RU2131750C1 - Respiration trainer - Google Patents

Abstract

FIELD: medicine. SUBSTANCE: trainer is designed to regulate composition of inhaled gas mixture. External mixing chamber of trainer has cover with air inlet and outlet holes. Mixing chamber accommodates inhaler formed as closed vessel containing coaxially positioned aerosol chamber which bottom is provided with holes for delivery of inhaled substance. It is arranged with space relative to closed vessel bottom. Respiratory tube is coupled to aerosol chamber. Gas mixture inlet and outlet holes are made in upper and lower parts of side surface of external mixing chamber. These holes are provided with facilities for regulation of respiratory mixture composition. Regulating facilities may overlap the holes completely or partially. Trainer is convenient in use, and its mass and overall dimensions are reduced. EFFECT: enhanced efficiency of gas exchanger. 5 cl, 1 dwg

Description

 The invention relates to medicine, more specifically to medical devices used for the prevention and treatment of respiratory diseases, as well as in teaching the most effective breathing methods that help protect the body from the harmful effects of environmental factors.

State of the art
Known breathing simulator according to the author's certificate of the USSR 1588423 A1 (Kolontaevsky F.V. and others) 08/30/90, A 61 M 16/00. The device provides a predetermined resistance to expiration, removal of dust and condensate from the inhaled air, as well as cleaning the inhaled air of dust and condensate. The device comprises a body with a hollow cylindrical threaded part and exhalation channels, a mouthpiece, a removable bottom, an exhalation regulating throttle, an inspiratory valve, and an exhalation resistance scale.

 The well-known breathing simulator according to the author's certificate of the USSR 1680171 A1 (KAI named after academician SP Korolev) 09/30/91 A 61 H 31/02, is intended for physical therapy patients with bronchial asthma and can increase the therapeutic effect by providing smooth muscle vibration massage bronchi and withdrawal of excess exhaled air. It contains a generator of low and high pressure, a mouthpiece, a breathing line and a check valve that respects breathing. Known solutions do not allow to obtain a respiratory mixture with a low oxygen content, are complex in design and not reliable in operation.

 It is advisable to consider the Frolov inhaler (SU 17904417 A3 (Frolov V.F. et al.) January 23, 93 A 61 M 15/02) as the closest analogue, which is essentially a breathing simulator. Its design provides wide functionality and allows both inhalation mode and breathing resistance mode at the entrance and exhalation under conditions of moderate hypoxia. The known device contains an external mixing chamber, inside of which the inhaler itself is located, made in the form of a cylindrical closed vessel (a glass with a lid) and an aerosol chamber coaxially installed inside it. The bottom of the aerosol chamber is perforated and installed with a gap relative to the bottom of the enclosed vessel enclosing it. The holes in the bottom of the aerosol chamber serve to supply inhaled substance, passage and crushing of liquid, gases, and also to provide the necessary resistance to breathing. An opening is made in the cover of the external mixing chamber, in which a breathing tube is installed with a gap, which also passes through the opening in the cover of the closed vessel of the inhaler with a gap and connected to the upper end of the aerosol chamber. The hole for the breathing tube in the lid of the outer mixing chamber is at the same time a hole for supplying / discharging air. In the outer chamber, the chemical composition of the inhaled air mixture is corrected by mixing atmospheric air and the air exhaled in previous cycles (the effect of return breathing). The hydrodynamic factors that occur during breathing through a liquid cause increased resistance to inhalation and exhalation, an increase in the content of carbon dioxide in the gas mixture, and the creation of moderate hypoxia.

