EP0485780A1 - Material generating optical effects and process for making said material - Google Patents

Abstract

The invention relates to an optically active material (1) and a method for its production with at least one element (2) which can be arranged in and / or on a carrier (3), the at least one element being able to be arranged in and / or on the carrier and optically three-dimensionally changed. Before adjusting its position in and / or on the carrier, the element is changed such that it assumes an optically three-dimensional effective shape. <IMAGE>

Description

The invention relates to an optically active material according to the preamble of claim 1 and a method for its production according to the preamble of claim 12.

Such optically effective materials are preferably used for the inexpensive imitation of structures of semi-precious stones. These materials can also be used in the manufacture of buildings as visually striking and aesthetically pleasing components.

Insects or similar optically attractive elements are often poured into acrylic glass objects. Their quasi three-dimensional arrangement in the acrylic glass object allows the complete physical representation of the element.

From DE-PS 35 33 463 it is known to imitate natural structures by fitting transparent effect layers one above the other. The arrangement and design of the effect layers is similar to that of the natural structure to be imitated. In addition to matching the appearance, the three-dimensional effect of the natural structure is also imitated. This agreement is particularly due to the spatial arrangement of the Layers.

Since the effect layers are flat and are arranged one above the other, they each have optical plumb lines oriented approximately in the same direction. As a result, incident light is always diffracted at approximately the same angle. However, this means that a different optical impression of the imitated natural structure can only arise if the position of the light source and / or the effect material and / or the viewer changes.

The aim of the present invention is to improve the optical effect of conventional optically active materials.

This object is achieved in a generic optical material by the characterizing features of claim 1 and in a generic method for producing an optically effective material by the characterizing features of claim 12. The element can be chemically or physically changed three-dimensionally before it is arranged in and / or on the carrier, for example. H. is adapted to the conditions specified by the carrier.

The three-dimensionally effective element optically creates a double spatial effect in a carrier. On the one hand, there is an increased three-dimensional effect compared to the prior art due to the arbitrary arrangement of the element in the carrier. On the other hand, the element works three-dimensionally for itself. The basic prerequisite for achieving such a three-dimensional effect is of course a difference in the optical properties - for example the refractive indices - of the support and the element. The layer, sheet or film-like element preferably has relief-like contours within the carrier. The Depth effects when looking at natural substances that appear in space can be imitated in a surprisingly similar way. In the case of color phenomena, other effects can also be achieved due to the three-dimensional optical additional effect than when viewing a colored area that can be identified from the standardized color chart. The element can of course also be a deliberately created flaw or gap in the carrier, but it may also have flaws itself. All physical states are conceivable for material, carrier and also element. The surface quality must be adapted to the respective requirements. Since the element can have any dimensions, industrial production is possible to an almost unlimited extent.

The element advantageously has surface sections with at least two surface normals not aligned parallel to one another. As a result, the viewer's eye not only receives light from a preferred direction of incidence. Rather, differently oriented surface normals and, accordingly, differently oriented optical incidence solders cause a variety of different diffractions. The different sections of the element are quasi optically individualized, ie each section is a diffraction system in its own right. This increases the spatial effect of the changed element in a physically known manner. The viewer has an intense depth effect. At the same time, individualization also means that light is not only perceived at a certain angle on the element. The likelihood of diffraction at an incident perpendicular to any element section is increased. This is particularly advantageous for objects - such as so-called "cat eyes" on bicycles - where the function depends on the reflection of the incident light. The light does not have to fall according to the invention at a preferred angle. Almost all directions of incidence are possible. In the case of "cat eyes", the incident light is reflected in all directions according to the invention.

The element particularly preferably has sections of surfaces which are inclined at different angles to one another. These automatically arise when the film-like element is subjected to different external forces. Such surfaces are preferably produced mechanically, for example using the so-called embossing process or the vacuum process.

In a particularly preferred embodiment of the material according to the invention, the element has surfaces with sections of different shapes. As a result, the intensity of the diffracted light can be changed as a function of the incidence section on the element. A curvature of the element, for example, achieves an optically dispersing or collecting effect.

