DE1950136C3 - Process for applying a phosphor layer to a support - Google Patents

Description

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The invention relates to a method for applying a phosphor layer to a carrier, in which a fine-grained luminescent solid with a very fine-grained non-luminescent solid mixed and with the help of a suspension of this mixture in one of at least two organic Liquids built-up suspension liquid, which also temporarily contains a binder, so with the carrier is brought into contact that a suspension layer adheres to this carrier, after which the not adhering suspension residue is removed and the suspension layer adhering to the carrier is dried and is then sintered.

For many purposes, e.g. in the production of Gas discharge lamps, such as low-pressure and high-pressure mercury-vapor discharge lamps, it is necessary that a carrier, e.g. B. a glass flask, with a well-adhering made up of phosphor grains Layer is coated. The distribution of the grain size in the phosphor depends on the type of lamp, however it is almost always chosen such that at least 950/0 of the amount by weight of the phosphor has a grain size between 6 and 40 ^ m

Such a fine phosphor cannot easily be attached to a support because many conditions must be met at the same time. One of the most important conditions is that the adhesion to the carrier in the finished product must be particularly good. Furthermore, the distribution of the grains in the luminous layer must be particularly uniform so that a uniform light emission over the entire surface of the support and an aesthetic appearance of the product is obtained. B. can be applied by electrostatic coating in the dry state on the carrier (DT-AS 11 77 269), it is more common to apply this substance with the help of a suspension of the phosphor. The suspension is brought into contact with the carrier to which part of the suspension adheres, after which the residue of the suspension is removed. Such a method is e.g. B. almost always applied when covering the wall of tubular low-pressure mercury-vapor discharge lamps. This coating takes place, for. B. in that a suspension liquid column either by injection from above or by pushing up from below wirti introduced into the vertically arranged tubular S-piston. Then, the adhesive on the wall layer is sintered and then dried at a temperature of 25 to 6O ⁰ C, d. This means that it is heated to a temperature of 400 to 600 ^{° C. for 90 to 240 seconds.}

In processes in which a suspension is used, the latter mostly contains a binder, in particular Nitrocellulose or ethyl cellulose. This binder is only used temporarily, namely in order to ensure that the phosphor grains adhere to the support as long as the layer has not yet been sintered. After that, will the binder is no longer required because the adhesion then takes place in another way, namely by van der Waals forces, can be achieved. The temporary binder may therefore disappear during sintering. In particular, when using nitrocellulose or ethyl cellulose, the binding agent disappears leaving practically no traces during sintering.

The temporary binder must be soluble in the suspending medium in order for it to pass over in a satisfactory manner the phosphor bodies distributed and a uniform coating of the carrier can be achieved. A such solvent is e.g. B. butyl acetate or xylene. During drying of the suspension adhering to the carrier the solvent of the binder evaporates and the phosphor grains adhere with the aid of the binder on the carrier.

Although, as mentioned above, the ultimate adhesion of the phosphor to the support, e.g. B. at the Glass wall of a discharge tube, achieved only by Van der Waals forces, i.e. without binding agents can be, it is known that the adhesion, especially coarser powder, through the use can be significantly improved by permanent binders

which effect or improve the binding of the phosphor to the carrier in the finished product and bring about mutual adhesion of the phosphor grains (US Pat. No. 33 16,109). For example, very fine-grain aluminum oxide, ie aluminum oxide with a grain size of about 0.02 μm, is used as a permanent binder. The amount of aluminum oxide is preferably 0.1 to 1.0 percent by weight, based on the amount of phosphor.

The aluminum oxide must be mixed very intimately with the phosphor and preferably simultaneously with it this substance can be applied to the carrier. Therefore, the alumina is used in the known method also introduced into the suspension. Two solids must therefore be very different in the suspension Type and grain size can be dispersed. In addition, there must also be a temporary in the suspension Binder be soluble because the aluminum oxide does not take over the function of the temporary binder can. It has been found that only then can these conditions be satisfied in a satisfactory manner when a suspension medium composed of more than one component is used. When Suspending medium is therefore a mixture of xylene and butanol used as a temporary binder Contains ethyl cellulose. The main purpose of the butanol is to ensure that the powder mixture turns out to be smooth coating is deposited on the carrier; the xylene serves mainly as a solvent for the ethyl cellulose.

