SE438568B - OPTIC READABLE INFORMATION DISC, INCLUDING A TRANSPARENT INFORMATION DISPLAY WITH A RADIATOR REFLECTING OPTICAL STRUCTURE - Google Patents

Description

7809614-6 2 in a plane, whereby the reflection coefficient of the blocks differs from the reflection coefficient of the middle surfaces. Preferably, the optical structure consists of small blocks and intermediate surfaces with the same coefficient of reflection, the blocks and the intermediate surfaces being located at different levels. Thus, a crenellated structure of the information track is obtained with a difference in height between the blocks and the intermediate surfaces of approximately 0.5 .mu.m. The information groove may be helical or be formed by concentric circles.

The radiation-reflecting optical structure is read on reflection by means of a focused light beam, in particular a laser light beam.

Plastic information discs with a one-sided reflective optical structure can be mass-produced using matrices. Different methods can be used, e.g. a pressing process which is described, inter alia, in Dutch patent application 7212045. Another known method is an injection molding process or a casting process. ' German Explanatory Note 2343020 describes e.g. a casting process in which a liquid polyurethane resin with a polyester substrate thereon is applied to a matrix of silicon rubber. After curing the urethane resin, the substrate with the associated cured polyurethane layer is removed from the matrix surface. Another method of production is the so-called the printing process in which a thermoplastic film is provided with the desired optical structure by a treatment with a rotating matrix such as e.g. is mounted on a roll.

The resulting information discs are then provided on the side of the optical structure with a radiation reflecting layer, e.g. a layer of metal or a layer of a selenide dielectric. A suitable radiation-reflecting layer is e.g. a layer of aluminum, silver or gold applied by vapor deposition or by electroplating. To protect the radiation-reflecting layer from chemical and mechanical attack, a protective layer of plastic is applied to it.

This is usually a layer of lacquer, but according to the mentioned patent application 7211999 it can alternatively be a thin sheet or a thin foil with an adhesive.

Another known method for producing information discs, which are unilaterally provided with a reflecting optical structure, is based on a disc-shaped substrate on which a reflecting layer is vapor-deposited via a perforated mask. Thus, no matrix was used in this method. Alternatively, instead of a vapor deposition process, an etching process may be used in which a layer of photoresist applied to a metal layer is exposed to light via a mask and developed, after which the exposed portions of the metal layer are etched away. These latter methods are considered less suitable for series production.

Attempts have also been made to eliminate the said disadvantage of reducing the quality of the optical structure by making such improvements in the manufacturing technique that the compressive stress and the thermal load to which the synthetic resin is subjected are minimized. It has e.g. It has been proposed to heat only the top layer of the synthetic resin in which the information structure is to be applied during the pressing process and the printing process.

However, all these attempts have not led to optimal results. According to the present invention, an optically readable information disc has been produced, which does not have the said disadvantage.

More particularly, the invention relates to an optically readable information disc of the type initially described, which is characterized in that the cover plate is a flat, rigid, heat-conducting plate which is made of inorganic material and connected to the information carrier over its entire surface.

The novelty of the information disc according to the invention is based on the following.

The invention is based on the view that the reduced quality of the information disc is mainly due to microstructural forces, i.e. forces acting on a very small surface part of the disc and which are released when reading the disc by means of laser light.

The laser light beam, which focuses on the optical structure of the information disc, will pass the transparent synthetic resin without appreciable light energy loss and will then be reflected by the radiation-reflecting layer. Depending on the reflection coefficient of the reflective layer used - usually a metal layer - more or less light energy will be absorbed by the reflective layer. The absorbed light energy is converted into thermal energy and as a result the temperature in the layer will increase locally, which in turn generates a local heating of the part of the optical structure which is in contact with the reflecting layer. Many internal stresses occur in the part of the information carrier that contains the optical structure. In connection with this, it is to be observed that in the described production of plastic information carriers, which are unilaterally provided with an optical structure, a thermal stress and a compressive stress are exerted on the thermoplastic material being treated. This becomes all the more pronounced in a pressing or printing process in which the optical structure is applied to an inverted thermoplastic synthetic resin under pressure and by means of a matrix.

