DE8905364U1 - Inhaler for aerosol therapy - Google Patents

Description

Paul Ritzau Pari-Werk GmbH & Co. D-8130 Starnberg

Inhaler for aerosol therapy

The invention relates to an inhaler according to the preamble of claim 1.

An inhaler of this type is described, for example, in European Patent Specification 170 715. In the previously known inhaler, opposite the mouth of the atomizer nozzle in the outlet cone of the pressurized gas there is a gas flow control which is wedge-shaped on its side opposite the nozzle opening ^and which is arranged near the mouth plane of the nozzle opening for the pressurized medium. To improve the formation of aerosols ^, the previously known inhaler also has a cylindrical insert with a baffle screen extending outwards and downwards into the nebulizer chamber at the lower end of an air supply chimney.

Concerns have been raised in modern aerosol therapy that pollutants from the treatment room can enter the patient's respiratory tract through the supply air chimney, something that one would like to avoid while maintaining the good nebulizing effect of an inhaler.

It is therefore the aim of the invention to further develop an inhaler of the type described above in such a way that it enables the production of a lung-penetrating aerosol, i.e. a

• I ···■ r«··

!»■■&Igr; ·· · rm w.m

Aerosols with the highest possible proportion of small particles in a closed nebulizer housing, even without an additional baffle screen.

According to the invention, this object is achieved with an inhaler of the type mentioned, which is characterized by the features of the characterizing part of claim 1. Further features emerge from the subclaims.

Through the clever sequential arrangement of a lower, essentially closed mixing chamber and an upper open mixing chamber with an impact head, a particularly high yield of aerosol fractions with very small particle sizes can be achieved, as can be easily determined by comparing the inhaler according to the invention with a known modern therapeutic nebulizer.

Further details of the invention emerge from the description of an embodiment shown in the drawing.

In the drawing show:

Fig. 1 A central longitudinal section through the inhaler according to the invention,

Fig. 2 is an enlarged view of the improved nozzle for the inhaler according to the invention as shown in Fig. 1,

Fig. 3 is a front view of the nebulizer nozzle according to Fig. 2, Fig. 4b is the particle spectrum of a sample taken with the inhaler according to

aerosol produced by the invention,

Fig. 4b shows the particle spectrum of an aerosol generated with a known inhaler for comparison.

As can be seen from Fig. 1, the inhaler consists in a known manner of the actual nebulizer container 1 and the nebulizer nozzle 2 inserted into the container 1.

The nebulizer consists of a container part 3 which widens conically towards the top and serves as a container for the nebulizer liquid 4. The cylindrical base 13 of the nebulizer nozzle 2 is inserted from below into the foot 5 of the container bottom part 3 with an interposed ring seal 6. A container top in the form of a nebulizer hood 7 which tapers conically towards the top and has an integrated outlet nozzle 8 with a side outlet 9' is placed on the container bottom part. In aerosol therapy, a breathing mask or mouthpiece is connected to this nozzle in the known manner.

A handle with an integrated compressed gas connection and manually operated valve can be attached to the base 5. The cylindrical hole 10 in the base 13 of the nebulizer nozzle 2 is used to connect the pressure line from the compressor, which is not shown in the drawing. The compressed air introduced into the nebulizer nozzle 2 via the hole 10 is used to atomize the nebulizer liquid 4. However, it is also used to discharge the aerosol from the interior 11 of the housing 1 to the outlet 9.

The structure and mode of operation of the nebulizer nozzle 2 are described below: Its structure is best

••••I ·· * · 4 · ·

2 and 3. The nebulizer nozzle 2 consists of the nozzle body 12 with the central channel/ which extends in the base 13 first over the bore 10/ then over the smaller diameter bore 14 and finally to the even smaller nozzle bore 15 in the head 16 of the nozzle body 12. The mixing chamber 17 is placed on the nozzle body 12 as a second part, which is held on the nozzle body 12 by the cap 20 that encloses it. This third part of the nozzle 2 formed by the cap 20 has an outer contour that corresponds to the nozzle body

In the upper open part of the cap 20, an impact head in the form of a spherical cap is inserted as a fourth part. In the embodiment shown, the impact head has a pin 22 which is pressed into the bore 23 of the upper end wall 24 of the cap 20. The upper end wall 24 has, as can be seen from Fig. 3, circular sector ^- shaped recesses 26-29 through which the aerosol can exit from the upper open mixing chamber 35 into the interior 11 of the nebulizer housing 1. These recesses extend not only in the area of the end wall 24 but also over the cylindrical side wall of the cap. downwards to the area of the cover 18 of the mixing chamber 17.