The element is preferably optically iridescent. The element is particularly preferably partially reflective, partially transmissive and / or absorbent. If light rays pass through a first element and strike another element below the first element, partial reflection also takes place here. The light reflected by the second element can again pass through the first element above and there again contribute to the formation of interference. The result is an individual color impression. The color impression is intensified insofar as elements arranged one above the other produce roughly the same visual images. This is the case, for example, when surfaces of the elements are aligned quasi parallel to one another with respect to the passage of light. In combination with the three-dimensional arrangement, color effects can be achieved that were previously not possible in their purity. In particular, these color effects provide an optical appearance that is extremely similar to the precious opal.

In a particularly preferred embodiment of the material according to the invention, a protective layer is arranged between the element and the carrier substance, which prevents a reaction between the carrier substance and the element. Especially when using acrylic there are often unwanted reactions when in contact with other materials. As a result, substances in an acrylic support, e.g. H. Items dissolve or swell. The adhesion of the different materials to each other is reduced or can even be lost entirely.

With the help of the protective layer according to the invention, undesired reactions between the element and the support or between existing reductions or dissolutions in adhesion can be excluded. It goes without saying that even element and carrier can be chosen without the use of a protective layer in such a way that undesired reactions or adhesion problems are ruled out from the start.

The protective layer, carrier or element can be a photopolymer with the property of curing under the action of UV radiation. As a protective layer, carrier or element, for example, solvent-based lacquers, solvent-free lacquer and two component systems that polymerize under the action of UV light, catalysts or heat, etc., copolymers or mixtures of systems etc. can also be used.

The protective layer is particularly preferably flame-retardant or self-extinguishing. This is precisely when using the optically effective material as a building or As a decorative element, it is an advantage if the risk of fire is to be minimized. Even if part of the optically active material should burn, the protective layer can prevent the remaining, protected part of the material from burning away. Of course, the support or element can also be flame-retardant or self-extinguishing, which means that the risk of fire can be completely excluded.

In order to achieve particularly beautiful effects, the materials used can be colored as desired. The coloring can of course, i. H. with the help of rock, metal, vegetable powders, color soils or sand, chemically, for example, through pigments, liquid-crystalline phases, fluorescent substances or physically via vaporization, possibly with metal oxides, interference colors, light guides.

The film-like element is preferably a rainbow film. Such films - consisting of a large number of translucent plastic layers - are inexpensive to manufacture and are available everywhere. A rainbow film creates an opalescent effect when illuminated with light at a certain angle of incidence due to different diffraction of certain wavelengths.

The element is particularly preferably a continuous layer and / or a light guide. If the above-mentioned layer is introduced between two identical materials, it essentially serves as an optical medium with a different refractive index than the rest of the material. The relief-like configuration of the layer again contributes to the double three-dimensional effect according to the invention. The layer can also be lightly coated with translucent plastic, preferably on both sides. This composition achieves the optical effect according to the invention and has the advantage that with extreme flexibility it can be used as a semi-finished product where the essential requirement of the optically effective material is its flexibility.

In a further preferred embodiment, the bottom surface and / or at least one side surface of the material has an optically non-transmitting layer. Radiation cannot leave the optically active material after the passage. A background contrast is thus created for the film-like elements, which enhances the optically three-dimensional effect of the optically active material. The optically non-transmitting layer can only be produced, for example, by coloring the already existing material, but also by providing an additional layer of its own.

In a further preferred embodiment of the material, the carrier is a carrier substance which maintains a relative equilibrium position of the at least one element in the material. A rigid, crystalline solid structure of the material for the viewer can be ensured in this way.

In an advantageous method, the originally smooth surface of the film-like element can be changed, inter alia, by applying pressure and / or tension and / or torque. This allows the required structure of the desired final state of the film-like element to be determined. The changes can be made either mechanically or manually.

In a further embodiment of the method according to the invention, the optically active material is finally cut and reassembled in any way. By changing the layering, the three-dimensional impression of the optically effective material can be enhanced. At the same time, there are more optical ones Appearances such as pictures, letters or objects can be arranged between the cutting planes. This makes it possible to combine the three-dimensional effects of the optically effective material with information media at the same time.