Cooling is then performed, freezing the internal stresses introduced into the material under the influence of pressure and heat. Such internal stresses often occur in particular in the part of the synthetic resin where the deformation is maximum, in other words in or near the optical structure.

Internal stresses are also present in the information carriers which are manufactured according to methods for producing plastic information carriers, in which no high pressures or high temperatures are used. In this context, reference is made to Dutch patent application 7611395. The process described here is based on a liquid varnish which can be cured with light, e.g. ultraviolet light, and which is spread over the information-bearing surface of a metal matrix. A transparent plastic sheet is then applied over the paint, which is then exposed to light via the plastic sheet and cured, after which the unit of the plastic sheet and the information-bearing cured lacquer layer, which is connected thereto, are finally removed from the matrix surface.

The plastic information carrier thus produced also exhibits internal stresses, in particular in the plastic sheet, which during its production e.g. with a spraying process, has also been subjected to a pressure and heat treatment.

As has already been stated, a very local heating of the plastic information carrier has rm in or near the optical structure when the information carrier is exposed to laser light. The turned-up surface is very small, of the order of microns. The stresses present in the heated part of the information carrier are released and the forces which result from this produce a defonation even if it is small. Considering the detail of the optical structure, this results in errors in the stored information to be read.

By using a friend-conducting plate according to the invention, the energy absorbed by the reflective layer when irradiating the optical structure with laser light will largely flow to the friend-conducting plate so that no appreciable increase in temperature will occur at the site of the irradiated surface. Consequently, the information carrier and in particular the optical structure thereof will not be heated, so that no internal stresses are released.

In addition to the microstructural forces described above, macrostructural forces also occur which act over a larger area of the plastic information carrier. These are in particular forces which can be said to be a result of a one-sided absorption or release of moisture by the information carrier and which result in bending of the carrier. A comparatively small bending over a large area of the plate will usually have no direct effect on the information being read, since the lens focusing the laser light can keep the gradually varying distance to the optical structure within the focal length, which is a few microns, by a compensatory gradual displacement of the lens. However, in the case where the carrier bends sharply along a small distance, the lens can no longer follow the varying position of the optical structure on reading and the information carrier fl is no longer optically readable.

The flat rigid heat-conducting plate included in the information disc according to the invention can absorb the above-mentioned forces without deformation of the plate taking place. than the information disc according to the invention will not bend. The information disc according to the invention gives good results, especially if the flat, rigid heat-conducting plate is a metal plate or a glass plate with a thickness of 0.2 - 2 mm. Due to the very good thermal conductivity and also the high thermal capacity, a plate made of metal, such as nickel, steel or aluminum, is preferred. 7809614-6 This applies in particular to an aluminum plate with a thickness of 0.3 to 1.3 mm. | another favorable embodiment of the information disc according to the invention is the side of the flat plate facing away from the information carrier provided with a second transparent plastic information carrier which on one side has a radiation-reflecting optical structure, wherein said radiation-reflecting optical structure of said second carrier structure is connected to the flat plate over its entire surface by means of an adhesive.

This results in an information disc that has information on two pages and has twice the amount of information or in other words has a double playing time.

In addition, the additional advantage is obtained that there is a fairly high probability that the macrostructural forces which can occur in the information carriers located on both sides of the flat plate at least partially compensate each other. In this context, it is observed that life surveys under extreme atmospheric conditions have shown that such an information carrier remains completely flat if a comparatively thin aluminum plate of 0.5 mm was used in it.

