DE29708997U1 - Electroluminescent light - Google Patents

Description

WORU-OIgDE .,

21 May 1997 * f I IJ:.. ',"I '",

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DESCRIPTION

Electroluminescent lamp TECHNICAL FIELD

The invention relates to an electroluminescent lamp. Such lamps use the luminous phenomenon that occurs when a phosphor is subjected to an alternating electric field. The phosphor is made to glow by the alternating field. To make the glow visible, one of the electrodes is made transparent. By varying the excitation frequency and the phosphor, the luminous color can be varied.

STATE OF THE ART

In one well-known type of electroluminescent lamp, the non-transparent electrode is made of metallic material. A base enamel is applied to this material and then the luminescent layer is applied as a transparent enamel layer. Such "metallic" electroluminescent lamps are particularly durable and have a long service life and high luminosity.

DESCRIPTION OF THE INVENTION

Based on this prior art, the invention is based on the object of specifying an improved electroluminescent lamp on a metallic basis.

This invention is defined by the features of claim 1. The invention therefore includes in particular that an enamel layer is applied directly to the metallic electrode. 35

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is applied as a direct enamel. The luminescent layer is then applied to this direct enamel. This luminescent layer consists of a mixture of transparent enamel powder and known electroluminescent pigments. This mixture is either made screen-printable by adding screen printing oil and applied using the screen printing process, or the mixture is made sprayable by adding water and applied directly to the direct enamel using the spray process. After drying, this luminescent layer is fired. A firing temperature of a maximum of 560 degrees Celsius is sufficient. At this temperature, the electroluminescent pigments (EL pigments) do not yet lose their brightness. The transparent insulating layer made of, for example, silicon nitride (S13N4) or tantalum oxide (Ta2Ü5) is then applied to this luminescent layer. The transparent electrode forms the final layer. This type of layer structure makes it possible to make the insulating layer very thin. In conjunction with a highly conductive metallic electrode, such a lamp can be made to glow using a very low electrical current.

It has proven advantageous to manufacture the metallic electrode from nickel-plated sheet metal or stainless steel.

A very economical manufacturing process and a very high-performance lamp are characterized in particular by the fact that the enamel layer applied as a direct enamel can also be applied using a spraying process or screen printing. Metal pigments can be added to this enamel layer, which serves as a reflective layer to increase the luminosity, before firing. The amount of

WQRU-QIgDE
21 May 1997

Metal pigments preferably make up between 5% and 40% of the enamel layer. The metal pigments can consist of up to 100% indium tin oxides.

For the luminescent layer, the ratio of enamel to pigments is approximately 20:30 to 80:70%.

According to an embodiment also shown in the drawing, the transparent insulating layer advantageously consists of a color and/or lacquer layer. The transparent electrode consists in particular of known materials of the indium-tin system. As is known per se, the transparent electrode can be produced, for example, by a membrane-forming process, such as in particular by reactive sputtering in a high vacuum.

In order to distribute the electrical voltage evenly in the transparent electrode, an electrically conductive coating can be applied to the edge area of the transparent electrode. This coating is present in particular as a surrounding frame and can be connected to one pole of the electrical alternating voltage source. This coating frame is advantageously made of silver.

To protect such an electroluminescent lamp from the weather, an outer casing can be provided as a water vapor barrier. Such a lamp can then be used as a tile, for example. The tile can have the function of an information sign. For example, a street name or a house number can be applied to such a tile.

Further advantages and features of the invention result from the features further listed in the claims and from the following exemplary embodiment.

WORU-OIgDE 21 May 1997

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SHORT DESCRIPTION OF THE DRAWING

The invention is described in more detail using the embodiment shown in the drawing. The single figure shows a schematic view of a tile with a schematic layer structure according to the invention.

WAYS TO CARRY OUT THE INVENTION

The only figure 1 shows a tile 10 with a layer structure according to the invention that is not to scale with regard to the layer thickness.

In the present example, a metallic electrode 12 consists of a nickel-plated sheet. It could also be made of stainless steel, for example. This electrode 12 is connected to one pole 13 of an alternating voltage source 16. The thickness of this metallic electrode 12 can be relatively thin and depends only on the mechanical strength requirements and thus the intended use of this tile 10.

A titanium white, direct enamel layer 14 is applied to the electrode 12. In this case, it is not necessary to apply a base enamel coating to the metal electrode beforehand. This so-called direct enamel can be applied using a spraying process or screen printing. It is baked into the electrode 12 at approx. 820 degrees Celsius. This enamel layer 14 serves as a reflective layer and thereby increases the luminosity. In order to change the electrical resistance in this direct enamel layer, which determines the luminosity and also the electrical voltage, metal pigments are used.

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present in this direct enamel layer 14. These pigments were added before firing. The pigments in this case consist of indium tin oxide. Their proportion is between 5% and 40% of the direct enamel layer quantity.

