CS209388B1 - Portable inhaler for continuous cycle changes of rhytmic supply of aerosol with interrupted overpressure - Google Patents

Abstract

The present invention relates to the field of medical technology. The portable inhaler for continuous changes in rhythmic aerosol delivery cycles with intermittent overpressure addresses the problem of eliminating the patient's irregular rhythm. SUMMARY OF THE INVENTION The present invention provides a portable inhaler according to the invention which is provided with a cycler consisting of a working chamber formed by a cycler jacket and a partition separating the volume chamber of the rhythm and the working chamber of the cycler connected to each other by a lance attached to the partition at its center and passing through the working chamber, wherein, the lance is terminated by a seat behind which it is adjustable in the direction of the lance; the regulating spindle fixed in the cycling head and between the inlet pipe seat and the regulating spindle is fixed perpendicular to the inlet pipe in the housing! cycling barrier membrane. An exemplary embodiment of the portable inhaler shown in the accompanying drawing is shown in the application.

Description

(54) Portable inhaler for infinitely varying cycles of intermittent positive pressure rhythmic delivery cycles

The present invention relates to the field of medical technology. A portable inhaler for continuous variation of intermittent pressurized aerosol delivery cycles solves the problem of eliminating irregular patient rhythm. SUMMARY OF THE INVENTION The present invention provides a portable inhaler according to the invention comprising a cycler comprising a working chamber consisting of a cycler housing and a partition separating the rhythm volume chamber and the cycler working chamber connected to each other by a lance attached to the bulkhead at its center and passing through the working chamber. the supply pipe is terminated by a seat behind which it is adjustable in the direction of the supply pipe; The control spindle mounted at the front of the cycler and between the inlet pipe seat and the control spindle is mounted perpendicular to the inlet pipe in the housing! cyclers closing membrane.

An exemplary embodiment of a portable inhaler is shown in the accompanying drawing of the application. ‘

SUMMARY OF THE INVENTION The present invention provides a portable inhaler for continuously varying cycles of intermittent pressurized aerosol delivery cycles provided with a rhythm device comprising a volume chamber, an outlet chamber ^. and a diaphragm chamber separated from the volume chamber and the outlet chamber by a working diaphragm and a seal on the volume chamber seat, wherein the diaphragm chamber is separated from the atmosphere by a diaphragm firmly connected by a diaphragm distribution to the diaphragm to the outlet chamber connected by an outlet duct the irrigation head and the supply line terminated by the inlet nozzle are connected both to the volumetric chamber and through the duct terminated by the compensating nozzle to the membrane chamber.

; The prior art inhalation devices can be divided into two groups as long as aerosol production is desired. The first group, the largest consists of devices that still produce aerosol, ie from the inhalation head emits a continuous continuous stream of inhalant. The nozzle that atomises the inhalant must still be in operation. The second group consists of inhaled devices with intermittent aerosol delivery, where the inhaler breath is used, ie aerosol is produced by inhalation and not by exhalation. Inhaling by inhalation creates negative pressure. At a very low vacuum, the air from the pressure source is directed by the inhaler into the spray nozzle in the irtation head, where the inhalant substance is sprayed. Upon exhalation, the inhaler stops the supply of pressurized air to the spray nozzle and thereby interrupts the spraying of the inhalant. Thus, aerosol formation is dependent on the breath of the inhaler. Both the inhaler breathes and the spray nozzle that generates an aerosol operates. Given that a healthy adult breathes in a 1/3 rhythm of a 2/3 inhale, we can see that the first group of 2/3 inhalants are sometimes very expensive to produce in space and this is not used. The operator is thus forced to inhale indirectly. These are about a few hours a day with various respiratory diseases in these people. Considering that they inhale people suffering from respiratory tract illnesses with concomitant breathing, the second group's devices save drug, do not contaminate the environment, but depend on the inhalation rhythm of the inhaler. Thus, the rhythm of the device is irregular as the inhalation breath. The purpose of the whole procedure is to get the drug sprayed into small particles into the lowest part of the lungs. This implies that the lungs work in a given rhythm 1/3 inhale and 2/3 exhale. The disadvantage of the second group of inhalation devices is that only the effect of the inhalation agent on the patient is used, but the bad and irregular rhythm of the breath is not corrected, on the contrary it is supported by the device adapting to this inhalation respiratory rhythm.

The aforementioned drawbacks are remedied by a portable inhaler for continuously varying cycles of an intermittent pressurized rhythmic aerosol delivery system of the present invention comprising a cycler consisting of a working chamber consisting of a cycler shell and a partition separating the rhythm volume chamber and the cycler working chamber connected to each other by a lance attached to The inlet tube is terminated by a seat through which in the direction of the inlet tube there is an adjustable control spindle mounted at the front of the cycler and a closing diaphragm is mounted perpendicularly to the inlet tube in the cycler casing between the inlet tube seat and the control spindle. .