The adhesive used in the method according to the invention is of conventional type, e.g. a two-component adhesive. In an advantageous embodiment, a radiation-curable lacquer is used, e.g. an acrylic acid-curable varnish based on ultraviolet radiation. The thin liquid varnish can be easily applied to one of the surfaces to be connected, e.g. by means of a spraying process or a centrifugation process, i.e. either on the information-bearing surface of the information carrier or on the flat, rigid heat-conducting plate. Rapid curing of the varnish is possible by exposure via the transparent information carrier. It has been found that the radiation-reflecting layer, which in particular reflects within the infrared region, still transmits sufficient short-wave light, e.g. ultra-violet light.

Optionally, the flat, rigid thermally conductive plate used may be provided with reinforcing ribs on the side facing away from the information carrier.

An information carrier and a plate can also be used, both of which have a central hole so that the resulting information disc also has a central hole.

The invention is described in more detail with reference to the drawing, where Fig. 1 shows a cross section through a plastic information carrier included in the information disc according to the invention, Fig. 2 shows a cross section through an information disc according to the invention and Fig. 3 shows a cross section through another embodiment. in the form of an information disc according to the invention.

Reference numeral 1 in Fig. 1 denotes a transparent plastic information carrier with an optical structure 2 on one side. The information carrier 1 with the optical structure 2 has a thickness of approximately 1 mm and is made of transparent polyvinyl chloride / acetate copolymers according to a known pressing process. The optical structure is crenellated and consists of small beams 3 with surface areas 4 whose dimensions are in the order of 1 / u. The optical structure 2 is covered with a vapor-deposited radiation-reflecting aluminum layer 5, approximately 300 Å thick.

On the side of the optical structure 2, the information carrier 1 is provided with a 0.5 m thick aluminum plate 6 (Fig. 2) using a layer of adhesive (not shown), e.g. a two-component adhesive.

The resultant information disc is shown in Fig. 2. The disc is read optically and by reflection with a laser light in the direction indicated by a pi1.

Reference numeral 7 in Fig. 3 denotes a 0.5 mm thick aluminum plate which on both sides is provided with piast information carriers which are denoted by 8 and 9, respectively. The information carriers 8 and 9 correspond to that shown in Fig. 1 and are provided on one side with a optical structure 10,11 which is covered with a vapor-deposited aluminum layer applied by vapor deposition. The information carriers 8,9 are connected to the plate 7 on the side of the optical structure 10,11 with an adhesive (not shown). The information disc shown in Fig. 3 is read from both sides in directions indicated by piïs. The thickness of the plastic information carriers 1 (Figs. 1 and 2) and 8.9 (Fig. 3) (approximately 1 mm) is sufficient to keep dust particles or notches, which may be present on the surface, out of the focal length of the lens not shown, which focus in the the bundle of the optical structures 2 (Figs. 1 and 2) and 10.11 (Fig. 3).

Claims (5)

7809614-6 7 Patent claims An optically readable information disc comprising a transparent plastic information carrier (1) with a radiation-reflecting optical structure (2) on one side, which structure contains a crenellated information track of areas (3 and Ä) which are alternately located at a higher and lower level and a reflective layer (5), a cover plate on the side of the optical structure being connected thereto by means of an adhesive, characterized in that the cover plate is a flat, rigid, heat-conducting plate (6) made of inorganic material and connected to the information carrier ( 1) over its entire surface (Figs. 1 and 2). Optically readable information disc according to claim 1, characterized in that the flat plate (6) is a metal plate or a glass plate with a thickness of 0.2 to 2 mm. Optically readable information disc according to claim 2, characterized in that the flat plate (6) is an aluminum plate with a thickness of 0.3 to 1.3 mm. Ä. Optically readable information disc according to claim 1, 2 or 3, characterized in that the side of the flat plate (7) facing away from the information carrier (8) is provided with a second transparent plastic information carrier (9) which on one side has a radiation-reflecting optical structure (11), the radiation-reflecting optical structure (11) of said second carrier (9) being connected to the planar plate (7) over its entire surface by means of an adhesive (Fig. 3). Optically readable information disc according to claim 1, characterized in that the adhesive used is a radiation-curable lacquer.