, 7 is a clamper, 9 is a magnetic head, 10 is a chip,
11 is a resin-based thin buffer, Ila is a resin film,
Ilb indicates a tape-like piece, and 11C indicates a tape with adhesive. 12 is ring, 13 is convex

Claims (1)

[Claims] A magnetic disk medium (5
) and spacer ring (6) alternately, when installing the magnetic disk medium (5) and spacer ring (6).
A thin resin buffer (11) is interposed between the magnetic disk medium (5) and the spindle hub (3), and the magnetic disk medium (5) and spacer ring (6)
An assembly of a magnetic disk medium characterized in that the magnetic disk medium (5) and the spacer ring (6) do not come into direct contact with the spindle hub (3) when the magnetic disk medium (5) and the spacer ring (6) are inserted into the outer periphery of the spindle hub (3). Method.