EP3243569A1 - Device for producing aerosols - Google Patents

Abstract

A cartridge nozzle (1) is claimed, comprising: a main flow channel (2), a feed channel (3), a reservoir (40, 50, 60) for a drug, the main flow channel (2) being fluidically connectable to a fluid pressure source (102) is, wherein the main flow channel (2) has a nozzle outlet opening (4) through which the main flow channel (2) is fluidically connected to the environment, wherein the main flow channel (2) with a supply channel (3) is fluidically connected, wherein the feed channel (3 ) is fluidly connected to the reservoir (40, 50), wherein the reservoir (40, 50, 60) has a variable volume, wherein the cartridge nozzle (1) is adapted to the volume of the reservoir (40, 50, 60) during a suction to reduce exactly the volume which is removed from the reservoir (40, 50, 60).

Description

The invention relates to a device for generating aerosols, also called spraying device. For example, the device may be used to transfer a personal care product, such as a deodorant or cream, from an initial liquid state to an aerosol and spray onto the desired body part.

Similar devices are known in the art. These are, for example, spray cans which, for example, spray a deodorant, a hairspray or a cream. Such spray cans are also known as spray cans or aerosol cans. These include a pressure vessel containing a high pressure propellant, such as propane, butane or mixtures thereof. As propellant gases and compressed air or nitrogen can be used. The principle of the action of a spray can with propane or butane as blowing agent is that the blowing agent is present in the interior of the pressure vessel in two phases, namely gaseous and liquid. Due to the density difference of the two phases, the liquid settles in the lower part of the can, above a gas space, also called pressure pad, formed of gaseous propellant. In addition, an active ingredient is dissolved in the liquid phase of the blowing agent. The spray can has a nozzle outlet which is connected to a hose which projects into the liquid phase of the propellant. Now, when the sampling valve is actuated, the active ingredient, dissolved in liquid propellant, escapes through the tube from the can.

Furthermore, spray cans are known in which the propellant and the active ingredient are stored in different containers. With spray cans of this so-called aerosol technique, it is also possible to spray those active substances which do not mix with a blowing agent or can be dissolved in it. The most widely used for this purpose is the valve bag system. Here, in addition to the compressed propellant, a bag in the pressure vessel in which the active ingredient is contained. The pressurized propellant in turn exerts a pressure on the bag in which the active substance is stored. When activating the removal valve, thus the pressure chamber, with the propellant contained therein, and the bag, with the active substance contained therein, simultaneously emptied into the environment. In this case, an aerosol is formed and discharged in the nozzle.

The disadvantage in the prior art is that conventional spray cans can contain and dispense only a single active ingredient or a single active ingredient composition. For example, it is not possible to use one and the same deodorant dispenser to dispense either with different fragrances. Also, it is not possible to issue either a deodorant, or a sunscreen emulsion from one and the same can.

It is an object of the present invention to provide a device for dispensing aerosols in which the drug to be delivered is arbitrarily selectable by the user.

The object is achieved with a device for generating aerosols, which contains the features of claim 1.

Advantageous developments are the subject of the dependent claims.

