DE29509286U1 - Device for atomizing fluids - Google Patents

Description

DEVICE FOR NEBULIZING LIQUIDS

The invention relates to a device for atomizing fluids according to the preamble of claim 1.

Devices are known in medical technology which are used for inhalation therapy. Such inhalers work, for example, with an atomizer nozzle which has a tapered nozzle bore. Pressurized gaseous pressure medium emerges from this nozzle bore, whereby a liquid medication can be sucked in from intake channels which are arranged adjacent to the nozzle bore. This sucked in liquid medication is then sprayed against a nozzle which is opposite the nozzle bore.

153-X2713-MaWa

The aerosol particles are then thrown onto the impact surface of a gas flow control arranged in the outlet cone of the compressed gas, so that aerosol droplets are generated. These aerosol droplets then flow against an impact screen, which further breaks up larger aerosol particles, so that respirable (intrathoracic) particle sizes of approximately 0.5 to 5 μ΄α are generated.

Such a jet nebulizer is known, for example, from EP-A-O 170 715.

However, since such jet nebulizers produce aerosol droplet diameters of 5 μ΄α and less, they are not suitable for applications that require larger droplet diameters. One example of such an application is topical inhalation anesthesia, which is used, for example, when carrying out bronchological examinations. In contrast to inhalation therapy, this requires much larger aerosol particles at a high output.

According to the state of the art, ultrasonic inhalers are also known that achieve atomization by means of ultrasound. However, such ultrasonic atomizers have the disadvantage that the medium being sonicated is subjected to a change mainly through cavitation, which can even lead to the destruction of the medium. The cavitation effects can thus destroy, for example, molecular chains of medications, since the ultrasound has a strong local effect on the medication. This changes the properties of the medication, which in turn is not acceptable for use in anesthesiology.

The object of the invention is to provide a device for nebulizing fluids which generates a droplet spectrum that is suitable for topical inhalation anesthesia.

This problem is solved by the features of the independent protection claim. The dependent protection claims give advantageous embodiments and further developments of the invention.

The device according to the invention for nebulizing fluids has a nebulizer lower part and a nebulizer upper part detachably connected to it. The two nebulizer parts are arranged rotationally symmetrically to one another. An insert can be pressed into the nebulizer lower part, which serves to hold fluid. This fluid is, for example, an anesthetic for carrying out topical inhalation anesthesia. An air supply arrangement and an outlet nozzle for generated aerosol droplets are provided in the nebulizer upper part. The air supply arrangement is arranged rotationally symmetrically to the nebulizer upper part and is essentially formed by a hollow cylindrical channel that is conically widened towards the air inlet side. A nozzle arrangement is also detachably provided in the insert, which is arranged rotationally symmetrically to the air supply arrangement.

The inventive design of the nebulizer enables an aerosol droplet spectrum to be achieved at the outlet nozzle of the nebulizer upper part, the medial mass diameter distribution of which has a maximum at 8.5 μ΄α . This means that no aerosol droplets that can be inhaled into the lungs are produced, but rather a deposition of the aerosol droplets occurs in the throat, the glottis and the bronchi.

en. For example, when carrying out bronchological examinations, topical inhalation anesthesia can be carried out with high efficiency. Furthermore, by providing an interval button, the anesthetic can be dosed. This avoids losses, as the respective preparation is only nebulized when the patient inhales. Furthermore, the parts of the nebulizer can be made of temperature-stable plastic, so that the nebulizer can be fully sterilized, boiled, and is dishwasher-safe.

In addition, the insert used as a measuring cup can be exchanged so that it can be used for different nebulizers. This means that a measuring cup can always be filled with the same medication, which can improve the handling of the device.

According to the invention, by coordinating the nozzle arrangement, the insert, the nebulizer upper part with the supply air arrangement and the outlet nozzle, an arrangement is created which creates an indication-specific droplet spectrum that is very well suited for topical inhalation anesthesia for carrying out bronchological examinations, for example.