For the purpose of finishing, the optically active material is preferably polished on the surface. Suitable finishing processes are, for example, the polyurethane adhesive technology with glass, the antistatic coating, the no drop coating, the coating by plasma polymerization, screen printing and scratch-resistant coatings, etc.

Remainders of the optically active material that are no longer used are advantageously ground, shaped or further polished in drum grinders or vibrators to form so-called “pebbles” or coated differently depending on the application. These "pebbles" combine excellently with, for example, acrylic blends, recycled acrylic of any size, color or transparency, which is also processed using the above method.

An exemplary embodiment of the invention is shown in the drawings and is described in more detail below.

Fig.1

einen Querschnitt durch das erfindungsgemäße optisch wirksame Material; und

Fig. 2

einen Querschnitt durch das zerschnittene und wieder zusammengesetzte optisch wirksame Material gemäß der Erfindung.

Show it:

Fig. 1

a cross section through the optically active material according to the invention; and

Fig. 2

a cross section through the cut and reassembled optically active material according to the invention.

There follows the explanation of the invention with reference to the drawings according to structure and, if appropriate, also after the effect of the invention shown.

1 shows a finished, optically active material 1. It is produced as follows:
First, a casting mold, not shown, is arranged in a water bath in a known manner. An uncured epoxy resin 3 is introduced into this mold up to a certain height.

A film-like element 2, for example in the form of a rainbow film, is processed outside the casting mold into pieces of the desired size. The rainbow film pieces 2 obtained in this way are subsequently subjected to an external force. They can be rotated, compressed, pulled or surface manipulated in any other way. The manipulation is only about generating surface sections 4a, 4b of different inclinations to one another or else surface sections 5a, 5b of different shapes. Depending on the number of differing surfaces of the rainbow film pieces 2, a correspondingly large number of optical solders in a wide variety of directions results. The number of different reflection or transmission preferred directions for incident light is directly proportional to the number of differently oriented optical solders.

Preferably after processing, the rainbow film pieces 2 are placed on the surface of the not yet hardened epoxy resin 3 or immersed therein. The rainbow film pieces 2 can also be changed in their structure only after arrangement in the epoxy resin 3.

If a desired piece of rainbow film 2 has been introduced into the epoxy resin 3 and fixed in position due to the curing of the epoxy resin 3, a further layer of liquid epoxy resin 3 can be poured into the casting mold. This further epoxy resin 3 again takes up rainbow film pieces 2 on the surface. After curing, the storage process of the rainbow film pieces 2 in the epoxy resin 3 can be repeated step by step.

Of course, the desired mold can initially be completely filled with epoxy resin 3. The pre-processed rainbow film pieces 2 are then arranged in the not yet hardened state of the epoxy resin 3, for example with the aid of tweezers, in the desired position. After curing, the pieces 2 are fixed.

Instead of the epoxy resin 3, silicone, glass, acrylic, oils or aqueous substances can also be used, for example. The carrier 3 is selected based on the criterion of the desired color and / or the desired refractive index. When using aqueous substances as the carrier 3, the severity of the film-like elements 2 determines their position.

When the curing process for the epoxy resin 3 has ended, the material 1 can be removed from the casting mold. To increase the spatial effect, the lower and / or. Side surfaces can be provided with an absorption color. The light incident on the material 1 is not allowed to pass through.

In order to be able to use the material 1 as a component, element of common everyday objects or as an art object, the surface is additionally refined. This refinement is carried out by attaching a glass 7 on the surface of the material 1 which appears to the outside or possibly by polishing this surface. This surface can also be painted.

2 shows a component composed of cut optically active material 1, 1 ', 1'',1'''.

For this purpose, individual optically active materials 1, 1 ', 1' ', 1' '' are first produced as previously explained. After curing, they are cut up. The resulting parts are then combined with one another as required. The combination is made by placing the parts on the corresponding cutting planes. In this way, even different carrier substances of different colors or refractive indices can be combined with one another. It is also possible to use film-like elements 2 and 2 'which cannot be accommodated in the other carrier substance 3, 3', for example for chemical reasons.

Images or similar recordable objects can advantageously be arranged between the cutting planes. This ensures that the optical component is used as a communication medium.

