WO2004089551A2 - Nozzle system for a liquid discharge device, comprising a nozzle and nozzle holder and/or coupling nut - Google Patents

Abstract

The invention relates to a nozzle system for a liquid discharge device, comprising a nozzle and a device which fixes the nozzle in the discharge device. The device comprises a liquid reservoir which pressurises the liquid through a nozzle in order to discharge liquid. The nozzle is fixed to the discharge device by a holding device. Said holding device can be automatically maintained by a second holding device, e.g. in the form of a coupling nut, or the coupling nut is the holding device. According to the invention, at least one part of the outer surface of the holding device is micro or nanostructured.

Description

 Nozzle system for an application device for liquids consisting of nozzle and nozzle holder and / or union nut

The invention relates to a nozzle system for a dispensing device for liquids, which includes a nozzle and a device that fixes the nozzle in the dispensing device. The device has a liquid reservoir, from which a liquid is pressed under pressure through a nozzle for dispensing the liquid. The nozzle is fixed to the delivery device by a holder. This bracket can itself from a second bracket, e.g. be held in the form of a union nut or the union nut itself is the holder. According to the invention, at least part of the outer surface of the holding device is micro- or nanostructured.

The present invention is preferably part of a propellant-free device for atomizing pharmaceutical liquids. Such a nebulizer according to the invention is used, for example, to provide an aerosol of droplets for inhalation through the mouth and throat area into a patient's lungs, for nasal absorption or for spraying the surface of the eye.

PRIOR ART WO 91/14468 discloses a device for the propellant-free administration of a metered amount of a liquid medicament for inhalation use. A further development of the device is described in detail in WO 97/12687. Reference is made to the cited references are expressly incorporated herein and the technology described therein is referred to as Respimat ^® technology in the context of the present invention. This term is understood in particular to mean the technology on which a device according to FIGS. 6a and 6b of WO 97/12687 and the associated description is based.

In such an inhaler, liquid drug formulations are stored in a reservoir. From there, they are transported via a riser pipe into a pressure chamber, in order to then be pressed further through a nozzle. The nozzle has a liquid inlet side and a liquid outlet side. There is an opening on the liquid inlet side through which a liquid coming from the pressure chamber can enter the nozzle. On the opposite side, the end face of the nozzle, the liquid then exits through two nozzle openings which are aligned in such a way that the liquid jets emerging from the openings collide with one another and are thereby atomized. The nozzle openings are located in the inhaler so that they are in direct contact with the outside environment. These inhalers usually deliver formulations based on water or water-ethanol mixtures. They can nebulize a small amount of a liquid formulation in the therapeutically necessary dosage within a few seconds into an aerosol suitable for therapeutic inhalation. The device can be used to atomize quantities of less than 100 microliters with, for example, one stroke to an aerosol with an average particle size of less than 20 micrometers so that the inhalable portion of the aerosol already corresponds to the therapeutically effective amount. In these nebulisers with Respimat ^® technology, a drug solution is converted into a respirable low-speed aerosol cloud by means of a high pressure of up to 500 bar, which can then be inhaled by the patient.

A small part of the liquid can be deposited as a film or as small droplets from the outside onto the face of the nozzle or the face of the holder system of the nozzle or the inside of the mouthpiece. This portion of the liquid is also referred to as the mouthpiece portion in the context of this description of the invention.

The proportion of precipitated liquid does not have to be constant with every stroke, but can be due to several factors such as the orientation of the device in space during the

Depending on aerosolization or the ambient temperature, air humidity etc. On the one hand, this leads to a certain, if only slight, variability in the amount applied, which is then available for the patient to take up.

The deposited liquid can also contaminate the outer surface of the nozzle system or the mouthpiece, which in turn can affect the pharmaceutical quality of a next aerosol cloud. Although the two effects are rather small with Respimat technology devices, it is important for quality assurance reasons to minimize such effects.

