JPS6310482B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a manufacturing apparatus for high-density information recording carriers such as video discs, and more specifically to a high-density information recording carrier for manufacturing high-density information recording carriers by injection molding using ultraviolet curable resin. The present invention relates to manufacturing equipment.

Conventionally, in manufacturing high-density information recording carriers (hereinafter sometimes simply referred to as disks), whether rigid disks such as so-called LP records or donut disks are manufactured, or flexible disks such as phono sheets are manufactured. In any case, a sheet of synthetic resin such as vinyl chloride is heated and softened, a mold (stamper) having an uneven signal is pressed onto it to copy the signal, and the signal is copied for a certain period of time. The disk is then manufactured by cooling and hardening, and this manufacturing method is also applied to the manufacture of high-density information recording carriers such as video disks.

However, since the disk is manufactured by recycling heat through intermittent motion, this method has the disadvantage that manufacturing requires a large amount of time and energy.

In addition, in order to shorten the time required for manufacturing, there is a manufacturing method that separates the heating process from the pressing/cooling process and constantly cools the stamper to obtain a disk (this is the case with so-called Sonosheet), but this method faithfully reproduces the irregularities of the stamper. It cannot be transferred and reproduced and cannot be used for manufacturing high-density information recording carriers such as video discs.

Furthermore, in the above manufacturing method, the stamper itself for molding the signal is made considerably thick, or the stamper is mounted on the back of a relatively thin stamper to give it a certain degree of thickness, and then the stamper is placed in a pressing mold. The disadvantages are that it takes a long time to plate each stamper, and that it is not easy to obtain a stamper with sufficient flatness when thickening the stamper itself. Distortion occurs in the high-density information recording carrier, and it is difficult to maintain a uniform thickness, which has the disadvantage that reproduction defects such as dropouts are likely to occur during reproduction. In addition, in the case of stampers that are made thicker by attaching a base of lead or the like to the back of the stamper, the production time and material costs increase because the base is attached to each stamper, making it extremely uneconomical. It is difficult to bring the pedestals into perfect contact with each other, and air pockets and the like occur, which appear as distortions in the manufactured high-density information recording carrier.

The present invention has been made in view of the above-mentioned prior art, and the purpose of the present invention is to shorten the time required to manufacture a disk, reduce material costs, etc., and provide an economical advantage to the manufactured disk. It is an object of the present invention to provide a manufacturing apparatus for a high-density information recording carrier that has both the quality advantages of being free from distortion and the like.

The present invention also relates to patent applications previously proposed by the applicant.
It is also an improvement of the invention described in the specification of No. 54-167892. Here, to briefly explain the invention described in the specification of Japanese Patent Application No. 54-167892, an ultraviolet curable resin is used as the material of the disk, and this ultraviolet curable resin is attached by a stamper, which is a type of injection molding machine. The disk is injected into a molding space consisting of a pair of molds, an upper mold and a lower mold, and is irradiated with ultraviolet rays to harden and mold the disc.

The present invention is also a kind of injection molding apparatus, which uses an ultraviolet curable resin as a material for a high-density information recording carrier to be manufactured, and has a first mold to which a stamper can be attached;
It consists of a second mold made of a material that transmits ultraviolet rays and an ultraviolet lamp located outside the second mold, and when the first mold and the second mold are brought into contact under a certain pressure. An apparatus for producing a high-density information recording carrier by injecting and filling the resin into a molding space created between the two, and curing the resin by irradiating the molding space with ultraviolet rays, which is characterized by: However, an annular outer peripheral wall and a convex part are formed in the center part of the stamper on the outer peripheral part of the information signal to be transferred, and a recessed part to become the molding space is formed in the stamper itself, and the stamper attachment surface of the first mold is formed with a concave part in the stamper itself. has the same shape as the back surface of the stamper, and the stamper is closely fixed to the first mold.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The apparatus for manufacturing a high-density information recording carrier according to the present invention will be described in detail below with reference to embodiments shown in the drawings.

FIG. 1 is an explanatory diagram showing a cross section of a high-density information recording carrier manufacturing apparatus according to the present invention.

The upper mold 11 is made of a material that transmits ultraviolet light, specifically, ultraviolet-transparent glass or ultraviolet-transparent plastic.

Reference numeral 1 denotes a lower mold, which is fixed to a base or the like (not shown), and a stamper 31 having a signal to be formed can be attached to the upper surface of the lower mold.

Further, 21 is an ultraviolet lamp, which is located above the upper mold 11.

The injection molding space created by bringing the upper mold 11 and the lower mold 1 into close contact as described above is injected and filled with ultraviolet curable resin, and is cured by irradiating ultraviolet rays from an ultraviolet lamp 21 through the upper mold 11, This molds a record carrier onto which the stamper's signals are transferred.

