JPS63206925A - Optical information recording disk and its production - Google Patents

Abstract

PURPOSE:To permit easy and precise matching of the center of guide tracks and the center of a spindle insertion hole by forming a step part for positioning into the central hole bored to the center of the guide tracks and disposing the center of the step part and the center of the spindle insertion hole bored to a hub on the same axial line. CONSTITUTION:The step part 7 which is a trace of penetration is easily formed in the central hole of a substrate 1 and the precision indexing of the central axis of the guide tracks 3 is permitted when a projecting part for fixing the substrate is press-fitted into the central hole 2 by using a centering jig consisting of a base plate 11, the projecting part 12 projected on the base plate 11 and a pin 13 for positioning the hub erected coaxially on said projecting part. Since the pin 13 for positioning the hub is coaxially erected on the projecting part 12, the axial lines of the step part 7 and the spindle insertion holes 8 are easily aligned by inserting the pin 13 into the spindle insertion hole 8 of the hub 5.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to an optical information recording disk that records and reproduces information by irradiating it with a light beam.

More specifically, the present invention relates to an optical information recording disk equipped with a hub for centering the optical information recording disk using a spindle provided in a recording/reproducing device.

[Conventional technology]

Conventionally, as shown in FIG. 7, a hub 22 made of a material with excellent wear resistance is attached to the center of a substrate 21, and a spindle 24 of a recording/reproducing device is inserted into a spindle insertion hole 23 formed in the hub 22. An optical information recording disk is known in which the guide track 25 formed in a concentric or spiral shape on the substrate 21 is centered by being inserted therethrough.

In this optical information recording disk, if the center of the spindle insertion hole 23 is not exactly aligned with the center of the guide track 25, when the substrate 21 is rotated, the trajectory of the guide track 25 will become elliptical and the optical head will The tracking of the irradiated laser beam becomes tsm, and in the worst case, the laser beam goes off track, making normal recording and reproduction impossible. For this reason, the center of the spindle insertion hole 23 and the center of the guide track 25 must be exactly aligned. For example, the track pitch is 1.
．． For 6μ- optical information recording discs, it is usually 5, 10
It is required to reduce the cost to ~20 μm or less.

Conventionally, when producing this type of optical information recording disk, a substrate 2 is placed on an X-Y table 26 as shown in FIG.
1 is fixed, the guide track 25 formed on the substrate 21 is read out by an optical head 27 disposed opposite to this X-Y table 26, and its center is determined by a calculation device 28, and the center and the hub 22 are After aligning the centers of the opened spindle insertion holes 23, the hub 22 is attached to the substrate 21.

In this optical information recording disk, the spindle 24 is inserted into the spindle insertion hole 23 of the hub 22, which is made of a material with excellent wear resistance.

There is an advantage that the substrate 21 is not damaged even if the spindle 24 is inserted in a reverse manner, and the durability is excellent.

[Problems to be Solved by the Invention] However, as mentioned above, conventional optical information recording disks are not provided with any means for determining the center of the guide track 25, This method not only requires expensive equipment such as a head and an arithmetic unit, but also requires a great deal of labor and skill for centering, which poses a problem that it cannot be applied to the production of optical information recording disks, which are mass-produced products.

[Means for solving problems]

The present invention provides an optical information recording disk in which the center of the guide track and the center of the spindle insertion hole can be easily and accurately aligned, and the center of the guide track can be easily and accurately aligned with the center of the spindle insertion hole. A step for positioning is formed in the center hole opened in the hub, and the center of the step and the center of the spindle insertion hole opened in the hub are arranged on the same axis.

In addition, a centering jig consisting of a base, an i & temporary fixing protrusion protruding on the base, and a hub positioning pin coaxially provided on the board fixing protrusion is provided. Use the above! WJ that the IIFi fixing protrusion was press-fitted into the center hole of the board, and then the hub positioning pin was inserted into the spindle insertion hole of the hub so that the axes of both holes were aligned.
This is an architectural feature.

[Effect]

When a step for positioning is formed in the center hole opened at the center of the guide track, for example, the roundness of the center hole may not be formed with a sufficiently high precision, or a bulge etc. may protrude into the center hole. Even in this case, the central axis of the guide track can be accurately determined, and the spindle insertion hole formed in the hub can be centered using this step as a reference. Therefore, the productivity of optical information recording disks can be improved without requiring expensive equipment as in the past.