It has now surprisingly been found that in devices for dispensing liquids, the proportion of the amount of liquid deposited on the outside of the nozzle system can be reduced if the corresponding surfaces are at least partially micro- or nanostructured. Devices based on Respimat ^® technology are preferred.

Description of the invention

It is an object of the invention to reduce the variability of the portion of the liquid which is dispensed by a device for dispensing pharmaceutical liquids, such as atomizers, inhalers etc.

It is a further object of the present invention to reduce the proportion of liquid which is deposited on the device for dispensing the pharmaceutical liquid from a generated aerosol cloud.

Another task is to optimize the quality with which atomizers of the Respimat ^® technology apply a liquid.

Description of the invention in detail

The present invention relates to a nozzle system for liquid nebulizers, in which at least a part of the outer surface of the nozzle system or other components of the nebulizer, which can come into contact with the applied aerosol, has / have a micro- or nanostructured surface. Preferably, at least the outward-facing end face of the nozzle (ie the side of the nozzle from which the aerosol cloud is discharged) and / or the analogously oriented side of the device for holding the nozzle are provided with such a surface structure. In the simplest case, the nozzle is a pinhole with at least one opening.

Other more complex designs relate to nozzles made of at least two plates lying one on top of the other, at least one of the plates having a second microstructure, so that the plates lying one above the other define a liquid inlet on one side, which is followed by a channel system and / or a filter system, which then connects into one , two or more liquid outlets opens.

In embodiments of the nozzle with a plurality of nozzle openings, all of the nozzle openings are preferably formed on a common side. In such cases, the nozzle openings can be oriented such that the liquid jets emerging therefrom collide in front of the nozzle opening. Such systems require nozzles with at least two openings. Such nozzles are explained in more detail in the description of the Respimat® technology.

These or other nozzles can be part of a nozzle system by which the nozzles are held at a defined location in the application device. Such a nozzle system consists of a nozzle and a nozzle holder and / or a union nut, each with an end face. This is the side that is oriented away from the side of the nozzle with the nozzle opening. The inside of the face of the nozzle holder or the union nut touches the liquid outlet side of the nozzle and thereby exerts the force required to hold the nozzle in the direction of the liquid inlet side of the nozzle. The end face of the nozzle holder and / or the union nut have a continuous bore or hole through which the aerosol can escape from the nozzle. The nozzle openings are therefore in or in a direct line below the bore.

The bore or the hole can be designed as an inner recess which widens continuously from the nozzle openings. Embodiments are advantageous here of the nozzle system, in which the recess has a funnel-shaped shape, preferably a conical shape.

In the case of nozzles with at least two nozzle openings which are oriented in such a way that the two liquid jets exiting the nozzle body meet, the point of impact at which the liquid jets are atomized to form an aerosol is preferably in the vicinity of the foot of the recess, i.e. near the nozzle opening. It is obvious that in such a case the recess is one of the areas particularly at risk of liquid precipitation.

According to the invention, at least some of the following areas are micro- or nano-structured:

- The outer surface of the liquid outlet side of the nozzle and / or

- The outer surface of the face of the nozzle holder and / or

- The side wall of the bore or hole of the nozzle holder and / or - The outer surface of the end face of the union nut and or the side wall of the bore or hole of the union nut.

In particular, the widening recess of the nozzle holder and / or the union nut or a structural combination of both parts preferably has the micro- or nanostructured surface.

These areas and / or the outer surface of the nozzle outlet side and possibly other surfaces in the vicinity of the nozzle opening, on which liquid from the applied aerosol mist can most likely be deposited, are also referred to as critical surfaces in the context of the present invention.

In the case of inhalers, the critical surface also includes the mouthpiece into which a nozzle usually sprays the pharmaceutical aerosol so that it can be inhaled from here. Such a mouthpiece can be designed as a tubular projection, at the bottom of which the nozzle is located. EP 772514 describes what the microstructures or nanostructures used according to the invention can look like, which is why the content of this document is hereby referred to.