In the following, embodiments of the invention are explained in more detail with reference to the accompanying drawings. They show:

Fig. 1 shows a partially sectioned embodiment of a nebulizer according to the invention;

Fig. 2 is a cross-sectional view of an embodiment of a medication cup according to the invention with a mounted nozzle arrangement;

Fig. 3 a cross-sectional view of an embodiment of a nebulizer upper part according to the invention with a supply air arrangement and an outlet nozzle and

Fig. 4 shows a partially sectioned embodiment of a nebulizer base according to the invention with interval button.

Fig. 1 shows a nebulizer with a nebulizer lower part 1 and a nebulizer upper part 2. An insert 5 is arranged in an upper section of the nebulizer lower part 1 so that it can be inserted. This insert 5 serves, among other things, as a medication cup. A nozzle arrangement 6 is provided in the insert 5. The nozzle arrangement 6 has a bore 9 which engages with a pin 10. The pin 10 in turn has an inner bore 11 which is connected to a supply channel 12 for compressed air. The supply channel 12 is also connected to an air outlet opening 14 via a connecting bore 13. The air outlet opening 14 can be closed by an interval button 15 provided in the nebulizer base 1, so that the compressed air supplied via the supply channel 12 flows via the inner bore 11 of the pin 10 into a compressed air channel 20 of the nozzle arrangement 6.

The upper section of the nebulizer base also has, for example, two openings 3 7 through which the insert 5 or the medication cup can be viewed.

Since the medication cup is preferably made of a transparent material, the current fill level of the medication cup can be checked.

A supply air arrangement 3 is inserted into the nebulizer upper part 2; this arrangement has a hollow cylindrical channel 7 on the air outlet side of the supply air arrangement 3 and a conical extension 8 on the air inlet side of the supply air arrangement 3. A hollow cylindrical outlet nozzle 4 is also formed on the nebulizer upper part 2, which can be connected to a mouthpiece (not shown). The patient can inhale the aerosol droplets generated by the nozzle arrangement 6 through this mouthpiece.

The nebulizer according to the invention can be easily put together or assembled thanks to the advantageous design of its parts. Starting, for example, with the nebulizer base 1 with the interval button 15 already provided, the insert 5 with the nozzle arrangement 6 inserted can be placed on the pin 10 or inserted into the upper section of the nebulizer base 1. The insert 5 can be filled with the appropriate anesthetic before it is inserted into the nebulizer base 1, for example, but it is also possible to only dose the anesthetic into the insert 5 once it has been inserted.

The nebulizer upper part 2 can then be attached to the nebulizer lower part 1. The connection can be made via a screw connection, whereby an external thread 16 arranged on the nebulizer lower part 1 fits into an internal thread 17 arranged on the nebulizer upper part 2.

engages. The nebulizer upper part 2 has the air supply arrangement 3, which is detachably inserted into the nebulizer upper part 2. The inserted air supply arrangement 3 is in the assembled state in a positive connection of a section of the extension 8 with an inner peripheral section 18 of the nebulizer upper part 2. In an upper area of the nebulizer upper part 2, the outlet nozzle 4 is arranged, which is inclined upwards at an angle of preferably 5° from a normal to the axis of symmetry of the nebulizer upper part 2. The mouthpiece (not shown) can then be pushed over this outlet nozzle 4.

When the nebulizer is in operation, compressed air is supplied to the supply channel 12. If the interval button 15 is not operated, this supplied compressed air flows out of the air outlet opening 14. If the interval button 15 is now operated, the supplied compressed air flows through the compressed air channel 20 of the nozzle arrangement 6 and exits through a nozzle 38 of the nozzle arrangement 6 (see Fig. 2). The compressed air flowing out of the nozzle 38 is deflected by a gas flow control 19 in such a way that a negative pressure is created in the intake channels 21 of the nozzle arrangement 6. A lower end 34 of the intake channel 21 opens into a lower region of the insert 5. During operation, the insert 5 is filled with fluid in such a way that the lower end 34 of the intake channel 21 is covered with fluid. Due to the negative pressure created at an upper end 35 of the intake channel 21, fluid is now sucked out of the insert 5 into the intake channels 21 and finely distributed by the compressed air exiting through the nozzle 38. The resulting aerosol particles preferably have a median mass diameter distribution that has its maximum at 40 μδα . These generated aerosol particles are now, for example,

an impact on a lower edge 22 of the hollow cylindrical channel 7 and by impact processes on the outer wall of the hollow cylindrical channel 7 and the inner wall of the nebulizer upper part 2.

