DE1076815B - Electroluminescent light cell - Google Patents

Description

Electroluminescent Leuditz cells are already known in which between two large-area parallel electrodes, at least one of which the Lets pass through, a phosphor is provided, which under the action of a on the electrodes applied AC voltage lights up. The clear electrode is usually made by that an insulating base plate made of transparent insulating material, e.g. glass or a plastic, covered with a conductive layer. ' This conductive layer as an electrode forms together with a just such a boundary surface or an opaque metallic conductive base plate with the between them provided fluorescent the luminous cell.

It is already known that it is advantageous to use a binding agent for the phosphor in the case of luminous cells a high dielectric constant to use.

With such light cells, D es tri au has established that the amount of light emitted is at an alternating voltage given frequency, with the field strength occurring on the phosphor increases rapidly. An electroluminescent Light cell that has a good λ effect should work, can therefore only be operated with a large electric field strength. With regard to that in practice the voltage that can be applied to the cell is equal to the mains voltage, e.g. B. 220 volts a large electric field strength can only be achieved with a layer that is as thin as possible.

The necessary field strength is in almost every case above the dielectric strength of the air, with alternating voltage about 21 kV / cm. Care must therefore be taken that even the most idiosyncratic traces removed from the cell by air. For this purpose, the luminous layer is expediently designed in such a way that that the phosphor consisting of the smallest grains of powder, together with organic Binders, to form a thin, film-like layer, with the electrodes supplying the voltage be connected to the two sides of this layer.

However, this embodiment has the disadvantage that with regard to the use of phosphors of the ZnS type, which has a dielectric constant of more than 12, while the dielectric constant of the binder serving as a filler is generally smaller, the voltage applied to the cell ·, depending on the dielectric Constants, the binder to a higher degree, the phosphor only to a lesser extent Degree claimed. Zxir achievement of a corresponding The field strength was either the mains voltage was insufficient or one was forced to to reduce the electrode spacing such that

Electroluminescent light cell

Applicant:

Egyesält Izzolampa es Villamossägi

Reszvenytärsasag,

Budapest

Representative: Dipl.-Ing. W. Meissner,

Berlin-Grunewald, Herbertstr. 22

and Dipl.-Ing. H. Tischer, Munich 2, patent attorneys

Dipl.-Ing. Elemer Nagy and Dr. Janos Szabo, Budapest, have been named as inventors

again the production of a correspondingly thin layer encountered technical difficulties, or there was the danger of air discharges

^a 5 enlarged between the leads of the electrodes.

Now electroluminescent cells are also known,

in which the luminescent material is in glass or in vitreous enamel nuts instead of organic binders is embedded. The production of such vitreous enamels is difficult, however.

In addition, these substances adversely affect the properties of the luminous powder, and it is theirs The relative dielectric constant is too low, but its dielectric loss is too high, which in turn leads to difficulties.

The purpose of the invention is to avoid the above difficulties and an electroluminescent Produce light cells, which with the normal mains voltages with an economical Lumeri-Watt value can be operated.

The invention also aims to increase the light output of electroluminescent light cells.

In the case of an electroluminescent light heat cell, in which between two electrically conductive electrodes there is a low ^{resistance of no more than 10 s} ohms per square area, of which at least one is translucent or transparent, a single, with both electrodes in direct contact, suitable for lighting, a If a layer containing luminous powder embedded in a binder is present, according to the invention this layer contains an additional powdered inorganic filler which is likewise embedded in the binder and whose dielectric constant is at least

909 758/225

20, advantageously at least 50, and its dielectric Loss is not more than 0.2, advantageously not more than 0.1, and that in a minimum of 10%, but at most 200%, the amount of the luminous powder amount and a grain size of at most 5 μ, advantageously at most 1 μ, is present in the layer.

The amounts of the filler and the luminous powder are expediently at least approximately like 3: 4.

The filler can, at least in part, be an oxide of an element of Group IV of the Periodic Systems, such as B. titanium dioxide or zirconium dioxide.