The device has a cartridge nozzle and a fluid pressure source. The gas in the fluid pressure source is under pressure. From the fluid pressure source, a fluid mass flow of a carrier gas can be removed, which is to flow through the cartridge nozzle. This process is called spraying. During the flow through the cartridge nozzle, that is, during the spraying process, an active substance which is stored inside the cartridge nozzle is added to the fluid mass flow of the carrier gas. The cartridge nozzle is arranged during the spraying process so that the carrier gas flow passes through it. The fluid mass flow enters at the designated location in the cartridge nozzle and leaves the nozzle at the designated output and then escapes into the environment. The device may include a plurality of cartridge nozzles. The different cartridge nozzles may have different active ingredients and / or drug combinations. The at least one cartridge nozzle may be positioned by a receptacle within the device. The receptacle may be rotatably mounted about an axis of the device. The cartridge nozzles can be arranged in a receiving component (receptacle). The receptacle can thus position the cartridge nozzles on the device. By moving the holder with the cartridge nozzles contained in it, the nozzles can be positioned. This can be done by moving or rotating the recording. By rotating the receptacle about a central axis of the device, a cartridge nozzle can be brought into and out of communication with the fluid pressure source. As an active ingredient, which is to be sprayed through the device, for example, a deodorant is conceivable. By the possibility of using different cartridge nozzles with different active ingredients in the device it would be conceivable to use as active ingredients deodorants with different fragrances. So a user can choose individually after the morning shower, which deodorant fragrance he wants to use. It would also be conceivable to have a cartridge nozzle with deodorant, after-shave, moisturizer and sunscreen cream available in the device at the same time. It would also be conceivable to have available in the device various cartridge nozzles which contain the identical active ingredient but in different concentrations. This could be a Anwendungskur, for example, for human hair, realized (5-day hair cure ect.). In addition, it is conceivable to mark the different cartridge nozzles with different colors. For example, the cartridge nozzle with deodorant could be red, the aftershave blue, the sunscreen yellow. The user of the device may also purchase all personal care products from a single device. When traveling, the required products would no longer have to be carried individually. It would also be conceivable to provide the device for multiple persons in a household for use. For example, each household member could insert the cartridge nozzle with the individually preferred deodorant fragrance into the device. Thus, the device would be used by several people as a deodorant dispenser, each user is his own deodorant fragrance available.

In the recording several cartridges can be arranged. The cartridge nozzles can be inserted into the receptacle. The receptacle may have at least one pocket for receiving at least one cartridge nozzle. By rotating the receptacle, the cartridge nozzles can be brought into an exchange position and replaced. The cartridge nozzle connected to the fluid pressure source can thus be exchangeable by rotation of the receptacle, while all the cartridge nozzles in the Remain recording. The cartridge nozzles may be removable from the device and reusable. The cartridge nozzles can be designed as disposable products that can be easily disposed of after use. An advantage of this is that the cartridge nozzles always provide an optimal spray pattern, as they do not clog by a regular exchange. In addition, the device according to the invention from an ecological point of view makes most sense, since after a consumption of the drug of a cartridge nozzle exclusively the cartridge nozzle must be disposed of and replaced, but not the entire device. A known from the prior art deodorant must be completely disposed of after consumption in comparison, which heavily pollutes the environment. In addition, the device according to the invention makes it possible to realize a business model which is known in other fields. For example, coffee makers are distributed by various manufacturers, which prepare from these inserted "coffee pads" a caffeinated hot drink. The coffee machines are very cheap, often sold without profit, to the customer. This is then forced to buy throughout the life of the coffee machine, the required "coffee pads", which is the contribution margin of the business model is generated. With the device according to the invention, a very similar business model can be realized, in which the customer can buy the device at a low price, and the cartridge nozzles with their active ingredient then have to be regularly re-purchased. Furthermore, there is a possibility of using the device for marketing purposes: It is known that, for example, in the perfume industry small perfume samples (filled in glass tubes) are spent free of charge to the end customer, so that he can test a new fragrance and then ideally intended for sale Perfume product acquires. A similar advertising concept can be implemented with the device according to the invention. It would be conceivable to issue corresponding cartridge nozzles to the end customer as "trial packs". These cartridges can contain only a small amount of active ingredient, which is sufficient only for a few applications, just for trial purposes. These sample test cartridges may also contain perfume, or other end products / agents.

The cartridge nozzles used in the device or the recording can be secured by the recording. The forces exerted by the fluid mass flow on the cartridge nozzle forces can be dissipated by the inclusion in the housing.

The device may also have a lid which can be placed on the device and is removable. This lid can at least partially enclose the cartridge nozzles used in the device. The lid may have at least one recess. Through this recess, a leaking from a cartridge nozzle into the environment fluid mass flow escape into the environment.

The cartridge nozzles can be secured in position by the lid. The forces exerted by the fluid mass flow on the cartridge nozzle forces can be discharged through the lid into the device. To replace used cartridge nozzles, the lid can be removed from the device, whereby the cartridge nozzles can be removed quickly and easily.