To inhale the aerosol particles produced, the patient creates a negative pressure at the outlet nozzle 4 via the mouthpiece, which creates an air flow through the supply air arrangement 3 from top to bottom in the direction of the nozzle arrangement 6. This air then flows through an annular channel 33 from bottom to top to the outlet nozzle 4. The annular channel 33 is essentially formed by an outer surface 35 of the supply air arrangement 3 and an inner surface 36 of the nebulizer upper part 2.

Due to the geometric design and coordination of the individual components with one another, in particular the nozzle arrangement 6, the supply air arrangement 3, the inner wall of the nebulizer upper part 2 and the outer wall of the outlet nozzle 4, aerosol droplets can be produced with a median mass diameter distribution which preferably has a maximum at 8.5 μδα . The nebulizer according to the invention is therefore particularly suitable for topical inhalation anesthesia, for example for carrying out bronchological examinations.

With the selected geometry, it has been found to be advantageous that the compressed gas preferably has an overpressure of 1.1 · 10 ^s Pa, whereby a total output of about 800 mg/min can be generated.

Fig. 2 shows an enlarged view of the insert 5 with the nozzle arrangement 6. The insert 5 is partially filled with a fluid 23. In this

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Fluid 23 is, for example, the anesthetic used. This figure shows that during operation the upper edge of the fluid 23 is arranged above the lower openings 34 of the intake channels 21. This allows the fluid 23 to be sucked into the intake channels 21 and then exit from the corresponding upper openings 2 6. The fluid 23 is then atomized by the gas flow deflected from the nozzle 3 8 and from the gas flow control 19. When inserted into the nebulizer upper part 2, the medication cup comes to rest on an upper edge of the nebulizer lower part via a step 24. Furthermore, the insert 5 is in contact with the nebulizer lower part 1 via a lower support surface 27. The nozzle arrangement β is arranged rotationally symmetrically to the insert 5. An O-ring 25 is arranged between the nozzle arrangement 6 and the insert 5. The O-ring 25 seals the nozzle arrangement S against the insert 5.

The nebulizer upper part 2 is shown in Fig. 3. The nebulizer upper part 2 is essentially cylindrical and has the internal thread 17 on its lower side. The supply air arrangement with the conical extension 8 is arranged in a form-fitting manner on the inner circumferential section 18 of the nebulizer upper part 2. The supply air arrangement 3 has a projection 28 at the upper end, which is supported against the upper edge of the nebulizer upper part 2. The supply air arrangement 3 can thus be inserted into the nebulizer upper part 2, whereby the projection 28 results in a defined position. In the inserted state, the supply air arrangement 3 is arranged rotationally symmetrically to the nebulizer upper part 2. The nozzle 4 is formed on the nebulizer upper part 2. The hollow cylindrical channel 7 of the supply air arrangement 3

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the ring channel 33 is formed between the outer surface 35 of the hollow cylindrical channel 7 and the inner surface 36 of the nebulizer upper part 2. The fluid mechanical processes occurring in this ring-shaped flow space contribute, among other things, to the preferred aerosol droplet diameter being generated. The dimensions of these components are selected such that a diameter ratio measured at a medium height between the inner diameter of the nebulizer upper part 2 and the outer diameter of the hollow cylindrical channel 7 can preferably be about 1.8. The wall thickness of the hollow cylindrical channel 7 can be about 1 mm and its inner diameter about halfway up can be 1.45 mm. The hollow cylindrical channel 7 can have a length of about 4.6 mm and taper slightly conically towards the air outlet side.