First, the stamper 31 of the present invention will be described. As shown in cross section in FIGS. 1 and 3, the thickness t of the stamper is uniform in all parts, and a recess 32 is formed by an annular outer peripheral wall 35. A concave and convex information signal 33 is carved concentrically or spirally on the bottom of the recess 32, and a truncated cone-shaped protrusion is formed in the center of the bottom of the recess 32 to form a rotation hole for the disk. The portion 34 protrudes. The upper surface 38 of this convex portion 34 and the upper surface 3 of the outer peripheral wall
9 is on the same level as wall surface 3 of convex portion 34.
6 and the inner wall surface 37 of the outer peripheral wall 35 are tapered so that the lower part of the recess 32 is lower than the upper part.
Its diameter is reduced so that the depth d ₁ of the recess 32 is the same as the thickness of the disk to be manufactured.

By adopting such a configuration, the recess 32 becomes a completely negative type with respect to the shape of the disk to be manufactured, and by simply filling the recess with the disk material, not only the signal can be transferred and formed, but also a perfect disk shape can be formed. It is.

Also, when removing the disc from the stamper,
This is extremely easy because the wall surface is tapered, and furthermore, since the disc rotation hole is tapered during playback, it is easy to locate the center using the chuck member.

Next, a process for producing a stamper having a distinctive shape as described above will be described.

As shown in FIG. 4a, a copper plate 4 is used as the master 41.
2 and a stainless steel plate 43 are bonded together, and then the surface of the copper plate is polished to a smooth surface, and a copper layer 45 is provided on this surface by copper sulfate plating. Here, both the copper plate and the stainless steel plate preferably have a thickness of about 1 mm, and the thickness of the copper layer is preferably about 60 to 70 μm. Note that the stainless steel plate 43 is effective as a reinforcing plate for the copper plate 42, and is significantly stronger against deformation than a case where only the copper plate is used. Further, as the adhesive 44, an epoxy adhesive or the like can be used.

Such a master 41 is attached to a cutting machine, and an information signal 46 is cut on the surface of the copper plating layer 45, and an annular groove 47 and a circular hole 48 are simultaneously cut in the outer circumference and the center.

This is shown in Figure 4b.

The annular groove 47 and the hole 48 are both tapered and cut to the same depth, and the annular groove 47 corresponds to the outer peripheral wall 35 of the stamper described above, and the hole 48
similarly corresponds to the convex portion 36, and the cutting depth corresponds to the disk thickness. What you need to be careful about here is:
After attaching the master 41 to the cutting machine,
It must not be removed until the signal 46, annular groove 47 and hole 48 have all been cut. This is because the stamper molds not only the signal but also the disc shape.
6. If the annular groove 47 and hole 48 are not completely concentric, when reproducing the molded disk,
This is because the image and audio will be disturbed.

After the information signal 46, the annular groove 47, and the hole 48 are cut into the master disc 41 in this way, a metal master 49 as shown in FIG. A stamper as shown in FIG. 3 is produced through the process.

As can be understood from the above explanation, the stamper according to the present invention is intended to form not only a signal but also a disk shape, and is extremely thin, so the lower mold 1 to which the stamper is attached has also been devised. has been done.

That is, as shown in FIGS. 1 and 2, the top surface shape of the lower mold 1 is made the same as the back surface shape of the stamper 31, and when the stamper 31 is attached to the lower mold 1, the two are configured to be in complete contact with each other. ing. That is, an outer peripheral wall 5, a recess 3 surrounded by the outer peripheral wall 5, and a truncated cone-shaped projection 4 located at the center of the recess are formed corresponding to the shape of the back surface of the stamper, and the dimensions of each part are d' and l. ′, m ₁ ′, m ₂ ′, n ₁ ′, and n ₂ ′ are approximately the same as the dimensions d ₂ , l, m ₁ , m ₂ , n ₁ , and n ₂ of the corresponding parts of the stamper.

Furthermore, a stamper attachment member 8 for attaching a stamper 31 is installed at a position outside the outer circumferential wall 5 on the upper surface of the lower mold 1.

Further, a large number of holes 9 for vacuum suction are opened in the upper surface 2 of the lower mold 1, and although not shown, the holes 9 are connected to a blower or the like to enable vacuum suction.

As a result, compared to the case where the stamper 31 is simply attached to the lower mold 1 using the stamper mounting member 8, there is no air pocket between the stamper 31 and the upper surface 2 of the lower mold, and the tightness is extremely improved. It becomes possible to manufacture a disk with good flatness and no distortion.

By configuring the lower die as described above, even if the stamper is made thin, it is securely fixed to the lower die, so the time required for making the stamper is shortened, and moreover, only a small amount of material is required for making the stamper. become.