The filler can also, at least in part, at least be one of the following compounds, in particular with an alkaline earth metal: titanate, zirconate, Hafnate, niobate, advantageously baraumtitanate.

The luminous layer can contain any desired mixture of the aforementioned fillers.

At least in part, nitrocellulose can be used as a binder.

In general, the binder is a mixture of nitrocellulose and / or a condensation synthetic resin and a polymerization resin, e.g. B. polyester.

ZnS can be used as a luminescent material in the luminous cell.

In more general terms, it has been found that, in order to achieve the aforementioned purposes, the space between the electrodes is to be filled with a filler whose dielectric constant is essential higher than that of the phosphor powder. It was also found that if this filler had a grain size which is finer by at least one order of magnitude than that of the fluorescent powder, this filler with the finer grain size creates the spaces between the grains of the phosphor powder with a good shape fill factor, so that the amount of organic matter required is at least is an order of magnitude smaller than was previously necessary. This ensures that when generating an electric field a much larger part of the total voltage on the phosphor and only one a much smaller part of this tension falls on the binder. This does not include the filler, due to its high dielectric constant, no or practically negligible voltage.

Since the grain size of the luminescent material expediently tends to be larger than 5 μ, the grain size is the The filler according to the invention is advantageously less than 5μ, for example 1 to 2μ or less.

Any inorganic filler is suitable for the electroluminescent light cell according to the invention Compound which does not adversely affect the functioning of the cell and which meets the above conditions.

Cellulose derivatives, e.g. nitrocellulose or similar substances, are advantageously used as binders. However, you can also use binders, which in addition to e.g. collodion or condensation synthetic resins also a polymerization resin, e.g. B. contain a polyester.

To produce a luminous tile according to the invention, z. B. a phosphor with a grain size of e.g. 8μ, advantageous e.g. ZnS, before production the layer with an inorganic powdery substance with a grain size of less than 5 μ, and with a correspondingly large dielectric constant, e.g. B. with barium titanate corresponding amount intimately mixed, then this mixture and one, if necessary with plasticizers or also other organic additives provided binders and a solvent made a suspension and this suspension by atomization or in some other manner known per se between the Electrodes e.g. B. with a layer thickness of 25 to 200μ, advantageously e.g. 50μ, then applied Solvent removed by evaporation. As a binder, e.g. B. in a known manner Collodion can be mixed with dibutyl phthalate as a plasticizer, but any can be used use a different nitrocellulose varnish or other similar material.

The solvent can advantageously be butyl acetate, but it can also be any other per se use a known solvent.

example 1

There are 100 g of Zn S luminous powder with a maximum grain size of 20 μ with 125 g of titanium dioxide a maximum grain size of 0.2 μ and 150 g of binder are intimately mixed with one another. This mixture is made with 101 of a 150 g plasticizer containing solvent mixed and made a suspension from the mixture. The suspension is applied between the electrodes with a layer thickness of 25 μ.

Example2

There are 100 g of zinc cadmium sulfide powder with a maximum grain size of 30 μ, 80 g of filler (50% barium titanate + 50% strontium titanate) with a maximum grain size of 0.5 to 1.5 μ and 200 g of binder are intimately mixed with one another. From this mixture, similar to that described in Example 1, a suspension made and this between the electrodes with a layer thickness of 55 μ applied.

Example 3

There are 100 g of zinc sulphoselenide luminous powder with a grain size of a maximum of 14 μ, 200 g of filler (a mixture of titanium dioxide, zirconium dioxide and strontium titanate) with a maximum coriir size from 0.3 to 1.1 μ and 220 g of binder mixed together. From this mixture, as in Example 1 described, a suspension prepared and this between the electrodes with a layer thickness of 38 μ applied.

Example4

There are 100 g of ZnS luminous powder with a maximum grain size of 27 μ filler (80% magnesium titanate-r-20% Barium zirconate) with a maximum grain size of 2 to 4 μ and 180 g of binder intimately mixed with each other. From this mixture with the help of a solvent, as in Example 1 described, a suspension prepared and this between the electrodes with a layer thickness of 100 μ applied.