The known process described above has the major disadvantage that xylene is particularly toxic and is very flammable. As a result, special precautions must be taken to protect the Workers are hit, which entails high costs.

If in the known method described above, the ethyl cellulose by nitrocellulose is replaced, there is not only the disadvantage associated with the use of xylene, but also a great one Disadvantage for the finished product itself, namely the formation of an uneven cloud-like coating on the carrier.

The invention has the task of creating a method with which without special safety measures uniform, well-adhering phosphor layers can be applied to the carrier.

According to the invention, this object is achieved by a method of the type mentioned at the outset, which characterized in that the suspension liquid is at least 50 and at most 98 percent by volume from a non-polar organic non-aromatic liquid and at least 2 and at most 50 Percent by volume of a non-aromatic liquid with one due to the presence of at least one Hydroxyl group consists of polar character, both liquids being a solvent for the intermittent Binders are.

The fact that in the process according to the invention as a non-polar component in the suspension medium organic non-aromatic liquid, e.g. B. butyl acetate instead of z. B. xylene is used, the above already mentioned difficulties with regard to toxicity and flammability avoided.

By using a polar non-aromatic liquid in which the temporary binder is soluble, very uniform, well-adhering, smooth luminous layers are obtained even when using nitrocellulose. The butanol used by the known method described above is a liquid which Although it has a polar character due to the presence of a hydroxyl group, it is not a solvent for Nitrocellulose is extensive studies have shown that the uneven cloud-like coating when using nitrocellulose and butanol, this can be attributed to the insolubility of the nitrocellulose in butanol When the suspension layer adhering to the carrier dries, the xylene evaporates more quickly than the butanol. The layer becomes relatively richer in butanol as it dries, which means that the Nitrocellulose, which is insoluble in it, flocculates in a given instant

A substance that is an ether is preferably chosen as the polar liquid. Excellent results were obtained with glycol monomethyl ether; other suitable substances are esters of lactic acid or Hydroxyacetic acid, e.g. B. M-ethyl esters thereof.

In the method according to the invention, as a non-luminescent solid z. For example, aluminum oxide, magnesium oxide, titanium dioxide, magnesium pyrophosphate, calcium pyrophosphate or barium pyrophosphate are used and found. Aluminum oxide generally gives a smaller drop in light than the other substances. The grain size of these substances is preferably less than 1 / nn, and the distribution of the grain size is preferably such that at least 50% of the substance has a grain size of less than 0.15 μm .

Preferably, a suspension is used in which the suspension liquid from 80 to 98 percent by volume non-polar liquid and 20 to 2 percent by volume of polar liquid, both quantities are given related to the liquid phase. In this suspension, 0.7 to 2.5 percent by weight of nitrocellulose are dissolved and 0.2 dispersed up to 1 percent by weight of aluminum. The percentages of nitrocellulose and alumina are based on the amount of the phosphor to be suspended. A with such a suspension very well adhering, smooth and uniform luminous layers made of very different luminous substances, such as B. alkaline earth phosphates, germanates and arsenates are obtained. Per liter of suspension liquid can be suspended from 500 to 1500 g fluorescent powder.

After the sintering of the luminescent layer with the very fine-grained material present in it, the Carrier, e.g. B. a glass tube forming the wall of a low-pressure mercury-vapor discharge lamp usual way to be processed into an end product.

The invention is illustrated below with the aid of two examples of compositions of suspensions for covering low-pressure mercury vapor discharge lamps.

example 1

45 g Al ₂ O ₃ ,

45 kg of luminescent calcium halophosphate,
■ 151butyl acetate,

1 l glycol monomethyl ether,
1.5 liters of nitrocellulose solution (obtained by dissolving 2 kg of nitrocellulose in a mixture of 95 liters of butyl acetate and 51 glycol monomethyl ether)

are inserted into a vessel.