If the critical surfaces are those of the nozzle holder or the union nut, at least 20% of their surface, more preferably at least 50%, even more preferably at least 75%, have a micro or nanostructure.

Alternatively and / or additionally, 20% of the outer surface of the nozzle outlet side, more preferably at least 50%, even more preferably at least 75%, can have a micro or nanostructure.

If the critical surface is the inner surface of a mouthpiece, this surface can also be at least 20% micro or nanostructured, more preferably at least 50%, even more preferably at least 75%.

Which surfaces are critical in individual cases depends on the device in question and can be found out by simple tests.

The critical surfaces of the nozzle holder and / or the union nut are preferably micro- or nanostructured.

The structuring of the critical surface according to the invention is achieved in that elevations and depressions are formed on the micro or nano-scale at least on parts of the critical surface.

The elevations and depressions can have the shape of tips, spheres, flat surfaces or be wedge-shaped, hemispherical, etc.

They can have a random arrangement or be ordered, for example in rows, circles, zigzag, meandering, etc. The distance between the elevations of the surface structure is in the range from 0.1 to 200 micrometers, preferably 0.1 to 100 micrometers. Distances from 0.1 to 10 micrometers are more preferred, distances from 0.1 to 1 micrometer are most preferred.

The height of the elevations or the depth of the depressions is in the range from 0.1 to 100 micrometers, preferably 0.1 to 50 micrometers. Distances of 0.1 to 10 micrometers are most preferred.

The elevations of the surface structures are preferably so close together that hydrophilic liquid drops, e.g. Drops of water on the bumps without really touching the surface. At the same time, the elevations of the surface structures must not be too close to one another or the depressions must not be too flat, so that they do not form a closed surface in relation to the droplet size of the liquid, in which the surface forces between the droplet and the surface take full effect. It should therefore be aimed at that with increasing distance the

Surveys should also increase the height of the surveys from the underground. Surfaces with elevations which have 0.1 to 50 micrometers and in which the distance between the elevations is 0.1 to 100 micrometers are preferred.

Structures with two differently scaled are particularly preferred

Surface modulations as they can be generated by superimposing a submicroroughness of 0.05 to approx. 0.5 micron period length and a roughness of 0.5 to 10 micrometer period length.

The critical surfaces preferably consist of hydrophobic materials or durable hydrophobic materials or they are coated with such materials. The surveys cannot be removed by water or by water with detergents. Plastics, metals, ceramics, glasses etc. can be used as materials.

Preferred materials are glass and / or ceramics and / or metals and / or

Plastics such as polyethylene, polypropylene, polycarbonate, polyacrylates, polyesters, silanes etc. Plastics are preferred. Possibly. Such a plastic can be provided with a lacquer layer of another plastic which carries or forms the surface structure, e.g. B. during drying.

Such structured surfaces can either be produced by the

Surface structures can be created from hydrophobic materials during manufacture or can only be created subsequently by subtractive or additive treatment of the surfaces. These processes include subsequent embossing, etching, laser ablation, galvanic removal, sticking on a structured film, sticking on a powder, spraying with suspensions, deposition of sublimates etc.

Finally, it is possible to create such surfaces of objects by subsequently making surfaces with the desired structures durable hydrophobic.

One possibility for subsequent, durable waterproofing is the subsequent silanization of previously produced surfaces with the desired structures. Silanization can take place on all materials that are naturally hydrophilic but are able to react with the reactive groups of the silanes, so that the surface ultimately consists of the hydrophobic residues of the silanes.

In order to create the desired surface structures from the production of hydrophobic polymers, the objects can be produced from the outset in forms which have the negative of the desired surface structure.

It is also possible to apply the hydrophobic polymers in the form of solutions and / or dispersions which, when they dry and set, lead to the desired surface structures.

Structures of this type arise, for example, from self-organizing polymers or under conditions which are known in principle from the production of matt lacquer surfaces. If it is not possible or not desirable to create the desired surface structures from the outset, this can also be done subsequently, for example by subsequent embossing or etching. The embossing can be done, for example, by heated or heatable stamps. The etching can be carried out using the known chemical etching means or by physical methods such as ion etching with oxygen or other irradiations, which lead to a roughening of the surface and a surface structure that can be used according to the invention.

