DE2318402A1 - DEVICE FOR DISPENSING VAPORS - Google Patents

Description

THE NATIONAL CASH REGISTER COMPANY ο O <1 ο / η ο

Dayton, Ohio (V. St. A.)

Patent application no .:
Our reference number: Case 1461 / GER

DEVICE FOR DISPENSING VAPOR

The invention relates to a device for emitting vapors, in particular substances such as perfumes and insecticides or inhalants, into the atmosphere.

It is already known to use a heat source with a volatile or vaporizable substance, such as a Perfume, which is vaporized by the heat generated and distributed in the surrounding atmosphere. Known devices this type have the disadvantage that the volatile substance evaporates too quickly and thus too large an amount of evaporable liquid is consumed.

The invention is based on the object of creating a device for the delivery of vapors in which this Disadvantages do not occur.

The invention thus relates to a device for emitting vapors, which is designed as a radiation source, and is characterized in that the radiation source carries a plurality of small polymer capsules containing a vaporizable substance, that said substance evaporates and the heat generated in the operating state of the radiation source is released into the surrounding atmosphere, and that the evaporation and release occurs at a temperature below the melting point of the capsule wall material.

The capsules are preferably in the form of a layer on a jacket which at least partially encloses the energy source upset. The energy or radiation source is in particular

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uses a light source. ^ O I Q A U Z

The device according to the invention has the advantage that the steam output can be easily switched on and off can. The mechanism underlying the release of the substance from the capsules is not yet known. It will, however assumed that the release by gradual diffusion of the vaporizable substance through the pores of a multitude of not broken capsule walls or by completely breaking open individual capsule walls as a result of the rising temperature caused by the heating internal printing. It is assumed that there is a high probability that the substance will be released by a Combination of these two effects, i.e. by diffusion and by breaking the capsule walls, takes place. However, will In any case, the cause of the release of the substance is eliminated by switching off the light source. It is important to care to point out that the release of the substance in the invention is not effected by simple evaporation and consequently

at

not only determined by the vapor pressure of the substance / exner in question Temperature, but also on factors such as porosity, fragility or composition depends on the capsule walls.

Light is understood to mean electromagnetic radiation of such a wavelength that such radiation contains (but does not necessarily consist only of such radiation), which is able to measure the temperature of a to increase absorbent body. Possible light sources include: filaments of gas-filled or not gas-filled incandescent lamps; open flames from candles or lanterns; and other electron emitting devices such as fluorescent lamps and cathode ray tubes.

The jacket preferably surrounding the light source and carrying the capsule layer is not necessarily required to be made of a translucent material. Further needs

to this coat the light source does not necessarily completely / surround.

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Vaporizable substances suitable for the invention can be solids or liquids which are sufficient for one have high vapor pressure to generate a sufficient amount of steam at only a moderately elevated temperature. Under a A moderate rise in temperature should range from just a few degrees Celsius to a few hundred degrees Celsius be understood about the normal ambient temperature. The height of the temperature rise is in the device according to the invention of minor importance, since even a small increase in temperature has the desired effect in one to a certain extent. It goes without saying that temperatures at which the capsule wall material or any polymeric binder that may be present melts or carbonizes. Fragrances are suitable as vaporizable substances, Disinfectants, medical inhalants, pest repellants and killers, germicides, flavorings, fertilizers, chemical reagents, bleaches.

The vaporizable substance can be a solution of a solid in a liquid solvent and the vaporizability the contents of the capsule can be adjusted by using different solvents with different vapor pressure properties can be combined, as is often done in fragrance manufacture.

The small capsules containing the vaporizable substance can have walls made of any polymeric material, which, however, is not softened or dissolved by the contents of the capsule or by the warmth of the light source normal operation of the device is allowed to melt. The melting temperature of the polymer or combination of polymers can be determined in a simple manner so that it does not cause any difficulties for the particular conditions required to choose a polymer of the desired melting temperature.

The diameter of the small capsules can vary from a few to a few thousand µm, with the preferred one

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Size range between about 5 µm and 5000 µm, most of the time however is below 300 µm. In most embodiments of the invention, the capsules are so small that they are no longer detectable with the naked eye. However, larger capsules can be used to advantage in order to achieve a decorative effect in addition to the release of the vaporizable substance. Regarding the decorative Effect should be noted that capsules of any size within the stated size range in the shape of egg determined Image pattern can be applied.

