NL1002768C2 - System to produce holographic image on a substrate - Google Patents

Abstract

The interference pattern is created as a microscopic relief in a thin layer of transparent thermoplastic material (2). During creation of the image, the layer is attached to a temporary carrier (3) by a separation layer (4). The temporary carrier is made from paper or polyester film. The final substrate (12) is a sheet of paper, card or plastic onto which a thin upper cover of nickel foil (11) has been glued. The outer surface of the thermoplastic layer is "rolled" over the nickel foil surface, to which it adheres. As the temporary carrier moves away from the final substrate, the rear face of the thermoplastic material (2) separates from the separation layer (4).

Description

Image carrier provided with an interference pattern as well as a method of manufacturing it.

The present invention relates to an image carrier comprising a substrate with an image layer disposed thereon in which an interference pattern, in particular a holographic image, is provided in the form of a microscopic relief, which image layer is provided with a reflective metallization. The invention also relates to a method for manufacturing such a carrier body, wherein a thermoplastic layer is provided on its surface with an interference pattern, in particular a holographic image, in the form of a microscopic relief, the thermoplastic layer on a substrate. is applied and provided with a reflective metallization.

Such a body and such a method lend themselves in particular as respectively for a holographic image, briefly referred to as a hologram. Holograms are increasingly used, in addition to for more or less artistic purposes, as authenticity or provenance mark, for example on securities, banknotes, credit cards and the like, and on the packaging of luxury articles, such as perfumes, and computer software. The three-dimensional holographic image recorded in a mother mold proves to be an effective means in the seemingly eternal battle against imitations and falsifications.

A conventional manner of manufacturing a hologram is based on a transparent or non-transparent image layer of a thermoplastic material. The imaging layer, whether or not located on the final support substrate, is subjected to a pressure roller coated with a so-called shim at elevated temperature and pressure. The shim comprises on its surface a microscopic relief pattern 25 which is thus transferred into the wholly or partly molten image layer. The image layer is then provided with a suitable metallization, usually by depositing a metal such as aluminum on the vapors.

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A drawback of such a production method is that the image layer must first cool down sufficiently before the metallization can be applied. Namely, if the reflective metal layer is vapor-deposited too early, it is unlikely that cracks and tears will occur therein as a result of the shrinkage behavior S of the still warm image layer, which would unacceptably damage the appearance and quality of the end product. Such a service life of the image carrier slows down the production process and therefore has an adverse effect on the final cost price of the final product.

An object of the invention is, inter alia, to provide a carrier body of the type mentioned in the preamble, wherein such a service life can be avoided during manufacture, and in a method that does not require such a service life.

In order to achieve the intended object, a carrier body of the type mentioned in the preamble according to the invention has the feature that the image layer is at least substantially transparent and that the substrate comprises an optionally laminated metal foil with which the substrate adjoins the image layer. In this device, the image layer is on a metallic top layer which, thanks to its glossy surface, provides the desired reflective properties. Therefore, a metallization after the introduction of the relief into the image layer, as necessary in the manufacture of the known image carrier, and the associated tool life, need no longer be taken into account in the invention.

According to the invention, a special embodiment of the carrier is characterized in that the substrate comprises a laminated or non-laminated metal foil with which the substrate adjoins the image layer. The substrate can be laminated with a metal foil which has the desired metallic reflective properties, for instance paper or polyester provided with a metal coating, but the substrate can also be made entirely of a metal foil, whereby a separate laminating step is saved. A laminated self-contained metal foil as a substrate, due to its temperature and pressure resistance, allows the use of materials for the "00 2 76 8-3" image layer that would not normally lend itself to embossing. Examples include thermosetting materials such as alkyd resins. In this respect, a special embodiment of the device according to the invention has the feature that the substrate comprises an aluminum foil Such foil material is generally available on a roll from a few to a few tens of kilometers and is therefore ideally suited for a relatively inexpensive rotary printing process with which the desired micro-relief is applied in the image layer, resulting in extremely short production times.

A preferred embodiment of the image carrier according to the invention is characterized in that the substrate comprises a foil of a metal from a group formed by cobalt, nickel and iron. These materials are permanently magnetisable, so that the image carrier not only provides an optical security of the product provided therewith, but also provides an invisible theft protection which can be detected with appropriate, known per se gates at the exit of a room such as a retail space.

According to the invention, a method of the type mentioned in the preamble has the feature that a transparent layer is used for the thermoplastic layer and that for the substrate a carrier body with a reflective surface is applied on which the thermoplastic layer is applied.

The invention will now be further elucidated on the basis of an exemplary embodiment and an accompanying drawing, in which: fig. 1 A-1B show successive stages of the manufacture of a first embodiment of the device according to the invention in a first embodiment of the method according to the invention; and Figures 2A-2C show successive stages of the manufacture of a second embodiment of the device according to the invention in a second embodiment of the method according to the invention.

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The drawings are purely schematic and not drawn to scale. In particular, for the sake of clarity, some dimensions are strongly exaggerated. Corresponding parts are designated with the same reference numerals in the figures.

In Fig. 1A-1B, a substrate 1 in the form of a metal foil, in this case aluminum, is started from, on which a thermoplastic layer 2 was applied. The thermoplastic layer 2 comprises a suitable transparent coating for which a commercially available substance can be used, such as, for example ... Such a laminate can be manufactured on a roll from a few to several tens of kilometers and can be processed well in a rotary printing process. The starting substrate is wound therein in a web of a roll and pressed through a preheating roll between a pressure roll and a counter roll. The pressure roller is coated with a so-called shim which bears the negative of the micro-relief to be applied in the thermoplastic layer 2.