 However, the known closest analogue is not without drawbacks: firstly, it creates a not quite satisfactory organization of the gas exchange process, which is determined by the fact that fresh air is supplied to the external chamber and the exhaust gas is removed from it through the same opening through which the breathing tube passes and which coaxially with the inhaler inlet. Since the hypoxic mixture, due to heavier carbon dioxide than air, accumulates in the lower part of the outer chamber, it is used ineffectively when inhaling. To compensate, it is necessary to double the volume of the outdoor camera, which naturally leads to an increase in dimensions, weight, material consumption and cost of the product, and reduces usability. Secondly, taking into account the individual characteristics of a particular user-patient, determined by age, gender, physical characteristics, in such a design, it is necessary to change the volume of the outer chamber, for example by adding adjustment rings, and therefore disassemble-assemble the device. This further reduces its consumer qualities. In addition, it is practically impossible to control the degree of hypoxia, i.e. adjust the composition of the gas respirable mixture.

 The invention is aimed at solving the problem of creating a multifunctional, providing efficient gas exchange, by using the resulting hypoxic mixture, simple, convenient in the head for use and its own device during operation, which has all the therapeutic qualities of its analogue.

 The technical result achieved by using the present invention is to increase the efficiency of gas exchange by using the resulting hypoxic respiratory mixture with the possibility of adjusting the degree of hypoxicity, improving ease of use and reducing overall dimensions.

 The technical result is achieved due to the fact that in the breathing simulator containing an external mixing chamber with a hole for supplying and discharging air in the cover of the external chamber, an inhaler is installed inside the outer chamber in the form of a closed vessel, inside of which an aerosol chamber is coaxially mounted, the bottom of the aerosol chamber is made with openings for the supply of inhalable substance and is located with a gap relative to the bottom of the closed vessel, and a breathing tube connected to the aerosol chamber, the passage of the respiratory channel Erez outer cover gapless mixing chamber formed in the upper and lower portions of the outer mixing chamber has openings for supplying and discharging the gaseous mixture, equipped with means for adjusting the composition of the gas mixture.

 The technical result is enhanced by making additional holes for supplying and discharging the gas mixture located on the peripheral part of the cover of the outer mixing chamber.

 Ease of use and accuracy of adjusting the composition of the mixture is provided by means of adjusting the composition of the respiratory mixture in the form of removable plugs or valves.

 Ease of use is also enhanced by the implementation of the breathing tube supply and removal of the gas mixture in the form of a rigid or flexible design.

 Due to the implementation of the breathing simulator as described in this application, a controlled change in the composition of the respiratory mixture is carried out with a greater or lesser degree of its hypoxicity. The hypoxicity of the gas mixture is associated with the amount of exhaled contained in it, i.e., oxygen depleted air. The greater the proportion of expired air in the mixture, the lower the oxygen content in it. Already with four holes made in the wall of the external chamber of the simulator, a wide range of regulation of the composition of the inhaled gas mixture is provided. With open or partially open upper openings, the mixture contains more oxygen, and, conversely, with open lower openings, its lower quality, since the mixture with the high content of gas exhaled in the preliminary respiratory cycle is primarily inhaled.

 The following example of a breathing simulator allows a more detailed explanation of the obtained technical result.

 In the drawing, a longitudinal section of the proposed breathing simulator.

Example
The simulator is an external mixing chamber 1, made in the form of a box with a cover 2, and an inhaler 3 located inside the external chamber 1 with a respiratory channel 4 and a breathing tube 14 connected to it. A hole 5 is made in the cover 2 of the external chamber 1 for the passage of the respiratory channel 4 moreover, the channel 4 is installed in the hole 5 without a gap. The inhaler 3 is made in the form of a closed vessel 6, which is, for example, a cylindrical glass with a lid 7, in which the aerosol chamber 8 is coaxially mounted, the upper end of which is the respiratory channel 4, which also passes with a gap through the opening 9. The bottom 10 of the aerosol chamber 8 made with holes for the supply of inhalable substance and is located with a gap relative to the bottom of the closed vessel 6. In the upper and lower parts of the side surface of the outer chamber 1 holes 11 are made, which are equipped with means for regulation the composition of the respiratory gas mixture, such as plugs or valves. In the given specific example, the plugs 12, depending on the conditions of the therapeutic task, can be removed or installed in the corresponding holes. The upper or lower row of the hole may be blocked in whole or in part. If it is necessary to ensure a greater degree of hypoxicity, the plugs are installed in the upper holes and, conversely, to obtain a respiratory mixture with a lower content of exhaled air in previous cycles, the plugs are installed at the bottom. In addition, the simulator can be equipped with holes 13 made on the periphery of the cover 2. A tube 14 for supplying and removing air is connected to the respiratory channel 4, either in the form of a rigid tube or in the form of a flexible breathing hose.