The lid may also have a plurality of recesses. These can be provided to recognize the arranged behind the lid cartridge nozzles. The various cartridge nozzles used in the device can, as already above mentioned, have different colors. These colors can be recognized by the recesses. Thus, it is possible for the user of the device to quickly and easily recognize which cartridge nozzle is currently connected to the source of fluid pressure or which agent (such as deodorant, aftershave, sunscreen, moisturizer, etc.) is currently removable from the device , In addition, the user can see through the recesses in which direction and at which angle he must rotate the receptacle to connect the desired cartridge nozzle with the fluid pressure source.

The fluid pressure source may include a gas cartridge for fluid supply. This can be exchangeable and / or refillable. In one embodiment with a replaceable gas cartridge, it would also be conceivable that a first active substance is already contained in the gas cartridge, such as a fragrance-neutral antiperspirant. Through the cartridge nozzles, a fragrance could be added to the antiperspirant during operation of the device for use as a deodorant. In one embodiment, with a refillable gas cartridge, in turn, the waste load can be reduced to meet environmental concerns.

The fluid pressure source may also include an air compressor, such as a compressor. The fluid pressure source can also have a gas cartridge and an air compressor, in which the air compressed by the air compressor can be stored. The air compressor may be integrated into the device, or be present as an external component. In an embodiment with a compressor integrated in the device, the power supply of the compressor can be provided by batteries or accumulators (for example lithium polymer accumulators). be guaranteed, which can also be integrated into the device.

The cartridge nozzle has a main flow channel, a feed channel and a reservoir. In the reservoir, a liquid agent may be included. The main flow channel is fluidically connectable to the fluid pressure source. At the end of the main flow channel, this has a nozzle outlet opening. Through this nozzle outlet opening of the main flow channel is fluidly connected to the environment. The main flow channel is in turn connected to a feed channel, which opens into the reservoir. The reservoir may also have a variable volume. The reservoir is designed to be fluid-tight, a fluid can flow out of the reservoir exclusively via the feed channel. The cartridge nozzle is also designed as inexpensive to be mass produced part.

The operation of the nozzle can be based on the Venturi principle. In this case, the main flow channel is designed as a Venturi tube and the feed channel opens into the constriction of the Venturi tube. Now, when a fluid mass flow flows through the cartridge nozzle, this is forcibly accelerated until reaching the bottleneck in the Venturi tube. The pressure drops within the flow of the Venturi tube. Due to this low pressure in the Venturi tube, which also rests against the mouth of the feed channel in the main flow channel (Venturi tube), the contents of the reservoir via the feed channel in the Venturi tube, ie in the main flow channel, sucked.

The volume of the reservoir can be made variable. This should make it possible to remove the contents of the reservoir, without doing a compensation flow in the Container into having to worry. The container reduces its volume during the suction by exactly the volume which is removed through the feed channel from the container. The volume change of the reservoir can be done by a piston which can be inserted and disengaged in the latter. This can penetrate during the emptying of the reservoir into the interior of the container to adjust the internal volume of the container.

The above-mentioned piston can be stored floating in the reservoir.

Instead of the piston, a membrane for volume adjustment or volume reduction of the reservoir can be provided. This membrane can be partially connected to the reservoir.

The reservoir may be at least partially or completely formed of an elastic shell material, which contracts when emptying the container. In addition, it is conceivable to carry out the storage container at least partially or completely from a flexible casing material, such as a film. This flexible casing material could be in the form of a bag and would change its shape during the removal of the active agent by a spraying operation so that the inner volume of the bag decreases. The film can fold up.

The cartridge nozzle may have upstream of the fluid mass flow a pressure chamber which is upstream of the main flow channel. This pressure chamber can have a connection opening through which a fluid mass or a fluid mass flow can be fed to the cartridge nozzle. The pressure chamber may be tapered downstream of the volumetric flow to accelerate to reach the mass flow. The entire geometry of the cartridge nozzle is also designed for the properties of the active ingredient to be sprayed (such as viscosity) and the desired spray pattern.