In the following, for example, a manufacturing method for the optically active material, as previously described in the principles with reference to the drawings, is explained in more detail:
First, a tubular body with an approximately U-shape is placed on a lying glass plate. Another glass plate is placed on the tubular body from above. Clamps to be arranged laterally along the outer circumference of the glass plates effect a sealing connection between the glass plates and the tubular body. The interior space delimited by the tubular body between the glass plates is only accessible from one side, namely through the opening between the two leg ends. Thus, the structure called glass mold and tubular body forms a pocket.

The mold is now placed upright in such a way that the formed pocket is open at the top.

An inherently stable film with protective lacquer is inserted into this bag from above. The bag is then filled with prepolymerized acrylic. If air bubbles form when filling, they are preferably sucked off using a vacuum. A leg portion of the tubular body in a U-shape is extended such that it protrudes from the mold. The protruding section is now carefully placed over the open edge of the mass in the mold, that is to say the casting mass, in such a way that no air bubbles remain in the casting mass. With the help of the adjustment of the brackets mentioned above, the removal of the air bubbles can be significantly supported.

In the final state, the previously protruding section of the tubular body and the other end of the tubular body lie side by side as seen from above. They are mutually sealed using a suitable kit. Clamps are then also attached to the location of the kit, which means that the necessary pressure is then exerted on the two glass plates.

The entire mold is placed in a preheated water bath. This prepolymerizes the prepolymerized acrylic. The duration of this process depends on a wide variety of factors, for example the thickness of the molding compound.

After the casting compound has polymerized and matured into a solid molded body, the entire casting mold is annealed in a forced air oven until no more stresses and migrations are to be feared.

After this procedure, the finished molded body is removed from the casting mold and used as such or as a semi-finished product for further processing.

This semi-finished product can be used as a core for injection molded articles. It is also possible to produce the optically active material by an injection molding process. It is particularly advantageous that the injection molds already specify certain objects and the optically active material quickly adapts to these shapes. This optimizes the speed and thus the economy of the manufacturing process. Of course, extrusion, co-extrusion, coating processes, etc. are also conceivable as processes for producing the optically active material.

Claims (14)

Optically active material with at least one layer, sheet or film-like element which can be arranged in and / or on a support, the support and material having at least one different optical property, characterized in that
that the at least one element (2) is arranged in and / or on the carrier (3) and relative to it as desired and is effectively changed in three dimensions. Material according to claim 1, characterized in
that the element (2) has surface sections (4a, b) with at least two non-parallel surface normals. Material according to claim 1 or 2, characterized in that
that the element (2) has sections of differently inclined surfaces (4a, b). Material according to at least one of claims 1 to 3, characterized in that
that the element (2) has surfaces with sections (5a, b) of different shape. Material according to at least one of claims 1 to 4, characterized in that
that the element (2) is optically iridescent. Material according to at least one of claims 1 to 5, characterized in that
that the element (2) is partially reflective, partially transmissive and / or partially absorbent. Material according to at least one of the preceding claims, characterized in that
that a protective layer is arranged between element (2) and carrier substance (3), which prevents a reaction between carrier substance (3) and element (2), the protective layer being in particular flame-retardant or self-extinguishing. Material according to claim 7, characterized in
that the film-like element (2) is a rainbow film. Material according to claim 6, characterized in
that the element (2) is a continuous layer and / or a light guide. Material according to at least one of the preceding claims, characterized in that
that the bottom surface and / or at least one side surface has an optically non-transmitting layer (6). Material according to at least one of the preceding claims, characterized in that
that the carrier (3) is a carrier substance which maintains a relative equilibrium position of the at least one element (2) in the material (1). Method for producing an optically active material (1) with at least one element (2) which can be arranged in and / or on a carrier (3), characterized in that
that the element (2) is layer, sheet or film-like and before adjusting its position in and / or on the carrier (3) is changed such that it assumes an optically three-dimensional shape. A method according to claim 12, characterized in
that the original smooth surface of the film-like element (2) is changed by applying pressure and / or tension and / or torque. A method according to claim 12 or 13, characterized in
that the optically effective material is cut and reassembled in any way.

Images