The way in which a surface structure is created depends on the material selected and the desired microstructure.

This invention is preferably used in a nebulizer ^® technology the Respimat.

Essentially, the preferred atomizer has a lower and an upper housing which is rotatably mounted relative to one another, a spring housing with a spring being formed in the upper part of the housing, which is preferably tensioned in the form of a screw thread or gear by rotating the two housing parts via a locking mechanism and by pressing a release button on Housing upper part is relaxed. This moves an output flange, which is connected to a hollow piston, at the lower end of which a container can be attached, and at the upper end of which there is a valve and a pressure chamber which is connected to the nozzle or the nozzle system, which (up) open area of the upper housing part is formed in a liquid-conducting connection. The liquid is sucked in by the hollow piston and pumped to the pressure chamber, from where it is discharged through the nozzle as an aerosol.

The hollow piston with valve body corresponds to a device disclosed in WO 97/12687. It projects partially into the cylinder of the pump housing and is arranged axially displaceably in the cylinder. In particular, reference is made to FIGS. 1-4 - in particular FIG. 3 - and the associated parts of the description. The hollow piston with

Valve body exercises one on its high pressure side at the time the spring is triggered Pressure of 5 to 60 MPa (about 50 to 600 bar), preferably 10 to 60 MPa (about 100 to 600 bar) on the fluid, the measured active ingredient solution.

The valve body is preferably attached to the end of the hollow piston which faces the nozzle body. The valve body is in fluid communication with the nozzle.

The nozzle in the nozzle body is preferably microstructured, i.e. made by microtechnology. However, the microstructure mentioned in this context is - at least in terms of function - different from the microstructure according to the invention, as is clearly evident from the context. Microstructured nozzle bodies are described, for example, in WO 94/07607 or WO 99/16530. Another embodiment is disclosed in WO 03/097139. We hereby expressly refer to all documents. With regard to WO 94/07607, reference is made in particular to FIG. 1 and its description.

The nozzle body is e.g. from two firmly connected plates made of glass and / or silicon, of which at least one plate has one or more microstructured channels which connect the nozzle inlet side to the nozzle outlet side. On the nozzle outlet side there can be at least one round or non-round opening 2 to 10 micrometers deep and 5 to 15 micrometers wide, the depth preferably being 4.5 to 6.5 micrometers and the length being 7 to 9 micrometers.

In the case of a plurality of nozzle openings, preferably two, the jet directions of the nozzles in the nozzle body can run parallel to one another or they are inclined towards one another in the direction of the nozzle opening. In the case of a nozzle body with at least two nozzle openings on the outlet side, the jet directions can be inclined at an angle of 20 degrees to 160 degrees, 60 to 150 degrees are preferred, and 70 to 100 degrees are particularly preferred.

The nozzle openings are preferably arranged at a distance of 10 to 200 micrometers, more preferably at a distance of 10 to 100 micrometers, particularly preferably 30 to 70 micrometers. Most preferred are 50 microns.

Accordingly, the jet directions meet in the vicinity of the nozzle openings. For the sake of simplicity, an embodiment is described below in which only the base part of the nozzle body has relief-like microstructures, but not the ceiling part. In other embodiments, the situation is just reversed, or both parts have these microstructures.

A set of channels can be formed on the base part on the flat surface in order to create a plurality of filter passageways in cooperation with the substantially flat surface of the ceiling part (filter channels). In addition, the base part can have a plenum chamber, the ceiling of which in turn is formed by the ceiling part. This plenum chamber can be connected upstream or downstream of the filter channels. Two plenum chambers of this type can also be formed. Another set of channels on the substantially flat surface of the base portion downstream of the filter channels forms, together with the top portion, a set of channels that provide a plurality of nozzle outlet passageways. The total cross-sectional area of the nozzle outlets is preferably 25 to 500 square micrometers. The total cross-sectional area is preferably 30 to 200 square microns.

