EP1765040A2 - Electroluminescent film and method of its production - Google Patents

Abstract

Electroluminescent film has a base film (1), which radiates during triggering the light. Electroluminescent film also has beam path of the base film lies a color filter layer (3), which absorbs a part of radiated light from the base film and a part lets it pass through during the change of a color tone of light. An independent claim is also included for the production method of the electroluminescent film.

Description

The invention relates to an electroluminescent film according to the preamble of claim 1 and a method for the production thereof according to the preamble of claim 11.

Electroluminescent films are flat illuminants that emit light when energized. The electroluminescent film has a base film in which fluorescent substances, usually zinc sulfide (phosphorus powder), are present. The color locus, i. the hue of the light emitted by the electroluminescent film depends on the doping of the fluorescent pigments. If the electroluminescent films have to be produced for different shades of the emitted light, the production is only profitable in the case of large quantities. Due to the different doping of the phosphor powder, not all color loci or hues can be realized. Also, the yield of luminance is often low.

There are also known electroluminescent films in which the color locus is adjusted by the addition of fluorescent colorants in the phosphor paste. For example, the reflected light color (electroluminescent foil is not switched on) may be pink, while the electroluminescent foil is white when switched on. By the added colorant, however, the incident light color of the electroluminescent, ie the hue of this film changes when it is not energized. Frequently, however, a neutral incident light color is required in the off state, so that the addition of fluorescent colorants is not possible. In addition, there is the problem of separation of the colorant within the phosphor paste, so that the Quality of the electroluminescent is impaired. There is also the problem of UV resistance of the colorant or pigment.

The invention has for its object to provide the generic electroluminescent and the process for their preparation in such a way that with simple production all the hues emitted by the electroluminescent can be adjusted while a long life and high luminance are guaranteed.

This object is achieved in the generic electroluminescent according to the invention with the characterizing features of claim 1 and the generic method according to the invention with the characterizing features of claim 11.

In the case of the electroluminescent film according to the invention, the light emitted by the base film, which as a rule has a hue, passes through the color filter layer. It can be used to produce any desired color location that is desired for the application of the electroluminescent film. For example, the electroluminescent film according to the invention has a lifetime of up to about 10,000 hours with green luminescent color and up to about 3,000 hours with red luminescent color. In addition, the electroluminescent film according to the invention is characterized by a high luminance.

In the method according to the invention, the color filter layer is first printed on the carrier film. Subsequently, the unit of color filter layer and carrier film is attached to the base film.

Advantageously, the color filter layer contains fluorescent, embedded in a binder pigments. The color filter layer thus forms a fluorescence filter with which the desired hue of the emitted light can be adjusted. Depending on the desired color location different fluorescent pigments are introduced into the binder.

The color filter layer is preferably provided on a carrier film, so that the base film remains unchanged. Only the carrier foil with the color filter layer is attached to it.

The carrier film is advantageously made of polyester.

In order to achieve optimum protection of the electroluminescent film, it is advantageously laminated.

The side of the carrier foil opposite the color filter layer is expediently provided with a layer which determines the incident light color of the electroluminescent foil. Advantageously, this layer consists of white fluorescent color. Then the electroluminescent film has a neutral, whitish hue when switched off. It is of course possible to make this layer so that the electroluminescent in the off state has a hue. Then fluorescent color particles are accommodated in this layer.

The fluorescent pigments are advantageously uniformly distributed in the color filter layer, so that the light emitted by the electroluminescent film has a uniform luminance.

But it is also possible that the fluorescent pigments are not evenly distributed in the color filter layer. Then a course of the light intensity can be adjusted.

Further features of the invention will become apparent from the other claims, the description and the drawings.

Fig. 1

in schematischer Darstellung und im Schnitt eine erfindungsgemäße Elektrolumineszenzfolie,

Fig. 2

in schematischer Darstellung und in Seitenansicht verschiedene Schichten der Elektrolumineszenzfolie,

Fig. 3

in explosiver Darstellung die verschiedenen Schichten der erfindungsgemäßen Elektrolumineszenzfolie.

The invention will be explained in more detail with reference to an embodiment shown in the drawings. Show it

Fig. 1

in schematic representation and in section an electroluminescent film according to the invention,

Fig. 2

in schematic representation and in side view different layers of the electroluminescent film,

Fig. 3

in an explosive representation of the various layers of the electroluminescent film according to the invention.

The electroluminescent film forms a planar illuminant that can emit light in different shades depending on the training. Such electroluminescent films are advantageously used in the automotive sector, for example in the interior of a motor vehicle. For example, electroluminescent films can be used on the headlining, as marking lights on door handles and the like.

The electroluminescent film has a base film 1 which, when switched on, emits colored light, for example green light. In the installed position, this base film 1 forms the back of the electroluminescent film. On the one side 2 of the base film 1 is a color filter 3, with which the desired color of the light emitted by the electroluminescent film light can be adjusted. The color filter 3 is located on one side of a carrier film 4, which covers the color filter 3. It contains fluorescent pigments 5 which are embedded in a binder 6. The proportion of pigment 5 to binder 6 is chosen as a function of the desired color saturation.