Furthermore, the lower die 1 is equipped with a cooling mechanism. The ultraviolet curable resin used as the disk material hardens while undergoing crosslinking through radical polymerization, but the high-density information carrier formed by the heat of polymerization tends to shrink. Therefore,
The high-density information carrier will have distortion corresponding to the shrinkage, which will cause dropouts during playback. In order to prevent such defects, the lower mold is constantly cooled to minimize shrinkage due to polymerization heat during curing.

Specifically, a cooling pipe 10 may be provided in the lower mold 1 and cooling water may be passed through the pipe 10. In addition, cooling pipe 1
0 is a surface to which ultraviolet rays are irradiated, in other words, the pipes are arranged in an annular manner below the recess 3 at regular intervals so that the recess 3 is evenly cooled. Further, as shown in FIG. 2, if the cooling pipes 10 are arranged in two or more layers, the cooling efficiency can be further improved.

The lower mold 1 has the above-mentioned characteristics, and the upper mold paired with the lower mold 1 will be explained next.

The upper mold 11 is made of an ultraviolet-transmissive material (for example, glass, plastic, etc. that transmits ultraviolet rays) at least the portion facing the recess 33 of the stamper attached to the lower mold, and the ultraviolet rays from above the upper mold are passed through the upper mold. It is necessary to irradiate the recess 33.

In addition, the upper mold 11 has an ultraviolet curable resin injection hole 12.
This is connected from the outside of the upper mold 11 to the lower surface of the upper mold 11, and an injection hole is formed at the end of the injection molding space created when the upper mold 11 and the lower mold 1 are brought into close contact. It is preferable to provide it at a position where it opens. By setting like this, injection hole 1
The installation of item 2 has almost no effect on the irradiation of ultraviolet rays into the injection molding space.

A nozzle is connected to the external opening of the injection hole 12, and although this nozzle is not shown, it communicates with a raw material hopper in which ultraviolet curable resin is stored.

In addition, the upper mold 1 has an air vent hole 13 and this hole 1.
A valve device 14 for opening and closing 3 is provided. 1st
As shown in the figure, the air vent hole 13, like the injection hole 12, opens at the end of the injection molding space on the lower surface of the upper mold, and is bent laterally to communicate with the outside.

The valve device 14 utilizes the bending of the hole 13, and opens and closes the hole 13 by vertical movement of a piston 15 connected to a drive unit 16 such as an air cylinder or solenoid above the upper die. Further, the air vent hole 13 is connected to a vacuum pump or the like to enable vacuum suction.

By providing such an air vent hole 13 and the valve device 14, the piston 15 can be moved upward to open the injection molding space before resin injection.
When the vacuum state is created by vacuum suction, the piston 15 is lowered, the valve is closed, and resin is injected. There is almost no air resistance and even the minute parts of the stamper 31 are injected. The easy and rapid penetration allows disks without air pockets to be manufactured.

Furthermore, the entire surface of the resin injection hole 12 described above is covered with an ultraviolet blocking material.

This is the upper mold 1 after injection molding space is filled with resin.
1. When UV rays are irradiated from above through the upper mold 11 to cure the resin, if the resin remaining in the injection hole 12 is also cured at the same time, it will not only block the injection hole but also cause damage to the manufactured disk. This results in the formation of "belly", which causes undesirable conditions such as uneven rotation during playback.
Therefore, by covering the injection hole 12 with the ultraviolet blocking material in this manner, ultraviolet rays are blocked and the resin within the injection hole 12 is prevented from curing, thereby solving the above-mentioned problems.

Specifically, it is preferable to perform metal vapor deposition 17 (for example, Al, Cr, etc.) on the inner surface of the injection hole 12. Alternatively, a metal tube may be inserted. Thereby, only the injection hole 12 can be completely shielded from ultraviolet rays.

Furthermore, the lower surface of the upper mold 11 (the surface facing the lower mold)
It is preferable to provide a plastic layer 18 which is transparent to ultraviolet rays and has elasticity. That is, even if the stamper 31 is attached to the lower die 1 and the upper die 11 is brought into contact with it under a certain pressure, it is difficult to achieve complete contact, and burrs are likely to occur on the outer periphery and center of the injection-molded disk.

When such a disc is reproduced, the center position accuracy deteriorates, leading to large eccentricity and extremely poor image stability.

However, as described above, by interposing the plastic layer which transmits ultraviolet rays and has elasticity, the stamper 31 and the upper die 11 are in perfect contact with each other, and no burrs are generated.

The plastic material used here is preferably polypropylene, polyester, etc., and the method for forming such plastic on the lower surface of the upper mold 11 is preferably by a normal coating method such as roll coating. is preferably in the range of 5 to 50 μm.