Fig. 4 shows the nebulizer base 1, which is essentially hollow-cylindrical in its lower section. In an upper section of the nebulizer base 1, it has the interval button 15. Opposite the interval button 15 is the supply channel 12 for the compressed air. This supply channel 12 is connected to the inner bore 11 of the pin 10 and to a connecting bore 13 to the air outlet opening 14. When the interval button 15 is not actuated, it is pressed outwards to a stop by a compression spring 29, so that a fluid connection is created between the supply channel 12, the connecting bore 13 and the air outlet opening 14. When the interval button 15 is pressed, the air outlet opening 14 or the connecting hole 13 is closed so that the pressure medium flowing into the supply channel 12 passes through

the inner bore 11 into the pin 10 and thus into the nozzle arrangement 6. The pin 10 has a step on which an O-ring 31 is arranged. When the arrangement shown in Fig. 2 is placed on the pin 10 (see also Fig. ₁₁₎ , the O-ring 31 seals the nozzle arrangement 21 against the pin 10. Furthermore, an annular locking disk 3 2 is formed on the top of the pin 10. The locking disk 3 2 serves on the one hand to fix the O-ring 31 in such a way that it does not slip off the pin when the nozzle arrangement 6 is removed and on the other hand to lock the nozzle arrangement in place when inserted.

The nebulizer according to the invention is particularly suitable for use in topical inhalation anesthesia, since aerosol droplet diameters are generated that lead to deposition in the throat, glottis and bronchi. Furthermore, a droplet spectrum is generated that is not respirable, since such a droplet spectrum is unfavorable for inhalation anesthesia. Due to the indication-specific droplet spectrum, the device according to the invention is preferably suitable for the preparation of bronchological examinations, whereby the nebulizer described can preferably be used for topical inhalation anesthesia in preparation for an intervention.

Claims (10)

PROTECTION CLAIMS 1. Device for atomizing fluids with - a nebulizer base (1), - a nebuliser upper part ( 2) arranged rotationally symmetrically to the nebuliser lower part (1), which has an air supply arrangement (3) for supplying additional air and an outlet nozzle (4) for discharging nebulised fluid (23), - an insert (5) for receiving the fluid (23) and - a nozzle arrangement (6) which is rotationally symmetrical to the supply air arrangement (3), characterized in that the supply air arrangement (3) has a hollow cylindrical channel (7) towards the air outlet side. 2. Device according to claim 1,
characterized in that the supply air arrangement (3) has a conical extension (8) towards the air inlet side. 3. Device according to claim 1 or 2, characterized in that the nebulizer lower part (1) is detachably connected to the nebulizer upper part (2). 4. Device according to at least one of claims 1 to 3, characterized in that the nebulizer base (1) detachably receives the insert (5) and the nozzle arrangement (6) is detachably arranged in the insert (5). 5. Device according to at least one of claims 1 to 4, characterized in that the nebulizer base (1) has a pin (10) which engages in a bore (9) of the nozzle arrangement (6) when the insert (5) with the nozzle arrangement (6) is inserted into the nebulizer base (1). 6. Device according to at least one of claims 1 to 5, characterized in that the pin (10) has an inner bore (11) which is connected to a supply channel (12) for compressed air, whereby when an insert (5) is inserted into the nebulizer base (1) with the inserted nozzle arrangement (6), a fluid connection is created between the supply channel (12) and a compressed air channel (20) of the nozzle arrangement (6) and that an interval button (15) is provided for interrupting the compressed air flow. 7. Device according to at least one of claims 1 to 6, characterized in that the insert (5) is made of a partially transparent material and the nebulizer base (1) has at least one opening (37) which allows a view of the insert (5). * 9 14 ·· 8. Device according to at least one of claims 1 to 7, characterized in that the nozzle arrangement (6) has two intake channels (21) for the fluid (23) and a gas flow control (19), wherein the nozzle arrangement (6) generates aerosol particles with a median mass diameter distribution which preferably has a maximum at 40 μιδα . 9. Device according to at least one of claims 1 to 8, characterized in that the nozzle arrangement (6), the supply air arrangement (3) of the nebulizer upper part (2), the inner surface of the nebulizer upper part (2) and an annular channel (33) formed between an outer surface (35) of the supply air arrangement (3) and an inner surface (36) of the nebulizer upper part (2) are designed and coordinated with one another in such a way that aerosol droplets are generated with a median mass diameter distribution which preferably has a maximum at 8.5 μηα . 10. Device according to at least one of claims 1 to 9, characterized in that the compressed gas preferably has an overpressure of 1.1 · 10 ⁵ Pa and a total output of preferably 800 mg/min is generated.