The electroluminescent cell according to the invention, as described above with reference to the examples, can with a voltage of 220VoIt can be operated. the The light output of the new cell is quite high compared to that of known cells. The efficiency the cell is approximately 4 to 5 lumens / watt and can even be much larger. Also is the cell is free of breakdowns and is easy to use Manufacturing.

An exemplary embodiment of the invention is described in more detail below with reference to the drawing.

In the illustration of the drawing, 1 and 2 denote the carriers of the two electrodes, which, for. B. can be made of glass or any plastic. At least one of these supports must be a transparent or a translucent support. These carriers made of an insulating material are each provided with a conductive layer 3 or 4 in a manner known per se. At least one of these layers is transparent or translucent, the latter allowing most of the light to pass through. This transparent or translucent conductor layer is of course provided on the likewise transparent or translucent carrier made of insulating material. As such conductor layers, amorphous oxides of cadmium or tin can be used in a manner known per se. Of course, the insulating support 1 and 2 provided with the conductive layers 3 and 4 can be replaced by such a transparent or translucent material which is itself conductive. B. can be a metallic plate, as is known in electroluminescent cells. The two electrodes are advantageously held together by a frame 7 made on the insulating material. The conductors 5 and 6 serve as power supply lines. 8 is the layer of the phosphor. According to the invention, this layer is composed in such a way that, in addition to an electroluminescent substance and a binder, it also contains an inorganic filler whose dielectric constant is at least 20 ¹ and whose dielectric loss is at most 0.2.

The preceding information is not intended to limit the invention. So may. B. any other Filler, even a mixture of fillers, can be used. The same is true for the binder, there this can also be any other substance or any other mixture. Instead of the Any other electroluminescent phosphor of the ZnS type given in the examples Fluorescent material can be used. The shape of the light cell can also be any. Can do the same the light cell can also be produced differently than described in the examples.

Claims (8)

Patent claims: 1. Electroluminescent light cell, in which between two electrically conductive electrodes the usual low ^{resistance of a maximum of 10 3} ohms per square area, of which at least one is translucent or transparent, a single, with both electrodes in direct contact, suitable for lighting, a layer containing luminous powder embedded in a binder is present, characterized in that this layer contains an additional powdery inorganic filler also embedded in the binder, the dielectric constant of which is at least 20, advantageously at least 50, and its dielectric loss at most 0.2, advantageously at most 0.1, and which ^{is present in the layer in an amount of at least 10 1} Vo, but at most 200%, of the amount of luminous powder and a grain size of at most 5 μ, advantageously at most 1 μ. 2. Electroluminescent light cell according to claim 1, characterized in that the Amounts of filler and luminescent powder are at least approximately 3: 4. 3. Electrolium luminescent light cell according to claim 1 or 2, characterized in that the filler, at least in part, an oxide of one Element of group IV of the periodic table, such as B. titanium dioxide or zirconium dioxide is. 4. Electroluminescent light cell according to claim 1 or 2, characterized in that the Filler, at least in part, at least one of the following compounds, in particular with an alkaline earth metal is: titanate, zirconate, hafnate, niobate, advantageously barium titanate. 5. Electroluminescent light cell according to one of claims 1 to 4, characterized in that that their luminous layer contains any mixture of the fillers according to claims 3 and 4. 6. Electroluminescent light cell according to one of claims 1 to 5, characterized in that that the binder is, at least in part, nitrocellulose. 7. Electroluminescent light cell according to one of claims 1 to 6, characterized in that that the binder is a mixture of nitrocellulose and / or a condensate synthetic resin and a polymerization resin, e.g. B. polyester. 8. Electroluminescent light cell according to one of claims 1 to 7, characterized by the Use of Zn S as a phosphor. Considered publications:
Belgian Patent No. 497,702;
French patent specification No. 1,116,612. 1 sheet of drawings 909 758/225 2.60