DE2531562A1 - METHOD OF MANUFACTURING VIDEO FREQUENCY SIGNAL RECORDING DISCS - Google Patents

Description

75008 PARIS / France

Our reference: T 1821

Method of manufacturing video frequency signal recording disks

The invention relates to a method of manufacturing video frequency signal recording disks (hereinafter referred to as Video disks). In particular, the reproduction of television signals in the form of a disk is sought, the Bears embossing / which are engraved on a spiral track and optically read by a laser beam which is focused on the imprint when reading.

In particular, it is the technique of the translucent sheet known, on which information is engraved in the form of depressions, the width and depth of which are of the order of magnitude of a micrometer. These depressions generate phase shifts in the light wave, which are detected by special

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facilities to restore the information.

The duplication of the plates engraved in this way brings, if one wishes to use photogravure processes, a particular difficulty with itself. Because of the very small dimensions of the information "dots", diffraction phenomena occur which severely impair the quality of the reproduction .

The invention enables this difficulty to be overcome.

According to the invention there is a method of making a video frequency signal record in the form of plates bearing embossings engraved on a track characterized by the following steps:

a) recording a latent image of the embossments by a Process (laser beam or exposure to X-rays through a negative) which is not a photographic process is in a photosensitive Resin layer covering one side of a recording medium covered,

b) developing the image,

c) applying a layer of opaque material on the carrier, and

d) removing the remaining resin and the opaque one Material only in the places where it covers the resin, by a solvent.

Further features and advantages of the invention emerge from the following description of exemplary embodiments Invention. The drawings each show in section a part of the information carrier in different stages of the Method according to the invention:

Fig. 1 shows the step of point-by-point recording

nens of signals in the form of latent

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Images in a photosensitive

Resin layer,

FIGS. 2 to 4 show the three steps of a method

for the production of metallic dots from the latent images, and

Fig. 5 shows a step in the course of which a

Irradiation with X-rays takes place.

Fig. 1 shows in partial section a carrier 1, in which it is for example a circular plate made of polyethylene glycol terephthalate (commercially available under the registered trademarks Mylar or Terphane). The plate, which has a thickness of 70 µm to 300 µm, is covered with a layer 2 coated with photosensitive resin to a thickness of 3,000 to 4,000 angstroms.

If this resin is positive, the process that will follow to make the metallic dots will allow making a copy that can be read optically.

If this resin is negative, the use of the same process results in the manufacture of a mask with the substrate chosen being translucent. Such a mask can be used in the manner explained below .

Among the photosensitive materials which have given good results, there is SCHIPLEY AZ 1350 resin (registered trademark).

For point-by-point recording of the video frequency signals in the layer 2, a laser radiation beam, which is represented by a simple arrow 3, is on / off-modulated with the aid of these signals. This bundle is not shown by a

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set device focused on layer 2. The carrier 1 is set in motion (arrow 4) through which the carrier 1 is passed under the bundle 3 in such a way that a very dense spiral is described in the resin layer 2 will.

The steps that follow are applicable to any carrier which carries a photosensitive resin layer containing a latent image formed in the resin by exposure radiation has been formed at predetermined points.

1) Development which continues until the support is exposed (Fig. 2).

By acting on an agent to develop the photosensitive resin used (which in the case of the resin SCHIPLEY AZ 1350 is basic), depressions such as the one shown in FIG. 2 are formed Depression 20. The base 201 of the depression 20 allows the surface of the carrier 1 to protrude.

2) Deposit a thin metal layer (Fig. 3).

By vacuum evaporation in a device of known type a uniform metal layer of thickness "h" is applied. As shown in Fig. 3, this thickness is less than the thickness "e" of the starting resin layer, i.e. less than the depth of the Well 20. Under these conditions there is between a cuboid 30, which fills a well, and the adjacent parts 41 and 42 of the metal layer, which is increased by the resin, a distance 31. This distance is used in the following step to remove the resin covered with metal. The one chosen for this step Metal is either copper or chromium or rhodium, the latter being excellent in durability against atmospheric corrosion agents.

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The thickness "h" of the metal layer is, for example 1500 angstroms when the thickness "e" of the starting resin is 3000 to 4000 angstroms. The vacuum evaporation process is suitable good for the precise production of such layers.

3) Elimination of the excess metal (Fig. 4).

At the end of the previous step, the support is treated with a solvent such as acetone, which is able to dissolve the resin. The resin layer located between the cuboids 30 is removed and takes away the metal that covered it.

As a modification of the method which combines the three above-mentioned steps, the same operations are carried out but a metal thickness "h" is deposited which is equal to the thickness "e" of the resin. Experience shows, that the action of the solvent in the third step enables the same result to be achieved, while the Cuboid 30 and their adjacent parts 41 and 42 have a common edge made of metal.

This modification makes it possible to produce a negative copy of a recessed embossing which can serve as a template. By Hot-pressing the negative copy on a plate made of thermoplastic material could be the duplicate of the in Fig. 2 produce the carrier shown.

Fig. 5 shows a method of irradiation with X-rays (band of 4 to 14 Angstroms). The irradiated vehicle is for example, the same as in Fig. 1 with the same resin layer. A mask 40 that corresponds to the code of the embossing of Fig. 2 is perforated (it is assumed that the cut is made along the recording track) is in a distance "d" which is as small as possible from the resin layer to avoid possible parallelism errors an X-ray beam 50 to eliminate. The thickness "a"

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the mask is chosen to be as small as possible without making the mask too fragile (namely some Ten angstroms in the case of a mylar mask).

The mask 40 can be produced by the preliminary step of the method according to the invention (point-by-point recording by a laser beam) is applied to a transparent substrate whose thickness satisfies the above condition Fulfills"

A mask made by any other known method can also be used within the scope of the invention has been.

The production of information elements with the help of small areas from a material, which the light waves absorbed, is also within the scope of the invention. The absorbent material can be a layer of carbon or made of a manganese alloy such as MnBi.

The method for producing absorbent areas is analogous to that described above. The layer of the Step c, however, is generally not performed by vacuum evaporation but, for example, by cathode sputtering manufactured.

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Claims (6)

Patent claims: Method of making a video frequency signal record in the form of plates bearing embossings engraved on a track, characterized by the following steps: a) Recording a latent image of the embossments by a process (laser beam or exposure to X-rays through a negative), which is not a photographic process, in a light-sensitive one Resin layer covering one side of a recording medium, b) developing the image, c) applying a layer of opaque material to the support, and d) removing the remaining resin and the opaque one Material only in those places where it covers the resin, by a solvent. 2. The method according to claim 1, characterized in that the recording in step (a) is made with X-rays whose wavelength is between 4 and 14 Angstroms. 3. The method according to claim 1, characterized in that the layer of opaque material is less thick than the resin layer. 4. The method according to claim 1, characterized in that the layer of opaque material is thicker than the resin layer is. 5. The method according to any one of claims 1 to 4, characterized in that that the opaque material is metallic. 6. The method according to any one of claims 1 to 4, characterized in that that the opaque material is absorbent. 509886/0405