Fig. 1

ist eine perspektivische Explosionsdarstellung einer Vorrichtung zum Erzeugen von Aerosolen.

Fig. 2

zeigt eine Schnittansicht einer Patronendüse, welche einen Vorratsbehälter aufweist, der durch einen Kolben begrenzt ist.

Fig. 3

ist eine Schnittansicht einer Patronendüse, welche einen Vorratsbehälter aufweist, der durch ein elastisches Hüllenmaterial begrenzt ist.

Fig. 4

zeigt eine perspektivische Ansicht einer Vorrichtung zum Erzeugen von Aerosolen.

In the following, the invention will be explained in more detail with reference to a preferred embodiment with reference to the figures.

Fig. 1

is an exploded perspective view of an apparatus for generating aerosols.

Fig. 2

shows a sectional view of a cartridge nozzle, which has a reservoir which is delimited by a piston.

Fig. 3

is a sectional view of a cartridge nozzle having a reservoir which is bounded by an elastic shell material.

Fig. 4

shows a perspective view of an apparatus for generating aerosols.

Fig. 1 shows an apparatus for generating aerosols 100, according to a preferred embodiment of the present invention. The device for generating aerosols 100 is cylindrical. In the lower part of the figure is a cylindrical pressure gas container 102. At the upper end of the gas cylinder 102, a circular guide rail is arranged in the circumferential direction, which receives and guides a selector ring 103, so that it is rotatable in the circumferential direction about the vertical axis of the device 100. Through this guide, the position of the selector ring 103 is set vertically. The selector ring 103 in turn receives a receptacle 101. The receptacle 101 and the selector ring 103 are not rotatable relative to each other. The receptacle 101 and the dial 103 can be exclusively simultaneously rotate about the vertical axis of the device 100. The receptacle 101 has pockets 109 into which cartridge nozzles 1 can be inserted. At the upper end of the compressed gas container 102, a shaft body 105 is arranged, which is fixedly connected to the compressed gas container 102 and formed integrally therewith. The shaft body 105 has a gas outlet opening 106. The gas outlet opening is firmly positioned in the shaft body 105. The position of the gas outlet opening 106 is therefore fixed with respect to the compressed gas container 102. The cartridge nozzles 1 in turn are forced to follow a rotational movement of the receptacle 101 and the selector ring 103 about the vertical axis of the device 100. When the compressed gas container 102, the selector ring 103, the receptacle 101 and the one or more cartridge nozzle (s) 1 are mounted, that is, that the selector ring is seated on the guide of the pressurized gas container 102, the receptacle 101 is inserted into the selector ring 103 and the Cartridge nozzles 1 are inserted into the designated pockets 109 of the receptacle 101, the cartridge nozzles 1 with respect to the receptacle 101 are fixed in their position in the circumferential direction of the device 100. The cartridge nozzles 1 are also defined inwardly by the shaft 105 of the gas cylinder 102 in the radial direction of the device 100, since the cartridge nozzles 1 abut the shaft 105 of the pressurized gas container 102. In order to set the cartridge nozzles 1 outwardly and in the radial direction of the device 100 to the outside in position, a lid 104 is placed over the cartridge nozzle 1 (placed on the device 100) and this fixed to the selector ring 103. To replace spent cartridge nozzles 1, the lid 104 can be removed from the device 100. The lid 104 has a plurality of recesses 107, which are formed in the lateral surface of the lid 104. These are small pockets which are formed only at the lower edge of the lateral surface of the lid 104. The recesses 107 are either as here shown as formed downwardly open recesses, or as window-shaped recesses. In addition, the cover 104 has in its lateral surface on a large recess 108, which extends almost to the upper limit of the lid 104. This large recess 108 may also be window-shaped. In the assembled state of all in Fig. 1 shown components can be recognized by the small recesses 107 in the lid 104 behind the cartridge nozzles 1, or it can be seen whether behind it, in the designated pocket 109 of the receptacle 101, an inserted cartridge nozzle 1 is located and what color this has , The small recesses 107 thus provide a view of the cartridge nozzles 1 used, although the cover 104 almost completely covers the cartridge nozzles 1 to the outside. The large recess 108 in the lid 104 is arranged so that the nozzle outlet opening 4 of the cartridge nozzle 1, which is located at the position of exactly this recess 108, is not covered to the outside. The lid 104 is fixed relative to the compressed gas container 102 and thus also with respect to the position of the fluid outlet 106 of the compressed gas container 102. That is, the lid 104 does not participate in a rotational movement of the selector ring 103 and the receptacle 101 and the cartridge nozzles 1. Therefore, the large recess of the lid 104 is always arranged so that it is located exactly at the point in the radial circumferential direction of the device 100, on which the gas outlet opening 106 of the pressurized gas container 102 is arranged. Upon actuation of the spray device 100, the pressurized fluid in the container 102 flows out of the opening 106 in the shaft 105 of the pressure vessel 102, then penetrates into the cartridge nozzle 1, is enriched in this with the active ingredient in the cartridge nozzle 1 and exits the nozzle exit opening 4 of the cartridge nozzle 1, and thus out of the device 100, through the large recess 108.