The inner contour of the cap 20 is adapted in its shape to the outer contour of the mixing chamber 17, while, as already mentioned, the outer contour of the cap 20 is adapted to the nozzle body 12. However, the cap 20 can also follow the conical inner contour in its outer contour, whereby the step 25 is omitted. Between the recesses 26-29, webs 30-33 are arranged, which are not only formed in the upper end wall 24 of the cap,

5W W VVWV ■.·.

but also extend over the upper cylindrical region of the cap 20 to the cover 18 of the mixing chamber 17. This cover 18 of the mixing chamber 17 is concavely curved to ensure that nebulizer liquid condensed in the upper chamber 35, on the ribs 30-33 or on the impact head 21 finds its way through the bore 19 in the cover 18, the mixing chamber 17 and the channels 36 and 37 back to the nebulizer liquid 4 in the lower part of the container 3. The oppositely disposed oblique intake channels 36, 37 connect the suction channels 36 , 37 of the lower part of the container 3 with the lower closed mixing chamber 34 in the mixing chamber 17.

The new nebulizer nozzle in the inhaler according to the invention works as follows: When connected to a compressor, compressed air is pumped through the cylindrical bore 10 and the other bores 14 and 15 into the interior 34 of the mixing chamber 17 and passes through the ^bore 19 into the upper chamber 35 of the cap 20. Due to the tapering of the bores 10-14-15, the speed of the compressed air increases considerably and reaches practically the speed of sound when it exits the head 16 of the nozzle body 12. The compressed air accelerated in this way sucks nebulizer liquid 4 from the lower container part 3 of the nebulizer housing 1 from the intake channels 36, 37 in the nozzle body 12 in a known manner. This leads to the formation of aerosols in interaction with the inner walls of the mixing chamber 17 in the lower closed mixing space 34. The aerosol formed here is further hurled through the bore 19 against the opposite impact head 21 in the ceiling area of the upper open mixing chamber 35 and further crushed. The aerosol droplets formed in the lower mixing chamber 34 are thus in the upper open mixing chamber

I I

II · ■ < I ·

&igr; a

35 which is connected to the interior 11 of the nebulizer housing 1 through the recesses 26 to 29, is further crushed. The analysis of the aerosol spectrum generated by the nebulizer according to the invention shows that the fractions of very fine aerosol particles valuable for therapy are considerably larger than in a modern aerosol therapy nebulizer according to EP 170 715.

The following table shows the respective proportions of the aerosol fractions sorted by droplet size for the &ohgr; *- P 4 mA\mn anoma (Xt*r\ \7a r &eegr;&agr;&Ugr;\ 1 ay annonohon &Pgr;&igr;&ogr; 7. &lgr;&EEgr;"1&ogr;&tgr;*&igr;&tgr;&tgr;\&Lgr;&ogr;&ggr;

The second column contains the comparative figures for the nebuliser according to EP 170 715.

.' -i T

Table

Particle size of the aerosol fraction (in -u)

0 - 1.2 1.2 - 1.5 1.5 - 1.9 1.9 - 2.4 2.4 - 3.0 3.0 - 3.9 3.9 - 5.0

5.0 - 6.4 6.4 - 8.2 8.2 - 10.5

10.5 - 13.6

13.6 - 17.7

17.7 - 23.7 larger particles

Weight% EP170 715 invention 7.4 12.0 1.9 5.8 2.8 2.8 3.0) 2.4 6.0 6.0 IC, 8 10.2 10.7 9.6 43.1 48.8 12.6 ^r ' 13.0 16.4 ''" 15.8 14.1 10.3 9.1 6.4 4.1 4.5 0.6 1.2

total

100.0

100.0

The corresponding particle spectra are shown in Fig. 4a (invention) and 4b (EP 170 715) of the drawing.

The total proportion of the respirable aerosol, namely the aerosol with a particle size of up to about 5 _/ u, is, for example, as can be easily seen from the table above, 48.6% for the nebulizer according to the invention

compared to 43.1% for the known nebulizer according to EP 170 715 and thus also represents a clear improvement here. However, the increase in very small aerosol particles in the two lowest fractions is particularly clear (0 1.2%: 12.0% compared to 7.4% and 1.2 to 1.5/rev; 5.8% compared to 1.9%!). The good effectiveness of the new nebulizer is evidently due to the rear connection of two mixing and atomizing chambers, which have a favorable effect on the formation of particularly small aerosol particles.

ti «4-4 1 * t »

A»