In another embodiment, this nozzle construction also has only a single nozzle opening. In other embodiments of this type, the filter channels and / or the plenum chamber are missing.

The filter channels are preferably formed by projections which are arranged in a zigzag shape. For example, at least two rows of the projections form such a zigzag configuration. A plurality of rows of protrusions can also be formed, the protrusions each being laterally offset from one another, in order thereby to construct further rows obliquely to these rows, in which case the rows described last form the zigzag configuration. In such embodiments, the inlet and outlet may each have a longitudinal slot for unfiltered or filtered fluid, each of the slots being substantially the same width as the filter and being substantially the same height as the protrusions on the inlet and outlet sides of the filter, respectively , The The cross section of the passage passages formed by the projections can be perpendicular to the direction of flow of the fluid and - viewed in the direction of flow - can decrease from row to row. The projections, which are arranged closer to the inlet side of the filter, can also be larger than the projections, which are arranged closer to the outlet side of the filter. In addition, the distance between the base part and the cover part can taper in the area from the nozzle inlet side to the nozzle outlet side. The zigzag configuration, which is formed by the at least two rows of projections, has an inclination angle alpha of preferably 20 ° to 250 °.

Further details of this nozzle construction can be found in WO 94/07607. Reference is hereby made to this document, in particular to FIG. 1 and its description.

The nozzle can be embedded in an elastomeric sleeve, as described in WO 97/12683. In its simplest form, such a cuff is a ring or body with an opening into which the nozzle can be inserted. This opening encompasses the nozzle block over its entire lateral surface, i.e. the surface which is perpendicular to the preferably linear axis which is formed by the nozzle inlet side and the nozzle outlet side. The cuff is open at the top and bottom so as not to impede the liquid supply to the nozzle inlet side of the nozzle or the discharge of the liquid. This cuff can in turn be inserted into a second cuff. The outer shape of the first cuff is preferably conical. The opening of the second sleeve is shaped accordingly. The first cuff can be made of an elastomer.

The nozzle, possibly including the sleeve, is held by a device for holding it from the outside in the direction of the hollow piston, as described above.

The atomiser's locking mechanism contains a spring, preferably a cylindrical helical compression spring, as a store for the mechanical energy. The spring acts on the output flange as a jumping piece, the movement of which is determined by the position of a locking element is determined. The path of the output flange is precisely limited by an upper and a lower stop. The spring is preferably tensioned via a force-transmitting gear, for example a screw-push gear, by an external torque which is generated when the upper housing part is rotated against the spring housing in the lower housing part. In this case, the upper part of the housing and the output flange contain a single or multi-speed wedge gear.

The locking member with engaging locking surfaces is arranged in a ring around the output flange. There is e.g. from a radially elastically deformable ring made of plastic or metal. The ring is arranged in a plane perpendicular to the atomizer axis. After tensioning the spring, the locking surfaces of the locking member slide into the path of the output flange and prevent the spring from relaxing. The locking element is triggered by a button. The trigger button is connected or coupled to the locking member. To release the locking mechanism, the release button is moved parallel to the ring plane, and preferably into the atomizer; the deformable ring is deformed in the plane of the ring. Structural details of the locking mechanism are described in WO 97/20590.

The lower part of the housing is pushed in the axial direction over the spring housing and covers the bearing, the drive of the spindle and the reservoir for the fluid.

When the atomizer is actuated, the upper housing part is rotated against the lower housing part, the lower housing part taking the spring housing with it. The spring is compressed and tensioned via the screw-type thrust gear, and the locking mechanism engages automatically. The angle of rotation is preferably an integer fraction of 360 degrees, for example 180 degrees. Simultaneously with the tensioning of the spring, the driven part in the upper part of the housing is shifted by a predetermined distance, the hollow piston is withdrawn within the cylinder in the pump housing, whereby a part of the fluid is sucked from the reservoir into the high-pressure space in front of the nozzle. Several interchangeable storage containers containing the fluid to be atomized can optionally be inserted and used in the atomizer. The storage container contains the inventive aqueous aerosol preparation.

