AT12550U1 - LIGHT BODY AND METHOD FOR THE PRODUCTION THEREOF - Google Patents

Abstract

The invention relates to a luminous element (1) with a carrier material (2) and a light-emitting layer (4), wherein the carrier material (2) is arbitrarily shaped, electrically conductive and contactable, covered by a dielectric layer (3), which at least partially is covered by the light-emitting layer (4), which is at least partially covered by an electrically conductive and contactable front electrode (5), and a method for producing the luminous body (1) according to the invention.

Description

Austrian Patent Office AT12 550U1 2012-07-15

description

LIGHTING BODIES

The invention relates to a luminous body with a carrier material and a light-emitting layer and a method for producing such a filament.

There are currently known applications with so-called. Electroluminescent. Electroluminescence (EL) is a form of luminescence in which a solid is excited by application of an electric field or voltage to produce electromagnetic radiation, e.g. in the form of light, to emit. Luminescence is the optical radiation of a physical system that results from the transition from an excited state to a ground state (radiative deactivation). Electric field in electrostatics and electrodynamics refers to a state of space that is caused by the electrical charges present and by the temporal change of the magnetic field. Charges are influenced by the electric field.

The structure of such luminous bodies consists essentially of a carrier foil, which is rendered electrically conductive by means of vapor-deposited metal (for example indium-tin oxide - so-called ITO) and nevertheless remains translucent and the actual layer structure for generating the light by means of an electric field. This layer structure consists essentially of the light-emitting layer, which consists essentially of zinc sulfides, which is applied by means of a binder on the metallized film, thereon a dielectric layer and thereon an electrically conductive layer, e.g. made of silver or carbon. Between the two electrically conductive layers - the metallic layer on the film, in which the electric voltage is introduced by the contact path, and the electrically conductive layer in the layer structure - the electric field is built up and thus the electroluminescent effect generated in the light-emitting layer ,

The structure described has the disadvantage that the vapor-deposited metallic layer breaks on the film at too high a stress, whereby it can not be applied to three-dimensional body or this can not be subsequently deformed. Likewise, the structure described above must be protected with so-called laminates, hot or cold, against contact-insulation of the current-carrying layers - and against environmental influences, such as, for example. Humidity.

By this structure of the luminous body, it is not possible the existing technology for the backlighting of paints or in three-dimensionally deformed bodies without much effort, such. Filling the film in the transition region to the load-bearing component, and a higher material requirements, such as: apply the topcoats. Likewise, an application of the electroluminescent film would be possible only by gluing, whereby a permanent adhesion of the Elek rolumineszenzlichtes on the component is not guaranteed.

The present invention is based on the technical object of exploiting the advantages of the electroluminescent light as light among paints, which means that the electroluminescent light for the use in vehicle construction (cars, trucks, rail vehicles, aircraft) should be generally possible , Likewise, the production should also be possible on three-dimensional bodies or the light should be cold-workable. This should create new possibilities for design, theft protection or branding (representation of a brand or logo).

This object is achieved in that the substrate is arbitrarily shaped, electrically conductive and contactable, is covered by a dielectric layer, which is at least partially covered by the light-emitting layer, which at least partially covered by an electrically conductive and contactable front electrode is.

The luminous body is constructed starting from the back electrode to the front electrode with an attachment of the contact points laterally or in the rear region of the return electrode. 1/9 Austrian Patent Office AT 12 550 Ul 2012-07-15

As a return electrode, a sheet, which is electrically conductive is used.

Between the front electrode and the rear electrode, which is the carrier material in this case at the same time, an electric field is built up. By this electric field, electrons of the light-emitting layer are excited to vibrate, whereby electromagnetic radiation, in particular light, emerges.

For use as a colored topcoat special paints have been developed, which are light-permeable but still opaque. In addition, conventional paints can also be used as topcoats, allowing the user to continue to use proven paints or inks introduced by his customers. In a row, this particular light is called 3D fl ash light.

