RU4079U1 - SIMULATOR INHALATOR - Google Patents

Abstract

1. The inhaler simulator, comprising a sealed vessel with holes for inhaling air, a coaxially mounted inside of it a cylindrical aerosol chamber with a bottom, in which the spray holes are made and which is placed with a gap relative to the bottom of the vessel, and also an additional container covering the inhaler vessel and having holes in which a breathing tube is placed with a gap, characterized in that the bottom of the aerosol chamber is made in the form of a spherical surface with holes whose axes are perpendicular about the tangent sphere at a given point. 2. The inhaler simulator according to claim 1, characterized in that a spherical disperser with holes is installed in the upper part of the aerosol chamber. Inhaler simulator 1 and 2, characterized in that the breathing tube is equipped with a spherical expander. 4. The inhaler simulator according to claims 1 to 3, characterized in that the external vessel with a variable volume has an opening for communication with the atmosphere on a cylindrical surface in the zone of connection of the lid and the bottom of the vessel with an adjustable area.

Description

. SIMULATOR - INHALATOR The utility model relates to the field of healthcare, in particular to medicines related to the administration of drugs during inhalation and for therapeutic respiration, which increases the level of carbon dioxide in the blood, and also as a breathing simulator. Known inhaler according to US Pat. GDR v 55757 class ZOK 12/01 1967, which is a vessel in which a tube is located coaxially, which is an aerosol chamber. On the side surface of the lower end of the tube holes are made for the passage of inhaled substance and air. The disadvantages of the known device is the low efficiency of saturation of the air inhaled by the substance, since the area of aerosol formation is normalized in the wall zone, moreover, mainly in the upper part of the slotted openings located on the walls of the chamber-pipe. This is confirmed by the fact that to enhance the effect, it was proposed to introduce a gear insert. The closest is the Frolov inhaler according to the patent of the USSR k-1790417 A3 class. i 61 M I5 / C2, containing a sealed vessel with an opening for inhaling air, a coaxially mounted inside of it a cylindrical aerosol chamber with spray holes that are located in the bottom of the aerosol chamber, which, in turn, is placed with a gap relative to the bottom of the vessel. the inhaler is equipped with an additional container covering the inhaler vessel and having an opening in which the breathing tube is placed with a gap. MKy Ab m 15/02

„2 -

liquid.A drop of liquid in the respiratory tract is also facilitated by the fact that the inhalation liquid foams strongly after minutes of breathing. Another disadvantage is the fact that the openings for the exit of air from the outer vessel and the inhaler are located opposite each other around the breathing tube, which sharply reduces the intensity of mixing of the inhalation-air mixture and violates the percentage of carbon dioxide in the air mixture (when used as a simulator). When using an inhaler as a simulator, the level of loads cannot be regulated by the liquid level, because a slight increase in fluid level leads to the ingress of large drops of 13 airways.

The task of creating a useful model is to increase the efficiency and safety of the use of an inhaler simulator and to expand its ability as a simulator by eliminating the ingress of liquid droplets into the respiratory tract with undisciplined breathing pulsation and the effective use of an air mixture

In FIG. I shows a general view of an inhaler simulator.

The simulator-inhaler is as follows. An aerosol chamber is installed inside the outer vessel, which consists of the bottom Yfig.kh), lid 2 and ring 3, made of coaxially located outer vessel 4 and the aerosol chamber 5 itself, at the lower end of which there is nozzle b, which is also the removable bottom of the aerosol chamber 5 The bottom of the nozzle is a co6ow perforated spherical surface with a flange for fixing on the aerosol chamber 5, and the perforation density to provide a more efficient process of aerosol formation and reduce the likelihood and droplets of liquid entering the respiratory tract, it is advisable to reduce in the direction from the periphery to the center, while leaving the central part of the bottom unperforated; the size of the undeodorized part is described by a radius 0,, 3 of the radius of the bottom of the chamber 5. In addition, the perforation on the spherical .. surface is made in the form of small holes 7, the axis of which is directed perpendicular to the tangent sphere at this point. Along the perimeter of the flange of the nozzle b, touching the bottom of the outer vessel 4, there are grooves 8 for the passage of the inhalation liquid into the inhalation chamber. A further aeration process is facilitated by the dispersant 9 installed in the aerosol chamber 5 in front of its conical part. The dispersant is made similar to the nozzle b. The return of drops of inhaled substance is promoted by the performance of the upper

 3 parts of the aerosol chamber 5 with narrowing to the installation site of the respirator. tube U and a spherical dilator C. The breathing tube DO is tightly mounted on the open upper end of the chamber 5. The outer vessel 4 is closed from above with a lid 12 with openings 13 for communication with the outer vessel. Inhalation liquid is filled in vessel 4. 14. The position of chamber 5 is fixed by ribs 15 .Between the walls of the vessel 4 and the aerosol chamber 5, an annular channel is formed in which the liquid and the gas medium circulate. Between: the bottom of the vessel 4 and the nozzle b a spherical gap is formed. The dimensions and number of holes in the nozzle b are set and conditions ensuring high spray device properties and optimum resistance by breathing.