Particular capsule wall-forming substances suitable for the invention are natural and synthetic water-soluble or water-insoluble polymers. The choice of the respective capsule wall material depends on the capsule manufacturing process. It The following capsule wall materials can be used: gelatin, gum arabic, starch, carrageenan, urea immaldehyde resins and melamine-formaldehyde resins, alkyl vinyl ether-maleic anhydride copolymers, Ethylene-maleic anhydride copolymers, Polyvinyl alcohol, polyvinyl pyrrolidone, polyethylene oxide, albumin, polyacrylic acid and polymethacrylic acid, ethyl cellulose, Polystyrene, polyacrylonitrile, cellulose acetate butyrate, cellulose acetate phthalate, Cellulose nitrate, epoxy resin, polyurethane and polyethylene. The capsules can be made according to any known Capsule manufacturing processes, such as interfacial polymerization, phase separation, solvent exchange, meltable dispersion, mechanical processes of film formation or spray drying.

The capsules can be coated on the selected area from any suitable liquid carrier system will. Such a carrier system can contain a polymeric binder for certain applications. While as an adhesive Serving polymeric binders are preferred, such capsules that consist of a wall material that is in a liquid system swells or becomes sticky without its own

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Binder are coated. In the latter
In this case, the sticky capsule walls create the bond between the capsules and the substrate. For example, capsules formed by a process of complex coacervation in one
aqueous system, can be applied as a layer directly from the manufacturing liquid. The capsule walls can also be colored by a pigment or a light-absorbing dye. In those cases where
different capsules different types of vaporizable
Containing substances, the walls of the capsules can be colored or
be covered with a light- or heat-absorbing substance in order to effect a successive release of the substances contained in the capsules, the substances in the more heat-absorbing capsules being released first and the substances in the capsules, the walls of which are less absorbent of heat, being released thereafter.

If polymeric binders are used, they can be dissolved in such a vaporizable liquid that does not dissolve the capsule wall material. A capsule coating mixture can be prepared in that the capsules are dispersed in such a binder solution, after which this dispersion is applied to the surface to be coated and
the solvent is evaporated. The capsule dispersion can
by spraying, dipping, brushing or printing on the
Surface can be applied. The capsules can also be applied directly in that the surface is coated with a wet adhesive, after which the still
wet coating can be brought into contact with the dry capsules. The capsule dispersion can be used to achieve
other desired properties, other substances can be added. For example, surface-active substances can be added to change the coating and wetting properties of the dispersion. If the polymeric binder is a curable material, drying agents can also be used

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be added. Pigments or dyes can also be added to give the coating a certain color to give and to increase the light absorption capacity of the coating, so that a stronger heating and thus a faster release of the vaporizable substance follows.

Specific examples of polymeric binders are all those substances mentioned above as capsule wall material and such well-known coating materials as alkyd resins, silicone resins, polyester resins, isocyanate adducts -Resins and latices.

Further details of the invention are described in more detail below using examples and drawings. In these show:

1 and 2 each show an electric incandescent lamp;

3 shows a greatly enlarged sectional view of the coating of the device according to the invention; 4 shows a fluorescent tube and FIGS. 5, 6 and 7 show other types of light sources.

The incandescent lamp shown in Fig. 1 illustrates an embodiment of the invention in which the dumbbell (11) is formed by the glass bulb of the incandescent lamp and encloses the filament forming the actual light source. Of the The jacket (11) formed by the glass bulb is partially provided with the capsule coating (12). The one shown in FIG Incandescent lamp corresponds essentially to that shown in Fig. 1, but with the exception that the coating (12) the jacket (11) practically completely covered. Both gas-filled and non-gas-filled incandescent lamps can be used.

Fig. 3 shows a greatly enlarged sectional view of part of the capsule-coated shell (11) Layer (12) consists of the capsules (13) and the polymeric binder through which the former adhere to the shell (11). The capsules (13) contain the vaporizable substance (15), the

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is enveloped by the polymeric capsule wall material (14). The jacket (11) is made of a transparent material shown, but - as mentioned above - a translucent or even an opaque material can be used.