With the preheating roller, the top layer 2 is heated to its flow or melting point so that the layer is receptive to a permanent impression of the shim. Such a process is commonly referred to as embossing, micro-relief printing or micro-embossing and is known from the literature. After cooling, the result of figure 1B is obtained, whereby an image of the relief pattern of the shim is permanently contained in the top layer 2. The relief pattern is so fine that it gives rise to interference from light falling on it. Thus very imaginative artistic images can be realized and in particular holographic images can be produced. A condition for this is that the incident light is reflected. In the present image carrier, this is satisfied by the metallic and therefore reflecting surface of the underlying metal foil 1, so that no further treatment is required for this.

A second exemplary embodiment of a method according to the invention for manufacturing a second embodiment of an image carrier according to the invention will now be described with reference to Figures 2A-2C. This again starts from a transparent thermoplastic layer 2, for which the same material can be used, in order to receive a micro-relief therein in a comparable manner. In this case, the layer 2 initially rests on a temporary support 3 of, for example, paper, polyester or any other suitable support material. A release layer 4 is provided between the temporary carrier 3 and the top layer 2, which will promote adequate separation of the top layer 2 from the temporary carrier 3 later in the process. The temporary carrier 3 thus covered is presented on a roll of a few to a few tens of kilometers and on the temporary carrier 3 the top layer is provided with the desired micro-relief pattern in the manner described above, so that the structure of figure 2B is obtained.

Subsequently, the temporary carrier 3 is guided with its covered side against the final substrate 11,12, see figure 2C. The substrate in this case comprises a nickel foil 11 which is laminated on a paper bottom layer 12 and which is provided on the surface with a thin adhesive layer, not shown. Thus, the image layer 2 in which the relief was applied is pressed with its relief side against the adhesive layer on the substrate 11,12 and permanently adhered thereto. By subsequently dividing both webs 15, the imaging layer 2 is (partly) pulled apart from the temporary carrier 3, thanks to the release layer 2, which can be reused or destroyed. The image layer is thus transferred from the temporary support to the final substrate 11,12 which, thanks to the metallic surface of the nickel foil 11, provides the reflection of incident light required for visible interference.

Holograms made in such a manner are increasingly being used as a security feature for securities, credit cards and the like and on packaging of luxurious, expensive articles such as perfumes, cosmetics and, for example, computer software. In particular for this latter class of applications, the present embodiment of the image carrier according to the invention offers additional protection in that a permanent magnetic nickel foil is used therein. Alternatively, an iron foil or a cobalt foil may also be used. By magnetizing the foil, shoplifting of the product can be prevented by means of control gates, known per se, arranged at the exit of a shop space. The device thus offers 1002768 -6- not only a barrier against imitation and counterfeiting, but also against theft, so that additional means can be saved for the latter purpose.

Although the invention has been further elucidated on the basis of only a single exemplary embodiment, it will be clear that the invention is by no means limited to the given exemplary embodiments. On the contrary, many variations are still possible within the scope of the invention. For example, instead of a metal layer as a reflective surface on the substrate, a layer of a material known under the name "Essence d'Orient" prepared from the alver, a species of fish, can be used. This material consists of crystal plates of guanines, which are also found on the scales of the fish and exhibit extremely good reflection properties that are not inferior to a metal surface.

The said substrate and temporary support materials are also only given as an example of the invention and, like the material of the thermoplastic top layer, can be replaced by suitable other materials.

Furthermore, it is possible to separate the reflective metallic top layer of the substrate by a thin transparent layer, for example Croda shellac 799-M7001 or 799-M7018 or a nitrocellulose lacquer, from a lower reflective layer. The thickness of the transparent layer is typically of the order of 60-200 nm. In that case, internal reflection of ambient light occurs within the transparent layer thus coated on both sides with a reflective layer, which gives the overall product a particularly attractive appearance, the color of which depends on the exact thickness of the transparent layer.

In general, the invention provides an image carrier and a method therefor that allows a cost and production time reduction over a conventional counterpart 25 without sacrificing quality and durability.

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Claims (11)

Image carrier comprising a substrate with an image layer disposed thereon in which an interference pattern, in particular a holographic image, in the form of a microscopic relief is provided, the image layer being provided with a reflective metallization, characterized in that the image layer and substrate comprises a colored or at least substantially transparent layer, or at least a metallic top layer, with which it adjoins the image layer. Image carrier according to claim 1, characterized in that the substrate comprises a laminated or non-laminated metal foil with which the substrate adjoins the image layer. Image carrier according to claim 2, characterized in that the substrate comprises an aluminum foil. Image carrier according to claim 2, characterized in that the substrate comprises a foil of a metal from a group formed by cobalt, nickel and iron. Image carrier according to claim 1, characterized in that the metallic top layer 15 is successively separated from the rest of the substrate by a thin transparent layer and a further reflecting layer. 6. Method for manufacturing an image carrier according to one or more of the preceding claims, wherein a layer on its surface is provided with an interference pattern, in particular a holographic image, in the form of a microscopic relief, the layer on a substrate is applied and provided with a reflective metallization, characterized in that a transparent layer is applied for the layer and that the substrate is based on a carrier body with a reflective surface on which the layer is applied. 100276 8 -8- Method according to claim 6, characterized in that the transparent layer is applied to a laminated or non-laminated metal foil. Method according to claim 7, characterized in that the transparent layer is applied to an aluminum foil. Method according to claim 5, characterized in that the transparent layer is applied to a foil of a metal selected from a group comprising cobalt, nickel and iron. Method according to one or more of Claims 4 to 7, characterized in that the transparent layer lying on a temporary support is provided with the interference pattern 10 and only then transferred to the substrate. Method according to one or more of claims 4 to 7, characterized in that the transparent layer is applied to the substrate before applying the interference pattern therein. 1902768