The accompanying drawing shows a schematic illustration of a drawing ^. An exemplary embodiment of an inhaler according to the invention.

The portable inhaler for continuously varying cycles of the intermittent positive pressure aerosol delivery system comprises, on the one hand, a rhythm device 1 comprising a volume chamber 3, an outlet chamber 10 and a membrane chamber 11 separated from the volume. chamber 3 and outlet chamber 10 of working diaphragm 9 abutting seal 13 on seat 14 of volume chamber 3, the diaphragm chamber 11 being from. The outlet chamber 10 is connected by the outlet duct 21 terminated by the outlet nozzle 17 with the inhalation head 18 and the supply line 19 terminated by the inlet nozzle 16 is connected both to the volume chamber 3 and through the duct 20 and a cycler 25 consisting of a working chamber 2 consisting of a casing 22 and a partition 4 separating the rhythm volume chamber 3 and a working chamber 2 of the cycler 25 connected to each other by an inlet pipe 23 attached to the partition 4 at its center. The inlet pipe 23 is terminated by a seat 5 behind which in the direction of the inlet pipe 23 an adjusting spindle 7 is mounted mounted in the front 24 of the cycler 25, and between the inlet pipe seat 5 and the regulating spindle 7 is perpendicular The inlet pipe 23 is reinforced in the housing 22 of the cycler 25 by the closing membrane 6.

After connecting the compressed air to the supply line 19, the compressed air passes through the channel 20 into the diaphragm chamber 11 via the equalizing nozzle 15 and at the same time through the inlet nozzle 16 into the chamber 3, the pressure in the diaphragm chamber 11 rising faster than This is due to the cross-sectional difference between the equalizing nozzle 15 and the inlet nozzle 16. The air pressure in the diaphragm chamber 11 acts on the effective area of the working membrane 9 and the equalizing membrane 12, the effective area of the working membrane 9 being greater than that of the equalizing membrane 12. towards the seat 14 of the volume chamber 3 on which the seal 13 sits and closes. Upon closing, the pressure in the chamber 3 increases to a certain pressure, for example to 80% of the pressure, in the membrane chamber 11 and just pushes the membrane assembly and the seat 14 is abruptly flushed, bringing air from the chamber 3 into the outlet chamber 10 the nozzle 17 has a larger cross section than the inlet nozzle 16 and hence emptying (the volume chambers 3 are faster than filling them).

As soon as the pressure in the chamber 3 drops to 10% of the pressure in the diaphragm chamber 11, the force that held the diaphragm assembly open is less than the force against it in the diaphragm chamber 11 and the seat closes again (14 and the cycle repeats). The rhythm, i.e. the ratio of breathing to exhalation, i.e. the filling and emptying of the chamber 3, is determined by the diaphragm set and the difference in the nozzle cross-section n. we will eliminate the activities of the washing machine

Claims (2)

SUBJECT Portable inhaler for continuous change of cycles of rhythmic delivery of aerosqkis by intermittent overpressure equipped with a volume-containing rhythm device chamber, outlet chamber and diaphragm chamber separated from the volumetric chamber and the outlet chamber (s) by a working membrane abutting the gray chamber of the chamber, wherein the membrane chamber is separated from the atmosphere by an equalizing membrane firmly connected by diaphragm distribution to the working membrane; outlet nozzle with inhalation head and inlet pipe terminated by the inlet nozzle is connected both to the volumetric chamber and through the duct terminated by the equalizing nozzle to the membrane chamber 2. This will fill and empty the volume chamber 3 and the frequency will be the fastest; that is, a small amount of air, but more cycles per minute. If the regulating spindle 7 is released, the closing diaphragm 6 will not be pressed against the seat 5 of the inlet pipe 23 and the volume chamber 3 will increase by the working chamber 2 of the cycler 25 and thus increase the volume, filling will be slow and emptying too. (This implies that the frequency will be the slowest, less air, but less cycles per minute. By properly controlling the gap between the working diaphragm 6 and the inlet tube seat 5, the intermittent span 7 can be set by means of the control spindle 7. ‘It is possible to use the device outside the medical oblaisti in rescue equipment for mining, water and sports - to inject air into the affected air at the most suitable breathing frequency, ie to force the lungs to work. OF THE INVENTION a chamber, characterized in that it is provided with a cycling device (25) comprising a working chamber (2) comprising a housing (22) of the cycler (25) and a partition (4) separating the volume chamber (3) of the rhythm device (1) and the working chamber (2) ) a cycler (25) connected by an inlet pipe (23) attached to the bulkhead (4) at its center and passing through the working chamber (2), the inlet pipe (23) terminating in a seat (5) behind it 23) there is an adjustable spindle (7) mounted in the front (24) of the cycler (25) and between the seat (5) of the supply pipe (23) and the control spindle (7) is perpendicular to the supply pipe (23) in the housing (22). ) cyclers (25) closing membrane (6).