The mixture in the vessel is then 2 minutes at a speed of 900 revolutions / mi

ute stirred; then it is stirred for 2 minutes at a speed of 2000 revolutions / minute Thereafter, while stirring at a speed of 900 revolutions / minute 21 1 of the above already mentioned nitrocellulose solution added and 2 Stirred for up to 5 minutes.

If necessary, ethyl lactate can then be added to the suspension obtained. This addition gives possibly an even smoother coating in the manufacture of lamps, which is briefly described below is described.

Example 2

45 g Al ₂ O ₃ ,

45 kg of luminescent calcium halophosphate,
151 butyl acetate,
11 glycol monomethyl ether,
1.51 of an ethyl cellulose solution (obtained by dissolving 5 kg of ethyl cellulose in a mixture of 95 liters of butyl acetate and 5 liters of glycol monomethyl ether)

are inserted into a vessel.

The mixture in the vessel is then stirred for 2 minutes at a speed of 900 revolutions / minute; then it is stirred for 2 minutes at a speed of 2000 revolutions / minute. There-

15th

20 to 2531 of the above-mentioned ethyl cellulose solution, 101 butyl acetate and 0.51 of glycol monomethyl ether are added with stirring at a speed of 900 revolutions / minute and the mixture is stirred for a further 2 to 5 minutes

If necessary, this suspension can also have 3! Ethyl lactate can be added.

The suspensions obtained according to Example 1 or Example 2 can be used for the production of low-pressure mercury vapor discharge lamps by the process mentioned in the introduction. This process can be briefly summarized as follows: The starting point is a glass tube which is arranged in a vertical position and into which a column of a suspension prepared according to one of the two examples is introduced. The excess of suspension which does not adhere to the wall is allowed to drain off, after which the suspension layer adhering to the wall z. B. dried by the introduction of warm air and the dried tube is placed in a sintering furnace. In this sintering furnace, the tube with the layer adhering to the wall is ^{heated to a temperature between 400 and 600 °} C. for 1.5 to 4 minutes. After this heating, the tube can be further processed in the usual way to form a low-pressure mercury vapor discharge lamp.

Claims (7)

Patent claims: 1. A method for applying a phosphor layer on a support, in which a fine-grained luminescent solid is mixed with a very fine-grained non-luminescent solid and with the aid of a suspension of this mixture in a suspension liquid composed of at least two organic liquids which also temporarily contains a binder the carrier is brought into contact so that a suspension layer adheres to this carrier, after which the non-adhering suspension residue is removed and the suspension layer adhering to the carrier is dried and then sintered, characterized in that the suspension liquid consists of at least 50 and at most 98 percent by volume of a non-polar organic non-aromatic liquid and at least 2 and at most 50 percent by volume of a non-aromatic liquid with a polar character due to the presence of at least one hydroxyl group, both liquids en are a solvent for the temporary binder. 2. The method according to claim I, characterized in that that the polar liquid is an ether. 3. The method according to claim 2, characterized in that the polar liquid glycol monomethyl ether is. 4. The method according to claim 1, 2 or 3, characterized in that the temporary binder Is nitrocellulose. 5. The method according to claim 1, 2, 3 or 4, characterized characterized in that the fine-grained non-luminescent solid is aluminum oxide. 6. The method according to claim 1, 2, 3, 4 or or 5, characterized in that the non-luminescent solid consists of grains smaller than 1 μτη are, the grain size distribution is such that the substance has a grain size of at least 50% of less than 0.15 / tm. 7. The method according to claim 1, 2, 3, 4, 5 or 6, characterized in that the suspension consists of a suspension liquid with 80 to 98 percent by volume a non-polar liquid and 20 to 2 percent by volume of a polar liquid, with the suspension liquid still 0.7 to 2.5 Contains percent by weight nitrocellulose and 0.1 to 1 percent by weight aluminum oxide, calculated as a percentage of the amount of substance to be suspended in the suspension liquid.