The color filter 3 is applied to the carrier film 4 in a printing process. The printer or developer can adjust the color on-site according to the customer's request. This makes it possible to meet very quickly the customer's wishes regarding the color of the energized electroluminescent. During the printing process a direct influence on the color tone is possible. Because the printing process is well controlled can, the rejection rates in the production of this electroluminescent are low. In the printing process, the color pigments can be optimally arranged. For example, a uniform areal coverage of the carrier film 4 with the fluorescent pigments 5 is possible. However, color gradients in the printing process can also be generated simply and reliably. The color gradients can have different designs and / or permeabilities according to customer requirements.

The color filter 3 can also be connected to the carrier film 4 by lamination.

The carrier film 4 is made of a material which ensures optimum adhesion of the fluorescent pigments 5 or of the binder 6. The carrier film 4 consists for example of polyester. But it can also consist of any other transparent material that ensures adhesion of the pigments 5 and the binder 6.

On the opposite side of the color filter 3, the carrier film 4 is provided with a fluorescent layer 7, which is more or less highly pigmented. In the exemplary embodiment, this fluorescent layer is white, so designed achromatic, so that the passing through the layer 7 to the outside light is not changed in its hue. If the electroluminescent film is not energized, then it has on the outside through the layer 7 a white color. The so-called incident light color of the electroluminescent film is thus white in this case. The layer 7 is advantageously attached to the carrier film 4 by screen printing.

Of course, depending on the application, the fluorescent layer 7 may also have a hue, so that the electroluminescent film in the non-energized state has, for example, a yellow, a blue or an orange hue as incident light color. Of course, the electroluminescent film then has a corresponding luminous color.

In the described embodiment, the achromatic, white fluorescent color of the layer 7 has no or only a negligible influence on the hue of the electroluminescent in the energized state.

So that the electroluminescent film is optimally protected and in particular also has a high moisture stability, it is advantageously coated by a laminate (not shown), so that the electroluminescent film has a long service life even under harsh operating conditions.

The carrier film 4 with the printed color filter 3 is fixed on the upper side 2 of the base film 1 in a known manner.

The base film 1 emits when energized according to their color light 8 (Figure 2), which penetrates the color filter 3. According to the fluorescent pigments 5 in the color filter 3, the color tone after passing through the color filter 3 is changed. Thus, for example, the green hue of the light originating from the base film 1 after passing through the color filter 3 can assume an orange hue. When passing the light beams 9 through the carrier film 4 and the layer 7, the hue is not changed, so that at the layer 7, the light in the color filter 3 determined by the color emerges.

In the color filter 3, the most different fluorescent particles can be provided, so that all luminous colors can be adjusted. It is even possible to use within the color filter 3 areas of different colored fluorescent pigments, so that at the layer 7 differently colored light emerges. The distribution of differently colored fluorescent pigments 5 in the color filter 3 can be produced very accurately and in a wide variety of forms by means of the printing process.

It is possible to provide the color filter 3 only partially on the carrier film 4, so that it does not cover the entire outside of the carrier film.

The color filter 3 absorbs a portion of the light emitted from the base film 1 1 and leaves the rest of this light as a residual light 9 through.

As the fluorescent pigments, any suitable pigments can be used for the color filter 3 and the layer 7. All suitable binders can be used for binding the pigments. However, they must not have any influence on the pigment quality.

Depending on the desired color density, the proportion of pigment and binder in the electroluminescent film is about 10% to about 70%.

Claims (13)

Electroluminescent film with a base film which emits light when energized,
characterized in that in the beam path of the base film (1) at least one color filter layer (3), which absorbs a part of the base film (1) radiated light (8) and a part (9) passes under changing the hue of the light. Electroluminescent film according to claim 1,
characterized in that the color filter layer (3) has fluorescent, embedded in a binder (6) pigments (5). Electroluminescent film according to claim 1 or 2,
characterized in that the color filter layer (3) is provided on a carrier film (4). Electroluminescent film according to claim 3,
characterized in that the carrier film (4) consists of polyester. Electroluminescent film according to one of Claims 1 to 4,
characterized in that the electroluminescent film is laminated. Electroluminescent film according to one of claims 3 to 5,
characterized in that the carrier film (4) on its side remote from the color filter layer (3) side is provided with a reflective color of the electroluminescent film determining layer (7). Electroluminescent film according to Claim 6,
characterized in that the layer (7) contains fluorescent pigments. Electroluminescent film according to one of claims 1 to 7,
characterized in that the color filter layer (3) over the entire surface of the base film (1) is provided. Electroluminescent film according to one of claims 2 to 8,
characterized in that the fluorescent pigments (5) are arranged uniformly distributed in the color filter layer (3). Electroluminescent film according to one of claims 1 to 8,
characterized in that the fluorescent pigments (5) in the color filter layer (3) are arranged so that a gradient results. Process for producing an electroluminescent film according to one of Claims 1 to 10, in which at least one base film which radiates light when current is supplied is produced,
characterized in that a color filter layer (3) is printed on a carrier film (4), which is then connected to the base film (1). Method according to claim 11,
characterized in that on the carrier film (4) a Auflichtfarbe when not energized Elektrolumineszenzfolie determining layer (7) is applied. Method according to claim 12,
characterized in that the layer (7) before the connection of the carrier film (4) with the base film (1) is applied.

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