In addition, a centering jig consisting of a base, a board fixing protrusion protruding from the base, and a hub positioning pin coaxially provided on the board fixing protrusion is provided. When the board fixing protrusion is press-fitted into the center hole of the board, a step, which is a press-fit mark, is easily formed in the center hole. The center axis of the guide track can be precisely determined even when there is a protrusion in the central hole. In addition, since a hub positioning pin was installed coaxially on this board fixing protrusion, by inserting this hub positioning pin into the spindle insertion hole of the hub, the axes of the stepped portion and the spindle insertion hole were aligned. Can be easily matched.

〔Example〕

1 is a sectional view of an optical information recording disk showing a first embodiment of the present invention, and FIG. 2 is a plan view of the optical information recording disk of FIG. 1, in which 1 is a substrate, 2 is a central hole, and 3 4 is a guide track, 4 is a recording film, and 5 is a hub.

6 indicates a holder that holds the hub 5.

The substrate 1 is made of a transparent resin material such as polycarbonate or epoxy, and is formed into a disk shape with a central hole 2 in the center.

As shown in FIG. 2, this central hole 2 is opened such that its central axis coincides with the center P of a guide track 3 formed concentrically or spirally on one side of the substrate 1. Moreover, as shown in FIG.
A stepped portion 7 is formed from this sloped portion 7a to a straight portion 7b penetrating the inner surface of the substrate 1, that is, the surface on which the guide track 3 and the recording film 4 are formed.

The diameter of the straight portion 7b can be formed to an appropriate size as required, but it is a stepped portion to facilitate the i2f and to accurately and easily center the hub 5, which will be described in detail later. Taking this into consideration, it is sufficient to use a very small diameter, and in practice, it is sufficient to make the diameter D1 of the straight portion 7b larger than the diameter D2 of the central hole 2 by 0.1 to 60 μm.

Further, the inclination angle O1 of the side surface portion 7a can be formed to an appropriate size as necessary, but this is done in order to facilitate centering of the hub 5, which will be described in detail later.

It is preferable to set the angle to 15 to 45 degrees.Furthermore, the range I in which the step portion 7 is formed can be arbitrarily designed as necessary, but from the viewpoint of ease of manufacture, etc.
．． It is preferable to set it as 3-1.0 mm.

Incidentally, in the above embodiment, a case has been described in which the stepped portion 7 is composed of a slope 7a continuing from the central hole 2 and a straight portion 7b continuing from the end of the slope 7a to one side of the substrate 1. The gist of the invention is not limited to this, but as shown in FIG. It can also be configured. In this case as well, the diameter Dz of the straight portion 7b and the formation range l of the stepped portion 7 can be formed in the same manner as in the above embodiment.

Further, as shown in FIG. 4, the step portion 7 is
It can also be formed by an inclined surface continuing from one side of the substrate 1. In this case as well, the step portion 7 can be formed to any size.

In practice, the maximum diameter DB of the slope is the diameter D2 of the central hole 2.
It is sufficient to make the diameter larger by 0.1 to 60 μrrl. Further, the inclination angle θ2 of the stepped portion 7 and the range l in which the stepped portion 7 is formed can be formed in the same manner as in the first embodiment for the same reasons as described above.

As the means for forming the step portion 7, any known means such as cutting, pressing, etc. can be used.

This is because the stepped portion 7 is an extremely small step as seen from the top.

It can be easily formed by press-fitting a rod-shaped object having a slightly larger diameter than the central hole 2.

As shown in FIG. 5, the hub 5 is formed into a substantially disk shape with a spindle insertion hole 8 in the center. This hub 5
The hub 1 can be made of any material with excellent wear resistance such as metal or hard plastic, but the hub 5 is also used as a magnetic adsorption plate for application to a magnetic clamp type disk drive device. In some cases, magnetic fully refractory materials such as soft iron, ferritic or martensitic stainless steel are used. In this case 1
JIS standard 5US430 stainless steel is particularly suitable because it is less than M and can be obtained at a relatively low cost.