Based on the task of producing a structure which is to allow the introduction of light between the carrier material and topcoat, now the above-described construction of the prior art is reversed. This means that the back electrode is used as the carrier material. This carrier material is made of an electrically conductive material, such as e.g. Aluminum (AI), copper (Cu) or a similar material which is electrically conductive. This material is coated with a dielectric, e.g. Alumina (Al 2 O 3), barium titanate (BaTiO 3) or similar materials, so insulated that the complete material is covered by this dielectric, except for the area to which the contact for the back electrode is applied. At the same time, the carrier material is protected against oxidation by this dielectric layer.

The light-emitting layer is brought over the entire surface of the substrate, so that it extends to the edge or will be visible only as a logo under the topcoat. As a next step, the so-called front electrode, the second pole of the capacitor, is brought over the light-emitting layer. This front electrode is placed over the edge of the rear electrode, so that there the contact of the front electrode can be made. On the back electrode an accessible point for the preparation of the contact is freed from the dielectric layer. At this point, the contact for the second pole of the 3D flashlight is made. After contacting, the complete light is sealed in color or colorless by means of a translucent varnish.

It is in particular provided according to the invention, the front electrode made as electrically conductive rendered thin polymer layer. By performing as electrically conductive made plastic, such as polyvinyl, it is possible to dispense with the use of ITO. Such a plastic can be applied in the form of a lacquer or in a printing process to arbitrarily shaped body, a protective atmosphere is generally not required. As a result, the production of the light body is significantly facilitated and it is possible for the first time to treat any three-dimensional body without the applied layer breaks. The resulting light body can be made flexible and flexible.

For the support material, in particular, a steel sheet is used, but also aluminum (Al), copper (Cu), silver (Ag), gold (Au), or a similar material can be used. Prerequisite is the electrical conductivity - if other non-electrically conductive materials are used, the back electrode can be applied as an additional layer. As a pretreatment of the carrier material (back electrode), this area can also be isolated for the production of the contact area, so that the dielectric layer does not have to be specially processed in this area for subsequent contacting. The thickness of the material can be from 0.1 mm to 50 mm or more.

The dielectric layer, which consists of insulating material such as: alumina (Al 2 O 3), barium titanate (BaTiO 3), an insulating electroplated layer, plastics or similar materials is over the entire surface, front and back and the edges of the Carrier material applied, so that a protection against oxidation of the carrier material is formed. This coating can be applied both by pouring, knife coating, brushing, spraying, and 2/9 Austrian Patent Office AT12 550U1 2012-07-15

Diving or even be applied in digital printing. Due to the polarizability, this layer can also be applied by means of electrical or magnetic fields in a powdery or pasty manner.

It is also possible to apply this layer by electroplating or vapor deposition.

The light-emitting layer consists of zinc sulfide (ZnS), encapsulated or un-encapsulated phosphors, or other materials which can be excited when applying an AC electric field to glow. The layer is applied to the edge of the carrier material. Should a logo, lettering or only partial illumination be necessary, this can be achieved by applying the light-emitting layer in exactly this design. The application of the material can be applied by casting, knife coating, brushing, spraying, dipping or digital printing. Due to the polarizability, this layer can also be applied by means of electrical or magnetic fields in a powdery or pasty manner.

The front electrode is made according to the invention of a polymer made conductive, such as polyvinyl acrylate. However, the front electrode can also be constructed of any light-permeable layer of metal, such as, for example, indium tin oxide (ITO), silver (Ag), gold (Au). Important is the design of the layer thickness in a range, so that the electrical conductivity is given, the layer still remains permeable.

The front electrode is applied over the surface of the light-emitting layer, so that the contacting of the front electrode can be made. It is also possible to apply the contacting of the front electrode before the application of the front electrode, so that the front electrode is then brought over the contact. The front electrode can also be made white, black or colored translucent or specular, so that a font or logo appears only after activation of the light-emitting layer. This layer can be applied by casting, knife coating, brushing, spraying, dipping or digital printing. Due to the polarizability, this layer can also be applied by means of electrical or magnetic fields in a powdery or pasty manner. It is also possible to apply this layer by electroplating or vapor deposition.