 The breathing simulator works as follows.

 Before conducting a respiratory training session, depending on the specific characteristics of the user (age, gender, duration of training on the simulator, current state of health, etc.), plugs 12 are installed in the corresponding holes 11, 13 and water is poured into the inhaler 3. When inhaling air passes through holes 11, 13 in the wall or cover of the outer chamber 1, through the hole 9 in the cover 7 and enters the inhaler 3. Then the gas mixture is sucked through the hole in the bottom 10 of the aerosol chamber 8, sparges through a liquid that is Xia under discharge suction, and rises up through the breathing channel 4 is supplied to the user.

 When exhaling, the air mixture through the respiratory channel 4 enters the aerosol chamber 8, pushes the liquid through the holes in the bottom 10 into the gap between the bottom of the closed vessel 6 and the bottom of the aerosol chamber 8, sparging through the liquid, enters the space between the closed vessel 6 and the aerosol chamber 8 and exits through the hole 9 in the lid 7 into the outer chamber. Due to the fact that the respiratory channel 4 is installed in the hole 5 without a gap, the air coming up through the gap 9 pushes down the gas of the previous breathing cycle. Saturated carbon dioxide exhaled air as heavier is concentrated in the bottom of the outer chamber 1. In subsequent cycles, it is used as a hypoxic mixture for breathing in conditions of reduced hypoxia.

 The invention can be used when training breathing in the regime of resistance on inhalation and exhalation, in the mode of moderate controlled hypoxia, including with the introduction of aerosol therapeutic agents. Therefore, the breathing simulator can find application not only in traditional medicine as a means of treating and preventing diseases, but also in the field of sports, as well as a means of personal respiratory hygiene to develop and maintain an optimal breathing method that reduces the harmful effects of the environment.

Sources of information
1. SU patent 1790417 A3 (Frolov V.F. et al.) 01/23/93, A 61 M 15/02.

 2. SU 1588423 A1 (Kolontaevsky F.V. et al.), 08.30.90, A 61 M 16/00.

 3. SU 1680171 A1 (KAI named after Academician S.P. Korolev), 09/30/91, A 61 H 31/02.

Claims (5)

 1. A breathing simulator containing an external mixing chamber with an opening for supplying and discharging air in the cover of the external mixing chamber installed inside the external mixing chamber, an inhaler in the form of a closed vessel, inside of which an aerosol chamber is coaxially mounted, the bottom of the aerosol chamber having openings for supplying an inhaled substance and is located with a gap relative to the bottom of the closed vessel, a breathing tube connected to the aerosol chamber, characterized in that the passage of the respiratory channel is connected It is made with an aerosol chamber through the cover of the outer chamber and is clearance-free; openings for supplying and discharging the gas mixture are provided in the upper and lower parts of the side surface of the outer mixing chamber, equipped with means for adjusting the composition of the respiratory mixture, which are installed with the possibility of completely or partially blocking the openings.  2. The breathing simulator according to claim 1, characterized in that in the lid of the external mixing chamber there are additional openings for supplying and discharging the gas mixture located on its peripheral part.  3. The breathing simulator according to claim 1, characterized in that the means for adjusting the composition of the respiratory gas mixture are made in the form of removable plugs or valves.  4. The breathing simulator according to claim 1, characterized in that the breathing tube for supplying and discharging the gas mixture is made in the form of a rigid structure.  5. The breathing simulator according to claim 1, characterized in that the breathing tube for supplying and discharging the gas mixture is made in the form of a flexible structure.