As shown in FIG. 1, the hub 5 is attached to the outer surface of the substrate 1 via a holder 6, which will be described later. that time,
The spindle is installed so that the center of the spindle insertion hole 8 exactly coincides with the center of the step 7.

The holder 6 is formed in the shape of a single ring as shown in FIG. 5, and the hub 5 is integrally attached to the inner peripheral surface of the holder 6.

Although any known means such as adhesion or screwing can be used to integrate the hub 5 and holder 6, insert molding is particularly preferred since it has good productivity. As the material for forming this holder 4, any resin material can be used in addition to the same resin material as the substrate 1, but in particular 5, such as polyamide, polyimide, polyimideamide, polyacetal, polypropylene, etc. Resin materials are preferred.

The edge of the outer periphery of the holder 6 is provided with an edge to facilitate installation of a turntable installed in the disk drive device.
It is preferable to provide a chamfer 9. Of course, this chamfer shape may be an inclined surface or a curved surface, and the size thereof is preferably about 0.3 to 1.0 mm. 1. The holder 6 and the substrate 1 can be attached by any known means such as contact, fusion, and screwing, but bonding is preferable because of its good workability. Particularly suitable. In this case, any known adhesive can be used as the adhesive, but it is preferable to use photocurable fallen fat because it has particularly good workability.

The optical information recording disk of the above embodiment has a center hole 2 of a substrate 1.
Since the stepped portion 7 is formed in the center hole 2, the center of the guide track 3 can be precisely adjusted even if the roundness of the center hole 2 is not formed with high precision or if a ridge or the like protrudes into the center hole 2. can be divided into Therefore, the spindle insertion hole 8 formed in the hub 5 can be centered with respect to the stepped portion 7, and the spindle insertion hole 8 can be precisely centered with respect to the guide track 3.

Therefore, when assembling the board 1 and the hub 5, expensive equipment and a large amount of labor are not required as in the conventional case.

Productivity of optical information recording disks can be improved.

Hereinafter, a device for centering the center hole 2 formed in the substrate 1 and a spindle insertion hole 8 formed in the hub 5 and a centering method using the same will be described.

FIG. 6 is a front view of the centering jig. It consists of a hub positioning pin 13. The centers of the board fixing protrusion 12 and the hub positioning pin 13 are exactly matched, and their axes are arranged on the same axis.

The board fixing protrusion 12 is formed by forming an introduction part 12b above a straight part 12a having a height lower than the thickness of the board 1. The diameter of the straight portion 12a is as described above! Gml
The substrate fixing protrusion 12 is press-fitted into the center hole 2 to fix the base Fi1. The press-fitting margin between the board fixing protrusion 12 and the center hole 2 is 0.1 to 60μ.
The thickness is more preferably set to 20 to 30 μm. When the press-fitting is performed with this press-fitting allowance, a press-fitting mark 14 of the straight portion 12a is formed in part or all of the central hole 2. In this way, the press-fitting mark 14 of the board fixing protrusion 12 is inserted into the center hole of the board.
Forming this will make the outside smoother and allow for more accurate centering.

The four-person portion 12b is formed into a sloped or curved shape. When the introduction portion 12b is formed in the shape of a slope, it is preferably formed with a slope inclined at approximately 15 to 45 degrees with respect to the vertical line.

The hub positioning pin 13 is formed to have a smaller diameter than the spindle insertion hole 8 formed in the hub 5.

The hub 5 can be positioned without press-fitting the hub positioning pin 13 into the spindle insertion hole 8. The clearance between the hub positioning pin 13 and the spindle insertion hole 8 is set to about 5 to 10 μm.

When centering the board 1 and the hub 5 using the centering device, the central hole 2 of the board 1 is press-fitted into the board fixing protrusion 12, and then the hub 5 is fitted into the hub positioning pin 13. The two axes are aligned by inserting the two through the spindle insertion hole 8 of the two. Thereafter, the holder 6 and the base film are bonded together or ultrasonically fused, etc., thereby fixing both members.