The protection of the electroluminescent light from environmental influences, or the isolation of the system is achieved by attaching a translucent layer over the entire system. In this layer, one can also have a special protection, such as to work against UV light or other influences. Likewise, a "set " the fire protection class through this layer possible. This layer is applied transparent or colored.

In order to apply the layers according to the invention on all possible 2- and 3-dimensional surfaces, a special application method, similar to the known painting technology has been developed. Likewise, the paste formulation has been optimized to this effect. However, it is possible to use all other known application methods, such as casting, knife coating, brushing, spraying, dipping or also digital printing methods.

According to the invention it is provided in particular that an electrical contact of the carrier material is provided laterally or on the side facing away from the light-emitting layer of the carrier material. It can also be provided that an electrical contact of the front electrode is formed laterally or on the side of the front electrode facing the light-emitting layer. This ensures that the contacts do not hinder the light emission.

It may further be provided that the light-emitting layer is applied in a specific design, in particular as a logo. Furthermore, a cover layer can be applied, which is translucent, but nevertheless opaque, so that the light-emitting layer is not recognizable in the resting state.

Both the light-emitting layer and the covering or translucent cover layer can be used to realize certain design effects with the light body. In particular in connection with a three-dimensionally shaped carrier material and differently masked light-emitting layers and outer layers, special desired design and display effects can be achieved, for example in the automotive industry.

The invention further relates to a method for producing such a luminous body, wherein the method comprises the following steps: First, an electrically conductive substrate is covered with a dielectric layer. Thereafter, a light-emitting layer is applied. On this an electrically conductive front electrode is applied, wherein an electrical contact is formed at the edge or on the back of the film. Thereafter, a portion of the dielectric layer is removed and the substrate is provided with an electrical contact. Finally, a translucent, colored or colorless topcoat can be applied. The individual layers which can be applied in the method can have, in particular, the properties described above.

Further features of the invention are described in the description, the claims and the figures.

The device according to the invention and the method according to the invention will become apparent from the following figures. 1 shows a schematic cross section through the layer structure of a luminous element in the form of a conventional electroluminescent film of the prior art, [0029] FIG. 2 shows a schematic cross section through the layer structure of an embodiment of a filament according to the invention.

3 shows a schematic cross section through the layer structure of an embodiment example of a multi-dimensionally shaped filament according to the invention.

Fig. 1 shows a schematic cross section through a conventional electroluminescent film of the prior art. Such films consist of a carrier material 2, on which an electrically conductive front electrode 5 is vapor-deposited. On the front electrode 5, the light emitting layer 4, which consists essentially of zinc sulfides, is applied by means of a binder, thereon a dielectric layer 3 and thereon an electrically conductive layer, the back electrode 6, e.g. made of silver or carbon. Between the two electrically conductive layers - the front electrode 5 on the film, in which the electrical voltage is introduced by a contact track, and the return electrode 6 - the electric field is established and thus the electroluminescent effect in the light-emitting layer 4 is generated.

FIG. 2 shows a schematic cross section through a luminous element according to the invention. FIG. The carrier material 2 is used according to the invention as a return electrode. This support material 2 is therefore made of an electrically conductive material, such as e.g. Aluminum (AI) or copper (Cu). This material is coated with a dielectric layer 3, e.g. Alumina (Al 2 O 3) or barium titanate (BaTiO 3) so as to cover the entire substrate 2 except for the area where the contact 7 is supplied. At the same time, the carrier material 2 is protected from oxidation by this dielectric layer 3.