For example, the number of holes can be at a cross section of each 0,, 4 mm.

The hole 13 in the lid 12, the channel between the walls of the outer vessel 4 and the chamber 5 and the breathing tube 10 and the nozzle for the mouth 16 are made with a cross section of at least the total area of the bottom holes 6 "bottom I, the cover 2 and the adapter ring 3 of the outer vessel have a matching hole I for communication with the atmosphere, located on their wall, and by turning the cover (or ring) relative to the bottom of the vessel I, you can adjust the size of the holes, and the volume of the outer vessel can be changed by removing the ring 2 and docking the cover 2 with the bottom 3.

The simulator-inhaler works as follows.

When inhaling due to the force of breathing, the inhalation liquid 14 is sucked into the aerosol chamber 5 through the grooves 8 and the opening 7 of the bottom nozzle b, and air is sucked in through the liquid, which is sucked through the opening 7 of the outer vessel I and the hole 13 in the cover 12. Passing through the hole 7 8 nozzles, air sparges through the liquid under the suction discharge and carries the liquid up, creating a boiling state in the entire volume of the liquid with numerous foci of spraying and spraying. With the aforementioned orientation of the holes and a variable density of the arrangement of the holes 7, the atomization ability of the device improves due to the turbulence of the flow. This is achieved due to the spherical surface of the bottom of the aerosol chamber since the liquid constantly flows from the spherical surface to the walls of the aerosol chamber, where the zone of the highest density of holes is located. Further aeration occurs due to the passage of the aerosol mixture through the dispersant 9, in which large droplets and bubbles of the aerosol mixture are destroyed,

 Part 4 of the droplets settles on the walls of the HS tube, then the aerosol-air mixture passes through a spherical expander II, in which due to a sharp decrease in the flow rate, the droplets and bubbles are completely cleaned of the aerosol mixture. This is also facilitated by the fact that the entrance of the aerosol mixture is vaporized pyrite Ts and the exit from it are at an angle to each other (for example, 120 °,). Through the respiratory mouthpiece 16, the inhalation stream flows to the patient. Small droplets deposited on the walls of the spherical expander II, breathing tube 10 flow into the inhalation chamber 5

Upon exhalation, the air mixture through a spherical expander II, the breathing tube Yu enters the aerosol chamber 5, pushes the liquid through the openings 7 and 8 of the bottom nozzle into the space between the chamber 5 and the vessel 4, and sparges through the layer of the expelled liquid, leaving through the hole 13 in the lid 12 into the outer vessel.

Thus, breathing is carried out with discharge on inhalation and resistance on exhalation. Moreover, the vacuum in the inspiration can be controlled by the amount of inhalation fluid and the size of the holes I in the outer vessel,

Due to the return breathing in the outer vessel and, accordingly, in the inhaled mixture, there is an increase in the carbon dioxide content and a decrease in the oxygen concentration, which gives a positive effect, and the location of the holes for communication with the atmosphere around the perimeter of the vessel promotes better mixing of the air, inhaled and exhaled mixture.

Thus, in comparison with the analogue, the proposed utility model of the inhaler-simulator provides complete safety of breathing with a high degree of saturation of the air with the inhaled substance, which increases the therapeutic effect. In addition, it has a more eductive effect as a simulator in connection with G wide possibilities for changing the inhalation and exhalation due to the increase in the amount of liquid and the adjustment of the size of the holes connecting the vessel with the atmosphere, as well as due to the possibility of changing the volume of the external vessel.

 /

AUTO.EA: N.A.Sazonov

j3 "A Sazonov S.H. Khvatskov

Claims (4)

1. The inhaler simulator, comprising a sealed vessel with holes for inhaling air, a coaxially mounted inside of it a cylindrical aerosol chamber with a bottom, in which the spray holes are made and which is placed with a gap relative to the bottom of the vessel, and also an additional container covering the inhaler vessel and having holes in which a breathing tube is placed with a gap, characterized in that the bottom of the aerosol chamber is made in the form of a spherical surface with holes whose axes are perpendicular about a tangent sphere at a given point.  2. The inhaler simulator according to claim 1, characterized in that a spherical disperser with holes is installed in the upper part of the aerosol chamber.  3. Inhaler simulator according to paragraphs. 1 and 2, characterized in that the breathing tube is equipped with a spherical expander. 4. The inhaler simulator according to claims 1 to 3, characterized in that the external vessel with a variable volume has an opening for communication with the atmosphere on a cylindrical surface in the area of the lid and the bottom of the vessel with an adjustable area.