The atomization process is initiated by gently pressing the trigger button. The barrage clears the way for the stripping section. The tensioned spring pushes the hollow piston into the cylinder of the pump housing. The fluid exits the atomizer nozzle in atomized form. The liquid pharmaceutical preparation hits the nozzle body at an inlet pressure of up to 600 bar, preferably 200 to 300 bar, and is atomized into an inhalable aerosol via the nozzle openings. The preferred particle sizes of the aerosol are up to 20 micrometers, preferably 3 to 10 micrometers.

Volumes of 10 to 50 microliters are preferably applied, volumes of 10 to 20 microliters are particularly preferred, and a volume of 15 microliters per stroke is very particularly preferred.

Further structural details are disclosed in PCT applications WO 97/12683 and WO 97/20590, to which reference is hereby made.

The components of the atomizer (Vemeblers) are made of a material that is suitable for their function. The housing of the atomizer and - as far as the function allows - other parts are preferably made of plastic, e.g. manufactured by injection molding. Physiologically harmless materials are used for medical purposes.

A nebulizer according to the invention is preferably of a cylinder-like shape and has a handy size of less than 9 to 15 cm in length and 2 to 4 cm in width, so that it can be carried by the patient at any time.

As already mentioned, according to the invention, in a device of the Respimat ^® type, the outer surface of the nozzle outlet side, parts of the nozzle holder and / or the union nut and, if appropriate, other surfaces in the vicinity of the nozzle opening on which liquid can flow the aerosol mist most likely to precipitate can be provided with the nano or micro structure. Additionally or alternatively, other surfaces of the Respimat ^® -Geräts can according to the invention having the microstructure or nanostructure. These include the inner and parts of the outer surface of the hollow piston, the inner surfaces of the components forming the nozzle, parts of the inner microstructured surface of the nozzle and others.

The present invention is applicable to all types of liquid nebulizers in which aqueous systems are nebulized. The invention is neither limited to the technology on which the vebulization is based, nor to the purpose which such vebulizers are intended to serve.

characters

In the figures la / b, a / b in Figures 6 of WO 97/12687 are similar to the nebulizer from the Respimat ^® is described, with which the aqueous aerosol preparations according to the invention can advantageously be inhaled.

2 show two embodiments of a nozzle system in a side view, partially in section,

3 shows an experimental example for a microstructured nozzle system.

4 shows a schematic illustration of an embodiment of a nozzle body in a side view, in section.

FIGS. 5 to 9 show surface structures of polyester films with a structured acrylic layer.

Figure 1 a shows a longitudinal section through the atomizer with the spring tensioned. Figure 1 b shows a longitudinal section through the atomizer with the spring relaxed. The upper housing part (51) contains the pump housing (52), at the end of which the holder (53) for the atomizer nozzle is attached. The widening recess (54) and the nozzle body (55) are located in the holder. The hollow piston (57) fastened in the output flange (56) of the locking tension mechanism partially projects into the cylinder of the pump housing. The hollow piston carries the valve body (58) at its end. The hollow piston is sealed by means of the seal (59). Inside the upper part of the housing is the stop (60), against which the output flange rests when the spring is relaxed. The stop (61) is located on the output flange, against which the output flange rests when the spring is tensioned. After tensioning the spring, the locking member (62) slides between the stop (61) and a support (63) in the upper part of the housing. The release button (64) is connected to the locking member. The upper part of the housing ends in the mouthpiece (65) and is closed with the clip-on protective cap (66).

The spring housing (67) with compression spring (68) is rotatably mounted on the upper part of the housing by means of the snap lugs (69) and rotary bearings. The lower housing part (70) is pushed over the spring housing. The exchangeable storage container (71) for the fluid (72) to be atomized is located within the spring housing. The storage container is closed with the stopper (73) through which the hollow piston protrudes into the storage container and with its end is immersed in the fluid (supply of active substance solution).