List of reference symbols used

1 nebulizer housing

2 nebulizer nozzle

3 Container base = container for the nebulizer liquid

4 Nebulizer fluid

5 feet ^on 3

6 Sealing ring

8 outlet nozzles

9 Opening of the outlet nozzle

10 2ylind:ciscl?.e Hole in the base

11 Interior of the dealer

12 nozzle bodies

13 bases of 2

14 Drill hole in the smock part.

15 Nozzle hole in the head 16 ^T ' IS Head of the nozzle body 12 '^<J

17 Mixing chamber

18 Mixing chamber cover

19 Hole in the cover 18 of the mixing chamber

20 cap

21 Impact head in the form of a spherical cap

22 Impact head pin

23 Hole in the upper front wall 24 of the cap

24 upper front wall of cap 20 (open)

25 steps on the inner wall

26/ 27/ 28/ 29 circular sector-shaped recesses

30/ 31/ 32/ 33 ribs

34 first closed lower mixing chamber (interior 34 of the mixing chamber 17)

35 second open upper mixing chamber (interior of the open cap 20)

36/ 37 Intake ducts in

Claims (9)

1. Inhaler for nebulizing, distributing and mixing liquid nebulizer in or with gas medium? a pressurized gas flow for producing aerosols for inhalation purposes, which essentially consists of a container (3) for the atomized material (4) and a nebulizer hood (7) that can be placed on the container, as well as an outlet nozzle (8) for the aerosol, whereby the gaseous pressure medium emerging from a nebulizer nozzle (2) arranged centrally in the container sucks the atomized material (4) from suction channels (36, 37) adjacent to the nozzle, and in which means for mixing and dividing the aerosol particles are provided opposite the nozzle mouth in the outlet cone of the compressed gas, characterized in that these means are provided by a mixing chamber (17) with a closed first mixing space (34) concentrically surrounding the head (16; of the nozzle body (12), as well as by an open second mixing space (35) arranged axially symmetrically above the mixing chamber (17), as well as by a centrally in the second mixing chamber (35) is formed and that both mixing chambers (34, 35) are connected to one another via a bore (19) and are enclosed by a common cap (20) open in the region of the second mixing chamber. 2. Inhaler according to claim 1, characterized in that ■ · &igr; I I I &bull; · ' III · i > . t - < 10 t- ■ &igr;&igr; · &bull; ' lit · · · ·· · · I II« t I * > The outer contour of the mixing chamber (17) and the inner contour of the wall of the cap (20) are adapted to one another in a conical manner towards the top, such that by pushing the cap (20) onto a suitable circular recess on the nozzle body M (12) , the mixing chamber (17) is connected in a sealing and captive manner to the nozzle body (12) and that the suction channels (36, 37) for the nebulizer liquid (4) open into the first mixing chamber -s (34) within the mixing chamber (17). 3. Inhaler according to claim 1 or 2, characterized in that the central pressure gas line in the nebulizer nozzle tapers down to the nozzle bore (15) in the head (16) of the nebulizer nozzle. 4. Inhaler according to claim 3, characterized in that the central pressure gas line tapers in three stages via a cylindrical bore (10) in the base (13) via a narrower bore (14) in the middle part of the nozzle body (12) to the even narrower nozzle bore (15) in the head (16) of the ^nozzle body (12). 5. Inhaler according to one or more of claims 1 to 4, characterized in that the connection between the lower closed mixing chamber (34) and the upper open mixing chamber (35) is made through a central bore (19) in the cover of the mixing chamber (17), the diameter of which is smaller than the diameter of the impact head (21). 6. Inhaler according to one or more of claims 1 to 5, characterized in that the impact head (21) is shaped as a spherical cap opposite the bore (19). 7. Inhaler according to one or more of claims 1 to 6, ■' characterized in that the cover (18) of the mixing chamber (17) to the bore (19) sloping conical or spherical f &bull;' JL JU ^&mdash; &ogr;# » « « t , » is trained. 8. Inhaler according to one or more of claims 1 to 7, characterized in that the impact head (21) is seated in a bore (23) in the upper end wall (24) of the cap (20) and that this end wall as well as the side wall of the cylindrical cap (20) are perforated in the region of the upper mixing chamber (35) and have circular sector-shaped recesses (26 to 29) which are delimited by ribs (30 to 33). 9. Inhaler according to one or more of claims 1 to 8, characterized in that the inner contour of the cap (20) above the cover (18) of the mixing chamber (17) has an annular step (25) inclined outwards and upwards for transition to the narrower rib contour.