Fig. 2 shows a side sectional view of the cartridge nozzle 1 according to a preferred embodiment of the present invention. In the lower region of the cartridge nozzle 1, a reservoir 40, 50, 60 is formed, which is closed in its lower region by a floating piston 41, 51. The reservoir 40, 50, 60 is completely filled with a liquid agent (not shown). The cartridge nozzle 1 has a connection opening 6 in the left-hand area of the illustration. During operation of the device for generating aerosols 100, a carrier gas jet or mass flow of fluid flows in the horizontal direction (with respect to FIG Fig. 2 ) from left to right through the cartridge nozzle 1 and exits the cartridge nozzle 1 on the right side (with respect Fig. 2 ) From the nozzle outlet opening 4 in the environment. In this case, a fluid mass flow through a main flow channel 2 from left to right in Fig. 2 educated. The cross section of the main flow channel 2 is significantly smaller than the cross section of a pressure chamber 5. According to the law of the continuity equation, the flow must flow through the main flow channel 2 (with a small cross section) faster than through the pressure chamber 5 (with a large cross section). In this case, the pressure of the flow in the main flow channel 2 falls according to the law of Bernoulli, since the flow velocity in the main flow channel 2 increases. The resulting by the Venturi effect negative pressure in the main flow channel 2 causes an intake of the in-reservoir 40, 50, 60 active ingredient through the feed channel 3, into the flow through the flow channel 2. This forms in the main flow channel 2, a mixture of the carrier gas flow and the fluid which is sucked through the feed channel 3 from the reservoir 40, 50, 60 becomes. During the process of emptying the reservoir 40, 50, 60, consequently, the amount of fluid in the reservoir 40, 50, 60 decreases. In this case, the floating piston 41, 51 shifts upward, which separates the reservoir 40, 50, 60 downwards from its environment fluid-tight. As a result, the internal volume of the reservoir 40, 50, 60 is reduced.

Figure 3 shows a further cartridge nozzle 1 according to another preferred embodiment of the present invention, wherein the reservoir 60 is bounded by an elastic sheath 61 which is fluid-tightly connected to the cartridge nozzle 1. As the reservoir 60 is deflated, the elastic sleeve 61 contracts to accommodate the changed contents volume of the reservoir 60. The remaining components or the rest of the structure corresponds to that of the cartridge nozzle Fig. 2 ,

