CH637783A5 - METHOD FOR PRODUCING AN OPTICALLY READABLE DATA DISK USING A FLAT-STiffening HEAT-CONDUCTING PLATE FROM INORGANIC MATERIAL. - Google Patents

Description

The invention relates to a method for producing a protective layer made of plastic. Mostly there is an optically readable data disc in which this layer is a lacquer layer, but it can be

Data carrier made of transparent plastic, which also contains a radiation-reflecting optical structure on one side of the Dutch patent application 7211999, on which a thin plate or film provided with an adhesive can be the side of the optical structure with the aid of an adhesive.

is provided with the cover plate connected to it. Another known method of manufacturing on a

Such a method is known from the Dutch patent application 7211999, which was laid on March 5, 1974 and has a reflective optical structure on the open side. Data disks are based on a disk-shaped substrate (PHN. 6493). on which a reflective over a mask provided with openings

The known method has the disadvantage that the 45 layer is evaporated. Here, therefore, no optically readable die produced using this method is used. Instead of an evaporation process, too

Long-term data slices errors or deviations are applied in an etching process, one of which points to one of the optical structures, whereby the quality of the metal layer applied photoresist layer is exposed and developed via a stored mask, such as image or sound data, after which the is exposed. 50 parts of the metal layer can be etched away. The latter sales

The previously produced optically readable and from one drive are less suitable for mass production than existing plastic data disks show all consider.

the aforementioned disadvantage. Many other attempts have been made to address the aforementioned disadvantage of

Attempts have been made in this regard to improve the deterioration in the quality of the optical structure, in particular by eliminating special plastic composites that have been sought in the improvements that have been made over a long period of time and in the lung technique Art under changing climatological conditions the fabric pressure and heat load is minimal. The desired great stability of a plastic data disk was proposed, in the pressing and printing process, because of the great delicacy of the data structure, only the upper layer of the plastic, in which the data requirements have to be set, is very strict. This structure consists of 60 structure that needs to be attached to heat.

mostly, as also in the aforementioned patent application. However, all these attempts have not described the desired result from radiation reflection results arranged in traces. The invention has developed a method for Hertzing areas of very small dimensions, in the large position of optically readable data disks, the order of um. These areas are e.g. does not have one and the aforementioned disadvantage.

Blocks and intermediate areas lying on the same level, whereby the present invention relates to a method of reflection coefficient of the blocks of that of the intermediate type mentioned in the introduction, which is characterized, is different. Preferably, the optical structure is that the cover plate is a flat stiffening heat-conducting door made of blocks and intermediate areas with the same reflect plate, which is made of inorganic material and

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is connected to the data carrier over the entire contact area.

This characteristic measure in the method according to the invention is based on the following knowledge on which the invention is based: 5

According to the applicant, the deterioration in the quality of the data disk is largely due to microstructured forces, i.e. attributable to forces that act on a very small surface part of the data disk and that are released when the disk is read out with the aid of laser light.

The laser light beam focused on the optical structure of the data disk will pass through the data carrier made of transparent plastic without any appreciable loss of light energy and will then be thrown back by the radiation-reflecting layer. Depending on the reflection coefficient of the reflective layer used, which is generally a metal layer, more or less light energy will be absorbed by the reflective layer. The absorbed light energy will thereby increase locally, which in turn results in local heating of the part of the optical structure lying on the reflecting layer. There are many internal tensions in the part of the data carrier that contains the optical structure. In this context, it should be noted that in the above-described production of plastic data carriers which are provided with an optical structure on one side, a thermal and pressure load is exerted on the thermoplastic material to be processed. This applies in particular to a press or print process, in which the optical structure is applied in a heated thermoplastic under pressure and with the help of a die. Cooling then takes place, the internal stresses introduced under the influence of pressure and heat being frozen into the material. Such internal stresses are mostly present in the part of the plastic in which the deformation is at a maximum, in other words in or near the optical structure.

Even in processes for producing a plastic data carrier, in which no increased pressure or high temperature is used, there are internal tensions in the data carrier produced. In this connection, reference is made to the German patent application P 274479.7. The process described therein starts with a liquid lacquer curable with light, such as ultraviolet light, which is spread over the data-carrying surface of a metal die. A sheet of transparent plastic is then placed over the paint,

after which the lacquer is exposed via the plastic plate, hardened and finally the structure of the plastic plate and the hardened lacquer layer containing the data connected to it is removed from the die surface.