In addition, if flatness of the back surface of the disk is required, it is preferable to provide a plastic layer only on the parts where the upper mold 11 and the stamper 31 directly contact, that is, the parts corresponding to the center part and the outer diameter part. Since the back surface of the disk is directly formed by the lower surface of the upper mold 11 made of glass or the like, extremely good flatness can be obtained. At this time, a plastic layer may be provided on the upper mold 11 side, and the stamper 3
Exactly the same effect can be obtained even if a plastic layer is provided on the upper surface of the first convex portion 34 and the outer peripheral wall 35.

Note that the ultraviolet lamp 21 located above the upper mold 11 is preferably covered with a concave mirror 22 in order to increase its irradiation efficiency, and a shutter 23 is interposed between the ultraviolet lamp 21 and the upper mold 11 to By opening and closing the lamp 23 to adjust the amount of ultraviolet irradiation and turn on/off the ultraviolet irradiation, the amount of light will be stabilized and the life of the lamp will be extended.

Next, a process for manufacturing a high-density information recording carrier using the apparatus as described above will be explained.

As shown in FIG. 1, the stamper 31 is attached to the lower mold 1 using the attachment member 8, and the stamper 31 is tightly fixed by vacuum suction. Thereafter, the upper die 11 and the ultraviolet irradiation device 21 are lowered, and the upper die 11 and the lower die 1 are brought into contact with each other with appropriate pressure, so that the recess 32 of the stamper 31 becomes a disk molding space having a disk shape. After that, the valve device 14 is operated to open the air vent hole 13 and suck the vacuum,
The disk molding space is brought into a vacuum state, and when the vacuum is sufficiently created, the valve device 14 is operated to close the air vent hole 13. At this time, the tip of the piston 15 is made flush with the lower surface of the upper die 11. In this state, an ultraviolet curing resin, which is a disc material, is injected into the disc molding space from a nozzle through the resin injection hole 12. When the disk molding space is sufficiently filled with the ultraviolet curable resin and the details have been reached, injection of the resin from the nozzle is stopped, the shutter 23 is opened, and ultraviolet rays are irradiated. The ultraviolet curable resin hardens approximately one second after being irradiated with ultraviolet rays, and the signal and disk shape are formed as well.

One process is completed by closing the shutter 23, raising the upper die 11 and the ultraviolet irradiation device 21, and taking out the disk on which both the signal and the outer shape have been molded from the stamper 31.

As described above, according to the present invention, high-density information signal recording carriers such as video disks can be manufactured in an extremely short time, and since only ultraviolet rays are irradiated, energy consumption is low and moldability is significantly improved. It is something to do.

[Brief explanation of the drawing]

The drawings show embodiments of the present invention, and FIG. 1 is an explanatory diagram showing a cross section of a manufacturing apparatus for a high-density information recording carrier of the present invention, and FIG. 2 is an explanatory diagram showing a cross section of a lower die of the present invention. 3 are explanatory diagrams showing a cross section of the stamper of the present invention, and FIG. 4 is an explanatory diagram showing the manufacturing process of the stamper shown in FIG. 3. 1... lower mold, 9... vacuum suction hole, 11...
... Upper mold, 21 ... Ultraviolet irradiation device, 31 ... Stamper.

Claims (1)

[Claims] 1. The material of the high-density information recording carrier to be produced is an ultraviolet curable resin, a first mold to which a stamper can be attached, and a second mold made of a material that transmits ultraviolet rays.
and an ultraviolet lamp located outside the second mold, and the resin is injected into the molding space created when the first mold and the second mold are brought into contact under a certain pressure. In an apparatus for manufacturing a high-density information recording carrier, which is formed by filling the molding space with ultraviolet light and curing the resin by irradiating the molding space with ultraviolet rays, a ring-shaped outer peripheral wall and a A convex portion is formed in the center to form a concave portion to be the molding space in the stamper itself, and the stamper attachment surface of the first mold is made to have the same shape as the back surface of the stamper, and the stamper is attached to the first mold. A manufacturing device for a high-density information recording carrier, characterized by closely fixing a stamper. 2. The apparatus for manufacturing a high-density information recording carrier according to claim 1, wherein the outer circumferential wall of the stamper and the wall of the convex portion are sloped surfaces. 3. The apparatus for manufacturing a high-density information recording carrier according to claim 1, wherein the upper surface of the outer circumferential wall of the stamper and the upper surface of the convex portion are on the same level. 4. The high-density information recording according to claim 1, characterized in that a plurality of vacuum suction holes are opened in the stamper mounting surface of the lower mold to improve the close contact between the stamper and the lower mold. Carrier manufacturing equipment.