Fig. 4 shows a perspective view of the device for generating aerosols 100 from Fig. 1 , In the upper part of the figure, the lid 104 can be seen, which has a small recess 107 in the left section, behind which a small area of a cartridge nozzle 1 can be seen. Furthermore, a large recess 108 can be seen on the right side of the image in the cover 104, which opens the view to another cartridge nozzle 1, wherein the nozzle outlet opening 4 of this cartridge nozzle 1 is not covered by the cover 104. A fluid mass flow exiting from this cartridge nozzle 1, or from its nozzle outlet opening 4, can escape freely into the environment. In a rotary operation of the selector ring 103, the compressed gas container 102 and the lid 104 remain rigidly in position. The positions of the recesses of the lid 104 remain unchanged. With a rotating operation of the selector ring 103, the receptacle 101 and the cartridge nozzles 1, which are not visible in this view, are rotated about the vertical axis of the device 100. Thus, the cartridge nozzle 1, which is located behind the large recess of the lid 104 and connected to the source of fluid pressure, can be exchanged for another cartridge nozzle 1 located in the receptacle 101.

• eine Patronendüse 1 mit einem Vorratsbehälter zur Aufnahme eines Wirkstoffs und einer Düse zum Ausbringen des Wirkstoffs in die Umgebung,
• eine Fluiddruckquelle 102 zur Aufnahme eines unter Überdruck stehenden Fluids,
• wobei die Patronendüse 1 durch die Fluiddruckquelle 102 mit einem Fluidmassenstrom versorgbar ist,
• wobei die Patronendüse 1 dazu angepasst ist, dass während des Versorgens der Patronendüse 1 der Fluidmassenstrom von der Fluiddruckquelle 102 durch die Patronendüse 1 hindurchströmt und anschließend in die Umgebung entweicht,
• wobei die Patronendüse 1 dazu angepasst ist, dass dem Fluidmassenstrom mittels der Patronendüse 1 ein Wirkstoff zusetzbar ist,
• wobei die Patronendüse 1 in eine Aufnahme 101 an der Vorrichtung 100 positionierbar ist,
• wobei die Aufnahme 101 drehbar um eine Achse der Vor-richtung 100 gelagert ist,
• wobei durch eine Drehung der Aufnahme 101 die wenigstens eine Patronendüse 1 mit der Fluiddruckquelle 102 in und außer Verbindung bringbar ist.

In one aspect, there is disclosed an apparatus for generating aerosols 100 comprising:

• a cartridge nozzle 1 with a storage container for receiving an active substance and a nozzle for dispensing the active ingredient into the environment,
• a fluid pressure source 102 for receiving a pressurized fluid,
• wherein the cartridge nozzle 1 can be supplied by the fluid pressure source 102 with a fluid mass flow,
• wherein the cartridge nozzle 1 is adapted to flow during the feeding of the cartridge nozzle 1, the fluid mass flow from the fluid pressure source 102 through the cartridge nozzle 1 and then escapes into the environment,
• wherein the cartridge nozzle 1 is adapted to be able to add an active substance to the fluid mass flow by means of the cartridge nozzle 1,
• the cartridge nozzle 1 being positionable in a receptacle 101 on the device 100,
• wherein the receptacle 101 is rotatably mounted about an axis of the Vor-direction 100,
• wherein by rotation of the receptacle 101, the at least one cartridge nozzle 1 with the fluid pressure source 102 in and out of connection can be brought.

• wobei die Aufnahme 101 mehrere Taschen 109 zum Aufnehmen von jeweils einer Düse 1 aufweist,
• wobei die in Verbindung mit der Fluiddruckquelle 102 stehende Patronendüse 1, in der Aufnahme 101 verbleibend, durch eine Drehung der Aufnahme 101 in eine Austauschposition bringbar und austauschbar ist.

In another aspect, a device is disclosed

• the receptacle 101 having a plurality of pockets 109 for accommodating a respective nozzle 1,
• wherein the cartridge nozzle 1 standing in connection with the fluid pressure source 102, remaining in the receptacle 101, can be brought and exchanged into a replacement position by rotation of the receptacle 101.

• wobei die wenigstens eine Patronendüse 1 durch die Aufnahme 101 sicherbar ist.

In another aspect, a device is disclosed

• wherein the at least one cartridge nozzle 1 is securable through the receptacle 101.