The plastic data carrier produced in this way also has internal stresses, particularly in the plastic plate, which e.g. has also been subjected to a pressure and heat treatment by means of an extrusion process.

As mentioned above, when the data disk is irradiated with laser light, the plastic data carrier is heated very locally in or near the optical structure. The heated surface is very small, on the order of microns. The voltages present in the heated part of the data carrier are released and the resulting forces will cause a deformation, albeit with small dimensions, in the optical structure. With regard to the delicacy of the details of the optical structure, this leads to errors in the stored and read-out data.

By using a heat-conducting plate, when the optical structure is illuminated with laser light, most of the energy absorbed by the reflecting layer will flow off to the heat-conducting plate, so that there will be no appreciable increase in the temperature of the reflecting layer at the location of the irradiated surface. The data carrier, and in particular its optical structure, is therefore not heated, so that no internal voltages are triggered.

In addition to the microstructured forces described above, macrostructured forces also occur which are effective over a larger surface of the plastic data carrier. These are, in particular, forces that can be attributed to one-sided moisture absorption or release of moisture from the data carrier and that cause the data carrier to bend. A comparatively slight warping over a large surface will generally not have a direct unfavorable influence on the data to be read out, because the lens that focuses the laser light, the gradually changing distance from the optical structure, possibly through a compensating, even displacement of the lens within the Depth of field, which is a few microns, can hold. In the event of a strong curvature over a smaller distance, the lens can no longer follow the changing position of the optical structure when reading out and the data carrier can no longer be read out optically.

The flat stiffening heat-conducting plate used in the method according to the invention can absorb the aforementioned forces without the plate being deformed.

The invention also relates to a data disc which was produced by the method according to the invention. Such a data disc manufactured in accordance with the invention will not bend.

With the method according to the invention, particularly favorable results are achieved if a metal plate or glass plate with a thickness of 0.2 to 2 mm is used as the flat stiffening heat-conducting plate. Because of the very good heat conduction and also the very large heat capacity, a plate made of metal, such as nickel, is preferred.

Steel or aluminum.

This is especially true for an aluminum plate with a thickness of 0.3 to 1.3 mm.

In a further favorable embodiment of the method according to the invention, the side of the flat plate facing away from the data carrier is provided with a second data carrier made of transparent plastic, which contains a one-sided radiation-reflecting optical structure, said side of the flat plate being provided over the entire surface with the aid of an adhesive is connected to the radiation-reflecting optical structure of the data carrier.

In this way, a double-sided data disc is obtained which contains twice the amount of data, or in other words has a double playing time. In addition, the further advantage is obtained that there is a fairly large possibility that the macrostructured forces which can occur in the data carriers lying on both sides of the flat plate are at least partially balanced. In this connection it should be noted that endurance tests under extreme atmospheric conditions have shown that such a data disk remains completely flat when a relatively thin aluminum plate of 0.5 mm is used therein.

The adhesive used in the method according to the invention is of a common type, e.g. a two-component adhesive. In a favorable embodiment, a radiation-curable lacquer, such as e.g. a UV-curable lacquer based on acrylic acid esters, who used

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the. The low-viscosity lacquer can easily e.g. by means of a spraying process or a centrifuging process on one of the surfaces to be connected, i.e. either on the data-containing surface of the data carrier or on the flat stiffening heat-conducting plate. The varnish can be quickly cured by exposure to the transparent data carrier. It has been found that the radiation-reflecting layer, which primarily reflects in the infrared range, still allows a sufficient amount of short-wave, such as ultraviolet light, to pass through.

The flat stiffening heat-conducting plate used can, if desired, be provided with stiffening ribs on the side facing away from the data carrier. A data carrier and a disk can also be used, both of which have a central opening, so that the data disk obtained has a central centering opening.

The invention will now be explained in more detail with reference to the drawing, for example. Show it:

1 shows a cross section through a plastic data carrier used in the method,

Fig. 2 shows a cross section through a data disc obtained according to the invention, and

Fig. 3 shows a cross section through another embodiment of a data disc obtained according to the invention.