The spindle (74) for the mechanical counter is attached to the outer surface of the spring housing (optional). The drive pinion (75) is located at the end of the spindle which faces the upper housing part. The rider (76) sits on the spindle.

Figure 2a shows an embodiment of the system of nozzle (55) and nozzle holder in side view, partially in section.

The nozzle (55) or the nozzle body as an independent structural unit - so-called uniblock - is arranged in a conical sleeve (77), which in turn is placed in the nozzle holder (78). The nozzle holder (78) is clamped to the housing (80) by means of a union nut (79) and the nozzle (55) is ultimately fixed with it. The union nut (79) holds the nozzle holder (78) from the outside without engaging in its conical recess (81). The recess (81) is of a conical shape in such a way that it widens continuously with increasing distance from the nozzle openings. The recess (81) has a cone angle 2Θ.

Because the union nut (79) does not engage in the nozzle holder (78) from the outside, the recess (81) is formed exclusively by the nozzle holder (78).

Figure 2b shows an embodiment of the nozzle system (55) in side view, partially in section, which differs from Figure 2a in that this time the union nut also forms part of the conical shape (81). There are no steps in the recess (81) in the area of the transition from the nozzle holder (78) to the union nut (79). The particles of the atomizing cloud, which then deposit in such a stage and contribute to the mouthpiece portion, can no longer be carried away by actuating the nebulizer again.

Figure 3 - Example

A Respimat brand device is used, analogous to FIG. 1. This device was modified in such a way that the critical surface, i.e. the recess (81), the

Nozzle system analogous to that of Figure 2, with the silicone paint Lotusan ^® of the company Dyckerhoff is coated.

Then the device is sprayed with an aqueous placebo solution and the amount of liquid deposited on the critical surface is measured compared to an uncoated device.

The trial will be for several devices with different opening 0s ° the conical angle

Recess repeated (Figure 3). The experiments prove that the microstructuring of the critical surface of the nozzle system advantageously reduces the amount of liquid deposited on the critical surface compared to a smooth nozzle system.

FIG. 4 shows a schematic illustration of a section of an embodiment of a nozzle body (55) with two nozzle openings in a side view.

The two nozzle channels (82) are arranged in such a way that the jets emerging from the nozzle openings (84) of the nozzle channels meet at an angle alpha = 90 ° at the collision point (85). The collision point (85) has an impact height h = 25 micrometers above the nozzle openings.

Figures 5 to 9 show examples of surface structures of polyester films with a structured acrylic layer, which can be glued to the critical surface of the nozzle holder and or the union nut

Slide 1 with structures in the 0.5 micron range.

Slide 2 with structures in the range of 2 micrometers.

Slide 3 with structures in the range of 2 microns and 10 microns superstructure.

Claims

claims

1. Nozzle for a dispensing device for liquids, which has a liquid inlet side and a liquid outlet side, characterized in that the outer surface of the liquid outlet side is micro- or nanostructured.

2. Nozzle according to claim 1, characterized in that the nozzle has at least one nozzle opening.

3. Nozzle according to claim 1 or 2, characterized in that the nozzle has at least two nozzle openings which are oriented such that those emerging therefrom

Impact liquid jets in front of the nozzle opening.

4. Nozzle according to one of the preceding claims, characterized in that the nozzle is formed from at least two structural units.

5. Nozzle according to one of the preceding claims, characterized in that the nozzle is formed from at least two plates lying one on top of the other, at least one of the plates having a second microstructure, so that the plates lying one above the other define a liquid inlet on one side to which a channel system is defined and / or a filter system which then connects into one or more

Liquid outlets open.

6. Nozzle according to claim 5, characterized in that the nozzle has at least two nozzle outlets oriented towards one another.