Fig. 4 shows a fluorescent tube in the longitudinal The capsule layer (11) is applied in the form of a strip of its jacket (11). In Fig. 5 is the inventive Device shown in the form of a kerosene lamp, in which part of the cylinder serving as a jacket (11) with the capsule layer is provided. In Fig. 6, a candle is shown burning in a container that extends upwards into Form of a cylinder forming the jacket (11) runs out. The coating (11) is applied to this in the form of strips. Finally, FIG. 7 shows a conventional battery-operated flashlight with a cap on the headlight head is placed, which is completely covered with a coating (12). Similar light or heat generating devices can also be used.

The preparation of some of these exemplary embodiments is described in the following examples.

Example 1:

In this example, a coating composition is prepared by dissolving 5 grams of polyvinyl alcohol in an aqueous dispersion of 10 grams of capsules and 85 grams of water. The polyvinyl alcohol forms the polymeric binder. The capsules contain a clove fragrance as a vaporizable substance. The capsules have an average diameter of about 10 to 40 ₇ µm and the capsule walls are made of gelatin and gum arabic. The capsules were produced by complex coacervation.

A LOOW incandescent lamp is put into the coating composition dipped and the resulting coating dried at room temperature. The incandescent lamp treated in this way,

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which corresponds approximately to that shown in FIG. 2, emits practically no aroma when switched off. When switched on, however, it continuously gives off a clove scent. Incandescent lamps coated in the above manner also give after periodic trials extending over a period of more than a year, the encapsulated fragrance provided, however, that the bulb of a LOOW incandescent lamp did not become excessively hot during operation.

Example 2:

In this example, a fluorescent tube with about 20 to 24 W was provided with a strip-shaped layer by means of a brush in the manner shown in FIG. 4. The coating composition used for this purpose comprises a polymeric binder of ethyl cellulose dissolved in toluene, and member ho halt lent forming capsules. The capsule walls consist of a condensation polymer made from Resoi'cin and formaldehyde. The capsules are between about 100 and 300 µm in diameter. As a result of the encapsulation, the vaporizable substance is released so slowly that the capsule layer was even after several months of uninterrupted operation,

Example 3

In this example, a candle lamp! * - is produced in accordance with the illustration in FIG. 6. The capsules produced by koaiplex coacervation contain lemon oil and the capsule production system serves as a coating composition without the addition of a polymeric binder. The capsule production system contains small amounts of dissolved gelatin residues and the capsule walls are still swollen, which is sufficient to ensure that the capsules adhere to the lamp cylinder. The capsules placed on the lamp cylinder let:. You dry »By lighting the candle s. ± ch unfolds the insect-repellent effect of citronella oil,

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Example 4:

The cylinder of a kerosene lamp shown in FIG. 5
The type shown is removed and sprayed with a coating composition in which a small amount of capsules containing pine needle oil is present. The capsules coated over the entire surface of the glass cylinder have such a low coating density that they are almost invisible
and do not weaken the light emitted by the lamp.

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Claims (11)

PATENT CLAIMS: 1.) The invention relates to a device for emitting vapors, which is designed as a radiation source, characterized in that the radiation source carries a plurality of small, a vaporizable substance containing polymer capsules that the said substance evaporates in the operating state of the radiation source by the heat generated and is released into the surrounding atmosphere, and that the evaporation and release occurs at a temperature below the melting point of the capsule wall material. 2. Apparatus according to claim 1, characterized in that the radiation energy quXe during the evaporation and Release process of the vaporizable substance works as a light source. 3. Apparatus according to claim 2, characterized in that a layer of said capsules on one of the heat and light source / giving coat is applied. 4. Apparatus according to claim 3, characterized in that the jacket is at least partially made of translucent Material. 5. Apparatus according to claim 4, characterized in that the translucent material is glass. 6. Apparatus according to claim 4 or 5, characterized in that the jacket of the cylinder of a fuel lamp is. 7. Apparatus according to claim 4 or 5, characterized April 6, 1973 309844/0425 draws that the mantle through the t & H glass bulb of an electric Incandescent lamp or the glass tube of a fluorescent tube is formed. 8. Apparatus according to claim 4 or 5, characterized in that the jacket through a light beam permeable Disc of an electric flashlight or similar device generating a light beam. 9. Device according to one of claims 4 to 8, characterized characterized in that the coating is carried by the translucent material. IC. Device according to claim 8, characterized in that that the coating and / or the capsule walls contain a radiation-absorbing substance, the heating during operation of the vaporizable substance. 11. Device according to one of the preceding claims, οudurch that during operation the capsule wall material is permeable to the vapor of the vaporizable substance. April 6, 1973 309844/0425 Il Blank page