In Fig. 1, 1 denotes a transparent plastic data carrier, which is provided on one side with an optical structure. The data carrier 1 with the optical structure 2 has a thickness of approximately 1 mm and is made of transparent polyvinyl chloride / acetate copolymer according to a method known per se

Press process manufactured. The optical structure 2 is rectangular and consists of blocks 3 with intermediate areas 4, the dimensions of which are of the order of 1 μm.

The optical structure 2 is covered with a vapor-deposited radiation-reflecting aluminum layer 5, which is approximately 300 μm thick.

The data carrier 1 is provided on the side of the optical structure with a 0.5 mm thick aluminum plate 6 (FIG. 2) using a layer, not shown, of an adhesive, such as a two-component adhesive.

The data slice obtained is shown in FIG. 2. The disc is read optically and in reflection with laser light in the direction indicated by an arrow.

In Fig. 3, 7 denotes a 0.5 mm thick aluminum plate 15, which is provided on both sides with a plastic data carrier, which is designated 8 and 9, respectively. The data carriers 8 and 9 correspond to those according to FIG. 1 and are provided on one side with an optical structure 10, 11, which is covered with a vapor-deposited aluminum layer (not shown). The data carriers 8, 9 are connected to the plate 7 on the side of the optical structure 10, 11 with the aid of an adhesive (not shown). 3 is read out on two sides in the direction indicated by arrows.

25 The thickness (about 1 mm) of the plastic data carrier 1 (Figures 1, 2) and 8.9 (Fig. 3) is sufficiently sufficient to keep dust particles or scratches on the surface outside the depth of field of the lens, not shown, that the readout beam is focused on the optical structures 2 3o (FIGS. 1, 2) and 10, 11 (FIG. 3).

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Claims (6)

637 783 1. Process for producing an optically readable different levels. Then a rectangular data disc, in which a data carrier of transparent structure contains the data track with a height difference between plastic, which on one side contains radiation-reflecting blocks and intermediate areas of approximately 0.5 (im. The optical structure (2), on the side the optical structure 5 data track can be spiral or made up of concentric tur with a circle connected to it with the aid of an adhesive. Cover plate is provided, characterized in that the radiation-reflecting optical structure with cover plate (6) is a flat stiffening heat-conducting plate with the help of a focused light beam, in particular by laserists, which is made of inorganic material and is read out via the light in reflection. Whole contact area with the data carrier (1) with this io plastic data disks, which is connected to one side. reflective optical structure can be provided 2. The method according to claim 1, characterized in that using matrices in the mass who-that the flat plate is a metal plate or a glass plate. Various methods can be used, with a thickness of 0.2 to 2 mm. such as. a pressing process that i.a. in the disclosed never- 2nd PATENT CLAIMS xions coefficients, with the blocks and intermediate areas on 3. The method according to claim 2, characterized in 15 of the Dutch patent application 7212045 (PHN. 6519) that the flat plate is described as an aluminum plate with a thickness. Another known method is one from 0.3 to 1.3 mm. Injection molding or casting process. So in the German Open 4. The method according to any one of claims 1 to 3, characterized in reference 2.443.020 mentions a casting process, characterized in that a liquid polyurethane resin side of the flat plate (7) with a second data carrier is removed from the data carrier (8) on a silicone rubber matrix (9) 20 with a polyester substrate mounted thereon. After it is made of transparent plastic which contains a hardened urethane resin, the substrate with the radiation-reflecting optically bonded hardened polyurethane layer attached to it is removed from the matrix structure, the said side of the flat plate removing the surface. Another manufacturing process is that over the entire contact area with the help of another so-called print process, in which a thermoplastic adhesive with the latter radiation-reflecting film by treatment with a rotating e.g. is connected to an optical structure of the data carrier. Roller arranged die with the desired optical 5. The method according to claim 1, characterized in that the structure is provided. that a radiation-curable lacquer is used as an adhesive. The data discs obtained are then turned over on the side. the optical structure with a radiation reflecting 6. Optically readable data disc, produced after the 30 layer, such as a metal layer or a layer formed by a Sele method according to one of Claims 1 to 5. A suitable radiation reflecting layer is e.g. a vapor-deposited or electroless aluminum, silver or gold layer. In order to protect the radiation-reflecting layer from chemical and mechanical attack, this is done