An electroluminescent light layer 18 is present on the direct enamel layer 14. This layer 18 is a second enamel layer. It is composed of a transparent enamel powder, a so-called aluminum transparent enamel. This aluminum transparent enamel 1 was originally developed for coating aluminum. It has been found that this transparent enamel 1 can be applied excellently to the titanium white direct enamel layer mentioned above. This electroluminescent light layer (EL light layer) 18 consists of the above-mentioned transparent enamel powder and electroluminescent pigments (EL pigments). In the present example, EL pigments from Osram Sylvania Inc. with the types EL10, EL20, EL30, EL40, EL50, EL60, EL21, EL22, EL23, EL31, EL41, EL51 were used. The ratio of enamel powder to these pigments is approximately 20:80 to 30:70. To apply this layer 18 to layer 14, either a screen printing oil is added to this mixture of transparent enamel powder and EL pigments so that the mixture can be applied to layer 14 using the screen printing process, or water is added to the mixture of transparent enamel powder and EL pigments so that the mixture then contained can be sprayed onto layer 14 using, for example, a spray gun. Layer 18 is then dried. Layer 18 can then be fired into layer 14 in an oven at just 560 degrees Celsius. A higher firing temperature is not required. This means that the EL pigments used do not lose their brightness.

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A transparent insulating layer is then applied to the EL luminous layer 18, which also covers the metallic electrode 12. The insulating layer consists of the known compound S13N4 or Ta ₂ O ₅ or comparable compounds. When enamel is fired, small bubbles form inside which can, under certain circumstances, cause the applied electrical voltage to break through. This breakdown is prevented by the insulating layer 2 0. This insulating layer can be applied very thinly, thus keeping its electrical resistance low.

The transparent electrode 22 is applied to this transparent insulating layer 20. Manufacturing processes for this transparent electrode are known. For example, such a transparent electrode can be manufactured by membrane-forming processes, such as in particular by reactive sputtering in a high vacuum. Such an electrode is referred to, for example, as an ITO electrode.

A surrounding frame 24 made of silver material is applied to the electrode 22. This frame 24 is connected to the other pole 26 of the alternating voltage source 16. The current is thus absorbed through the frame 24 and the metallic electrode 12. The frame 24 enables a uniform voltage distribution in the transparent electrode 22.

All of the above layers are surrounded by a water vapor barrier layer 28. In this case, this barrier layer consists of optically translucent plastic paint in which the layered body has been immersed.

Claims (1)

WORU-QIgDE 21 May 1997 * Z*"l I *,*,,* '.I , -1-CLAIMS 01) Electroluminescent lamp (10) with - an electroluminescent light layer (18) between two electrodes (12, 22) connectable to an electrical alternating voltage source (16), of which one electrode (22) is transparent, - an electrical insulating layer (20) between the electrodes (12, 22), - a second, non-transparent electrode (12) made of metallic material, which is provided with an enamel layer (14), characterized in that - the enamel layer (14) is a titanium white direct enamel, - on this enamel layer (14) there is a luminescent layer (18) consisting of a mixture of transparent enamel powder and electroluminescent pigments, - this luminous layer (18) is screen-printable by adding screen-printing oil and is applied using the screen-printing process, or is sprayable by adding water and is applied using the spraying process, - the luminescent layer (18) is burned into the enamel layer (14), - the transparent insulating layer (20) is present on this luminescent layer (18), - the transparent electrode (22) is present on this insulating layer (20). 02) Luminaire according to claim 1, characterized in that - the metallic electrode (12) is made of nickel-plated sheet metal or stainless steel. WORU-OIgDE
21 May 1997 -2 — 03) Luminaire according to one of the preceding claims, characterized in that - the enamel layer (14) is applied by spraying or screen printing and fired. 04) Luminaire according to one of the preceding claims, characterized in that - the enamel layer (14) contains metal pigments (17). 05) Luminaire according to claim 4, characterized in that - the quantity of metallic pigments (17) is 5 % to 40 % of the enamel layer quantity. 06) Luminaire according to claim 5, characterized in that - the metal pigments (17) consist of up to 100 % indium tin oxides. 07) Luminaire according to one of the preceding claims, characterized in that - in the luminescent layer (18) the ratio of enamel powder to EL pigments is approximately 20:80 to approximately 30:70. 08) Luminaire according to one of the preceding claims, characterized in that - the transparent insulating layer (20) contains either silicon nitride (S13N4) or tantalum oxide (Ta2Ü5). 09) Luminaire according to one of the preceding claims, characterized in that - the transparent electrode (22) consists of materials of the indium-tin system. -3- 10) Luminaire according to claim 9, characterized in that - the transparent electrode (22) is produced by a membrane-forming process, in particular by reactive sputtering in a high vacuum. 11) Luminaire according to one of the preceding claims, characterized in that - an electrically conductive coating (24) is present on the upper edge region of the transparent electrode (22), - this coating (24) is present as a surrounding frame and can be connected to a pole (26) of the electrical alternating voltage source (16). 12) Luminaire according to claim 11, characterized in that - the coating (24) consists of silver. 13) Luminaire according to one of the preceding claims, characterized in that - an outer covering as a water vapor barrier layer (28) is present. 14) Luminaire according to claim 13, characterized in that - the water vapor barrier layer (28) is a plastic paint coating.