The substrate fixing protrusion 1 of the centering jig is inserted into the center hole 2 of the substrate 1.
2, a ring-shaped press-fit mark is formed around the center hole 2. Therefore, even if the roundness of the center hole 2 is not formed with high precision or if a ridge or the like protrudes into the center hole 2, the shape of the center hole 2 is formed, and the center of the guide track 3 is formed. The axis can be precisely determined. Further, since a hub positioning pin 13 is provided upright coaxially with this board fixing protrusion 12, by inserting this hub positioning pin 13 into the spindle insertion hole 8 of the hub 5, the step part 7 and the spindle insertion hole 8 axes can be easily matched. Therefore, the guide track 3 formed on the substrate 1 and the spindle insertion hole 8 can be precisely centered.

Further, the above-mentioned centering jig can be manufactured at a much lower cost than a conventional centering device equipped with an optical head and an arithmetic device.

1. The gist of the present invention is that a step for determining (it'111) is formed in the center hole of the substrate, and the center of the step and the center of the spindle insertion hole are arranged on the same axis. However, the material and shape of the hub, the means for attaching the hub and the board, and the shape and dimensions of the stepped portion are not limited to those of the above embodiments, and these may be changed as necessary. can be designed.

〔Effect of the invention〕

As explained above, the optical information recording disk of the present invention has
Since a step for positioning is formed in the central hole opened at the center of the guide track, the spindle insertion hole can be easily centered with respect to the guide track using this step as a reference.

Productivity of optical information recording disks can be improved.

[Brief explanation of the drawing]

FIG. 1 is a sectional view schematically showing an optical information recording disk according to the present invention, FIG. 2 is a plan view of the optical information recording disk shown in FIG. 1, and FIGS. FIG. 5 is a partially cutaway perspective view of the hub and holder, FIG. 6 is a partially cutaway front view of the centering jig according to the present invention, and FIG. 7 is a conventional FIG. 8 is a cross-sectional view showing an example of an optical information recording disk, and FIG. 8 is a front view showing an example of a conventional centering device. 1: Board, 2: Center hole, 3: Guide track. 4: Membrane, 5: Hub, 6: Holder, 7: Step, 8 Nissin spindle insertion hole, 9: Chamfer, 11: Base. 12: Board fixing protrusion, 13: Hub positioning pin, 1
4: Press-fit marks Fig. 1 1: X plate 6: This IL/
ri2・Chuinukyou 7=jsenku 3+ rTl: J1 rat 2 7a: Reito nb
4, Myoko a Tsukisara 7b = Tray 1 - Shu 5
I huff “8:2 μ” I, about 2nd figure 3rd figure 4th figure 5th figure 6th figure

Claims (1)

[Claims] (1) A substrate having a central hole formed in the center of a guide track formed in a concentric or spiral shape, and a spindle hole into which a spindle provided in a disk drive device is inserted. In an optical information recording disk equipped with a hub,
An optical information recording disk characterized in that a step for positioning is formed in the center hole, and the center of the step and the center of the spindle insertion hole are arranged on the same axis. (2) In the optical information recording disk according to claim 1, the stepped portion includes a sloped portion or a curved surface portion continuing from the central hole, and a slope portion or curved surface portion continuing from the end of the sloped portion or curved surface portion to one side of the substrate. An optical information recording disk characterized in that it is formed from a straight section. (3) In the optical information recording disk according to claim 2, the diameter of the straight portion is set to 0 from the center hole.
．． An optical information recording disk characterized by having a large diameter of 1 to 60 μm. (4) The optical information recording disk according to claim 2, wherein the slope portion has an inclination of 15 to 45 degrees with respect to the center line of the central hole. (5) The optical information recording disk according to claim 1, wherein the stepped portion is formed in a slope shape extending from the central hole to one side of the substrate. (6) In the optical information recording disk according to claim 5, the maximum diameter of the stepped portion is set to be 0.1 from the center hole.
An optical information recording disk characterized by having a large diameter of ~60 μm. (7) The optical information recording disk according to claim 5, wherein the step portion has an inclination of 45 degrees or less with respect to the center line of the central hole. (8) A centering jig consisting of a base, a board fixing protrusion protruding on the base, and a hub positioning pin coaxially provided on the board fixing protrusion. manufacturing an optical information recording disk, comprising the steps of press-fitting the substrate fixing protrusion into a central hole of the substrate, and then inserting the hub positioning pin into the spindle insertion hole of the hub to align the axes of both holes. Method.