7. Nozzle system for a dispensing device for liquids, consisting of a nozzle and a nozzle holder with an end face, which has a continuous bore or hole and the inside of which contacts the liquid outlet side of the nozzle, the nozzle openings being in or below the bore and / or a union nut whose end face has a continuous bore or hole and which has the nozzle holder on its end face or the nozzle on its liquid outlet side touched, characterized in that at least one of the following surfaces is micro or nano structured:

- The outer surface of the liquid outlet side of the nozzle and / or

- The outer surface of the end face of the nozzle holder and / or - The side wall of the bore or hole of the nozzle holder and / or

- The outer surface of the end face of the union nut and / or

- The side wall of the bore or the hole of the union nut.

8. A nozzle system according to claim 7, characterized in that a nozzle holder is formed, the bore or hole of which is formed as an inner recess which widens continuously from the nozzle openings.

9. Nozzle system according to claim 7, characterized in that a union nut is formed, the bore or hole of which is formed as an inner recess which widens continuously from the nozzle openings.

10. Nozzle system according to one of claims 7 or 8, characterized in that the side of the recess facing away from the nozzle opening is micro- or nanostructured.

11. Nozzle system according to one of claims 7 to 10, characterized in that the nozzle has the features of a nozzle according to claim 1 to 6, wherein the micro or nanostructure of the liquid outlet side is optional.

12. Application device for liquids, characterized in that it has a nozzle according to claims 1 to 6 or a nozzle system according to one of claims 7 to 11.

13. Application device according to claim 12, characterized in that it is an atomizer for pharmaceutical liquids.

14. Application device according to one of claims 12 to 13, characterized in that the device a lower and an upper rotatably mounted against each other Housing part has, in the upper housing part a spring housing is formed with a spring, which is tensioned by rotating the two housing parts via a locking mechanism, preferably in the form of a screw thread or gear, and relaxed by pressing a release button on the upper housing part, the spring moving an output flange that moves with a hollow piston is connected, at the lower end of which a container can be plugged on and at the upper end of which there is a valve and a pressure chamber which is connected to the nozzle or the nozzle system which is formed in the region of the housing upper part which is open at the top, is in a liquid-conducting connection.

15. Dispensing device according to one of claims 12 to 13, characterized in that the device is an inhaler or another nebulizer for medical liquids.

16. Nozzle according to one of claims 1 to 6, nozzle system according to one of claims 7 to 11 or application device for pharmaceutical liquids according to one of claims 13 to 15, characterized in that the micro- or nanostructure by elevations and depressions with height / depth of 0.1 to 100 micrometers is formed on at least one of the following surfaces: the outer surface of the liquid outlet side of the nozzle and / or

- The outer surface of the face of the nozzle holder and / or

- The side wall of the bore or hole of the nozzle holder and / or

- The outer surface of the end face of the union nut and / or

- The side wall of the bore or the hole of the union nut.

17. Nozzle, nozzle system or dispensing device for pharmaceutical liquids according to claim 16, characterized in that the micro- or nanostructure is created by elevations and depressions, the distances between the elevations and depressions being in the range from 0.1 to 200 micrometers.

18. Nozzle, nozzle system or dispensing device for pharmaceutical liquids according to one of claims 16 or 17, characterized in that at least 20% of the corresponding surface is micro- or nanostructured, more preferably at least 50%, even more preferably at least 75%.

19. Nozzle, nozzle system or application device for pharmaceutical liquids according to one of claims 16 to 18, characterized in that the micro- or nanostructured surfaces by hydrophobic materials such as glass and / or ceramics and or metals and / or plastics such as polyethylene, polypropylene , Polycarbonate, polyacrylates, polyesters, silanes are formed. ■

20. Nozzle, nozzle system or application device for pharmaceutical liquids according to one of claims 16 to 18, characterized in that the micro- or nanostructured surfaces are created by subtractive or additive treatment of the surfaces, such as embossing, etching, laser ablation, galvanic

Removal, sticking of a structured film, sticking on a powder, spraying with suspensions, deposition of sublimates.