• Einen Deckel 104, der abnehmbar an der Vorrichtung 100 anordenbar ist,
• wobei der Deckel 104 die Patronendüsen wenigstens teilweise umschließt,
• wobei der Deckel 104 wenigstens eine Ausnehmung 108 aufweist,
• wobei die wenigstens eine Ausnehmung 108 des Deckels 104 einen aus der Patronendüse 1 austretenden Fluidmassenstrom in die Umgebung entweichen lässt.

In another aspect, an apparatus is disclosed, comprising:

• A lid 104 detachably attachable to the device 100,
• the lid 104 at least partially enclosing the cartridge nozzles,
• wherein the lid 104 has at least one recess 108,
• wherein the at least one recess 108 of the lid 104 allows escape from the cartridge nozzle 1 exiting fluid mass flow into the environment.

• wobei die Patronendüsen 1 durch den Deckel 104 sicherbar sind.

In another aspect, a device is disclosed

• wherein the cartridge nozzles 1 are securable through the lid 104.

• wobei der Deckel 104 mehrere Ausnehmungen 107 aufweist, welche dazu angepasst sind, die hinter jeder Ausnehmung 107 angeordnete Patronendüse 1 erkennen zu können.

In another aspect, a device is disclosed

• wherein the cover 104 has a plurality of recesses 107, which are adapted to be able to recognize the cartridge nozzle 1 arranged behind each recess 107.

• wobei die Fluiddruckquelle 102 eine austauschbare und/oder wiederbefüllbare Gaskartusche aufweist.

In another aspect, a device is disclosed

• wherein the fluid pressure source 102 comprises a replaceable and / or refillable gas cartridge.

• wobei die Fluiddruckquelle zur Druckerzeugung einen Luftverdichter aufweist.

In another aspect, a device is disclosed

• wherein the fluid pressure source for generating pressure comprises an air compressor.

• einen Hauptströmungskanal 2,
• einen Zuführkanal 3,
• einen Vorratsbehälter 40, 50, 60 für einen Wirkstoff,
• wobei der Hauptströmungskanal 2 mit einer Fluiddruckquelle 102 fluidisch verbindbar ist,
• wobei der Hauptströmungskanal 2 eine Düsenaustrittsöffnung 4 aufweist, durch welche der Hauptströmungskanal 2 mit der Umgebung fluidisch verbunden ist,
• wobei der Hauptströmungskanal 2 mit einem Zuführkanal 3 fluidisch verbunden ist,
• wobei der Zuführkanal 3 mit dem Vorratsbehälter 40, 50 fluidisch verbunden ist,
• wobei der Vorratsbehälter 40, 50, 60 ein veränderliches Volumen aufweist.

In another aspect, a cartridge nozzle 1 is disclosed, comprising:

• a main flow channel 2,
• a feed channel 3,
• a reservoir 40, 50, 60 for an active ingredient,
• wherein the main flow channel 2 is fluidically connectable to a fluid pressure source 102,
• wherein the main flow channel 2 has a nozzle outlet opening 4, through which the main flow channel 2 is fluidically connected to the environment,
• wherein the main flow channel 2 is fluidically connected to a feed channel 3,
• wherein the feed channel 3 is fluidically connected to the reservoir 40, 50,
• wherein the reservoir 40, 50, 60 has a variable volume.

• wobei die Funktionsweise der Düse auf dem Venturi-Prinzip beruht, wobei der Hauptströmungskanal 2 als

Venturirohr ausgebildet ist und der Zuführkanal 3 in die Verengung des Venturirohres mündet, sodass ein im Vorratsbehälter 40, 50, 60 befindlicher Inhalt von einem Fluidmassenstrom durch den Hauptströmungskanal 2 über den Zuführkanal 3 ansaugbar ist.In another aspect, a cartridge nozzle 1 is disclosed,

• wherein the operation of the nozzle based on the Venturi principle, wherein the main flow channel 2 as

Venturi tube is formed and the feed channel 3 opens into the constriction of the Venturi tube, so that a content in the reservoir 40, 50, 60 contents of a fluid mass flow through the main flow channel 2 via the feed channel 3 can be sucked.