The light-emitting layer 4 is wholly or partially brought to the substrate 2, so that it extends to the edge or will be visible only as a logo under the top coat layer. As a next step, the front electrode 5, the second pole of the capacitor, is applied via the light-emitting layer 4. This front electrode 5 is placed over the edge of the back electrode (support material 2), so that the contacting of the front electrode 5 can be made by the electrical contact 8 at the edge, without preventing the light radiation. On the back electrode, the carrier material 2, an accessible point for the production of the contact 7 is freed from the dielectric layer. The complete light is sealed by means of a cover layer 9 colored or colorless.

Fig. 3 shows a schematic cross section through a further embodiment of a filament according to the invention. In this case, the carrier material 2 is multi-dimensional 4/9

Claims (10)

Austrian Patent Office AT12 550U1 2012-07-15 deformed onal, and the applied layers follow this form. A front electrode 5 made of an electrically conductive polymer is particularly suitable for this application, since for example a layer of ITO would break at the edges with high probability. Furthermore, the voltage source 10 is shown, whose first pole is connected to the front electrode 5 and whose second pole is connected to the carrier material 2. The invention is not limited to the embodiments shown and also includes other, in particular three-dimensional structures of the filament. Furthermore, the invention also includes components, in particular parts of the body of a vehicle, which comprise a luminous body according to the invention. REFERENCE LIST 1 Illuminant 2 Support material 3 Dielectric layer 4 Light-emitting layer 5 Front electrode 6 Rear electrode 7 Electrical contact 8 Electrical contact 9 Cover layer 10 Voltage source Claims 1. A luminous element (1) with a substrate (2) and a light-emitting layer (4), wherein the substrate ( 2) is arbitrarily shaped, electrically conductive and contactable, covered by a dielectric layer (3) which is at least partially covered by the light-emitting layer (4) which is at least partially covered by an electrically conductive and contactable front electrode (5), characterized in that the front electrode (5) consists of an electrically conductive polymer, in particular polyvinyl acrylate, or contains this polymer, and the front electrode (5) is at least partially covered with a translucent and / or covering cover layer (9). Second luminous element (1) according to claim 1, characterized in that the light-emitting layer (4) is applied in a specific design, in particular as a one- or multi-dimensional logo. 3. luminous element (1) according to one of claims 1 to 2, characterized in that an electrical contact (7) of the carrier material (2) laterally or on the light-emitting layer (4) facing away from the carrier material (2) is provided. 4. luminous element (1) according to one of claims 1 to 3, characterized in that an electrical contact (8) of the front electrode (5) laterally or on the light-emitting layer (4) facing side of the front electrode (5) is formed. 5. luminous element (1) according to one of claims 1 to 4, characterized in that the carrier material (2) made of aluminum, copper, silver, gold or a similar material is formed. 6. luminous element (1) according to one of claims 1 to 5, characterized in that the dielectric layer (3) is formed of an insulating material such as aluminum oxide, barium titanate, an insulating galvanic layer, plastic or the like. 5/9 Austrian Patent Office AT12 550U1 2012-07-15 7. luminous element (1) according to one of claims 1 to 6, characterized in that the light-emitting layer (4) of zinc sulfide, encapsulated or non-encapsulated phosphors or of other materials that can be excited when an electric field is applied, is formed , 8. luminous element (1) according to one of claims 1 to 7, characterized in that the cover layer (9) is designed in certain areas at least partially translucent and covering certain areas. 9. luminous element (1) according to one of claims 1 to 8, characterized in that the cover layer (9) is designed as a lacquer. 10. A method for producing a luminous element (1) according to one of claims 1 to 9, characterized in that the method comprises the following steps: a. an electrically conductive substrate (2) is covered with a dielectric layer (3), b. a light-emitting layer (4) is applied thereon, c. an electrically conductive front electrode (5) is applied thereon, wherein an electrical contact (8) is provided on the rear side of the film (1) at the edge o, d. a part of the dielectric layer (3) is removed and the substrate (2) is provided with an electrical contact (7), e. an at least partially translucent, colored or colorless cover layer (9) is applied. 3 sheets of drawings 6/9