• wobei das Volumen des Vorratsbehälters 40, 50 durch einen in diesen ein- und ausdringbaren Kolben 41, 51 veränderbar ist.

In another aspect, a cartridge nozzle 1 is disclosed,

• wherein the volume of the reservoir 40, 50 is changeable by a piston 41, 51 which can be inserted and disengaged therefrom.

• wobei der Kolben 41, 51 im Vorratsbehälter 40, 50 schwimmend gelagert ist.

In another aspect, a cartridge nozzle 1 is disclosed,

• wherein the piston 41, 51 is mounted floating in the reservoir 40, 50.

• wobei statt des Kolbens 51 eine am Vorratsbehälter 50 fixierte Membran zur Volumenänderung des Vorratsbehälters 50 vorgesehen ist.

In another aspect, a cartridge nozzle 1 is disclosed,

• wherein, instead of the piston 51, a diaphragm fixed to the reservoir 50 is provided for changing the volume of the reservoir 50.

• wobei der Vorratsbehälter 60 wenigstens teilweise aus einem elastischen und/oder flexiblen Hüllenmaterial ausgebildet ist, wodurch das Volumen des Vorratsbehälters 60 veränderbar ist.

In another aspect, a cartridge nozzle 1 is disclosed,

• wherein the reservoir 60 is at least partially formed of an elastic and / or flexible casing material, whereby the volume of the reservoir 60 is variable.

• wobei die Patronendüse 1 eine Druckkammer 5 aufweist, welche mit dem Hauptströmungskanal 2 fluidisch verbunden ist und eine Anschlussöffnung 6 aufweist, durch welche der Druckkammer 5 eine Fluidmasse zuführbar ist.

In another aspect, a cartridge nozzle 1 is disclosed,

• wherein the cartridge nozzle 1 has a pressure chamber 5, which is fluidically connected to the main flow channel 2 and has a connection opening 6, through which the pressure chamber 5, a fluid mass can be supplied.

Claims (7)

Cartridge nozzle (1), comprising: a main flow channel (2), a feed channel (3), a reservoir (40, 50, 60) for an active ingredient, wherein the main flow channel (2) is fluidically connectable to a fluid pressure source (102), the main flow channel (2) having a nozzle outlet opening (4) through which the main flow channel (2) is fluidically connected to the environment, the main flow channel (2) being fluidically connected to a feed channel (3), wherein the supply channel (3) is fluidically connected to the storage container (40, 50), wherein the storage container (40, 50, 60) has a variable volume, characterized in that the cartridge nozzle (1) is adapted to reduce the volume of the reservoir (40, 50, 60) during a suction by exactly the volume which is removed from the reservoir (40, 50, 60). Cartridge nozzle (1) according to the preceding claim,
wherein the operation of the nozzle based on the Venturi principle, wherein the main flow channel (2) as
Venturi tube is formed and the feed channel (3) opens into the constriction of the Venturi tube, so that in the reservoir (40, 50, 60) befindlicher content of a fluid mass flow through the main flow channel (2) via the feed channel (3) is sucked. Cartridge nozzle (1) according to one of the preceding claims,
wherein the volume of the storage container (40, 50) is variable by a piston (41, 51) which can be inserted and disengaged therefrom. Cartridge nozzle (1) according to claim 3,
wherein the piston (41, 51) in the reservoir (40, 50) is floating. Cartridge nozzle (1) according to claim 3 or 4,
wherein instead of the piston (51) to the reservoir (50) fixed membrane for changing the volume of the reservoir (50) is provided. Cartridge nozzle (1) according to claim 1 or 2,
wherein the storage container (60) is at least partially formed from an elastic and / or flexible casing material, whereby the volume of the storage container (60) is variable. Cartridge nozzle (1) according to one of claims 1 to 6,
wherein the cartridge nozzle (1) has a pressure chamber (5) which is fluidically connected to the main flow channel (2) and has a connection opening (6) through which a fluid mass can be supplied to the pressure chamber (5).

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