RU2112557C1 - Respiration training apparatus - Google Patents

Abstract

FIELD: public health, in particular, sports, working of optimum respiratory method. SUBSTANCE: respiration training apparatus has mixing chamber, inhaler mounted within mixing chamber and made in the form of closed vessel, and aerosol chamber coaxially positioned within closed vessel. Aerosol chamber is connected with respiratory pipe extending in spaced relation through closed opening in inhaler vessel closure and through closure of outer mixing chamber. Aerosol chamber bottom is provided with inhalation substance supply openings and is spaced from closed vessel bottom. Respiratory pipe is positioned in opening so that it extends through outer chamber closure without space between them. Air supply/discharge opening in outer chamber closure is offset relative to opening through which respiratory pipe extends. Apparatus has gas channel provided with inlet and outlet valves and positioned in outer mixing chamber. Gas channel is offset relative to inhaler axis. Inlet valve is positioned at lower end of gas channel in bottom part of outer mixing chamber and outlet valve is arranged at gas channel upper end connected with air supply/discharge opening. In case ionizer and/or activator such as emitter or aerosol generator are available, they are mounted in gas channel between inlet and outlet valves. EFFECT: increased efficiency in usage of hypercapnic mixture and ionized gas produced and provision for working of optimum respiratory method reducing adverse action of environment. 3 cl, 1 dwg

Description

 The invention relates to public health, sanitation and human hygiene, namely, to means for breathing for therapeutic and prophylactic purposes and, above all, when learning methods of the most effective breathing to protect the body from the harmful effects of the environment.

 The prior art is characterized by the following technical solutions.

 Known inhaler a. from. N 1554915 (Egin N. L.), cl. A 61 M 15/02, 04/07/90 containing a breathing tube with three consecutive inlets of aerodynamically disconnected channels: a dry air supply channel, a vapor-air mixture supply channel and a drug substance supply channel. In the breathing tube at the inlet to which the channel for supplying atmospheric air is connected, an ionizer is installed to the point of connection of the other two channels. The vapor-air mixture supply channel contains a water tank with a heating element, and the drug supply channel contains a nebulizer installed in front of the entrance to the breathing tube.

 This inhaler can be used as a breathing simulator only in the inhalation mode and does not provide for the possibility of using it as a multifunctional breathing simulator, in particular, in the breathing resistance mode on inspiration and expiration and in the breathing mode under conditions of hypercapnia and moderate hypoxia.

 The breathing simulator has much greater potential using the Frolov inhaler described in USSR patent N 1790417 (V. Frolov and others), class. A 61 M 15/02 from 01/23/93. Its design allows the simulator to be used both in the inhalation mode and in the breathing resistance mode on inhalation and exhalation and in the breathing mode under conditions of hypercapnia and moderate hypoxia. The respiratory simulator 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 opening for the passage of the breathing tube in the lid of the external mixing chamber is at the same time an opening for supplying / discharging air. This hole, as well as the hole in the cap of the inhaler are aligned with the inhaler.

 In the external chamber of this simulator, air is prepared according to its chemical composition due to mixing of atmospheric air and exhaled from previous cycles (the effect of return breathing). A useful effect is created due to hydrodynamic factors that occur when breathing through a liquid, which increase the resistance to inhalation and exhalation, the increased content of carbon dioxide (hypercapnia) in the gas mixture, and thereby create moderate hypoxia.

 The simulator described in the above patent is a prototype of the invention.

 With all the advantages of the prototype simulator, the organization of the gas exchange process in it is not entirely satisfactory. This, in particular, is due to the fact that the supply of fresh air to the external chamber and the exhaust gas from it takes place through the same opening through which the breathing tube passes and which is aligned with the inlet of the inhaler. Since the hypercapnic mixture due to the denser (1.5 times) carbon dioxide accumulates in the lower part of the outer chamber compared to air, its ineffective use when inhaling. To compensate for this "failure" it is necessary to increase the volume of the outer chamber, which is undesirable.

 In addition, in some cases, an ionized and / or activated gas mixture is necessary for breathing. The prototype simulator does not imply the installation of an ionizer or activator (an electromagnetic emitter, an aerosol generator) in it to receive it. If, in particular, you install the ionizer at the entrance to the breathing tube, as is done in the known devices, the nature of the gas exchange process will not allow you to use the resulting mixture quite effectively. In addition, moisture particles and anthropotoxins contained in exhaled air can adversely affect the operation of the ionizer (activator).

 The technical problem solved by the invention is that, while preserving the multifunctionality of the prototype simulator in terms of breathing modes, to organize a gas exchange process that ensures the efficient use of both the resulting hypercanic mixture and ionized (activated) gas.

 To solve this technical problem, the breathing simulator contains, as is well known, an external mixing chamber with an air supply / exhaust hole in the cover of the external chamber, an inhaler mounted inside the external mixing chamber, made in the form of a closed vessel, inside of which an aerosol chamber is coaxially mounted, with the bottom the aerosol chamber is made with holes for supplying the inhaled substance and is located with a gap relative to the bottom of the closed vessel, and a breathing tube connected to the exit of the aerosol chamber and passing with a gap through the hole in the cover of a closed vessel of the inhaler and through the cover of the outer mixing chamber. Unlike the known device, it is equipped with a gas-conducting channel located in the outer mixing chamber and offset relative to the axis of the inhaler with inlet and outlet valves, the passage of the breathing tube through the cover of the outer chamber is clearance-free, the hole for supplying / discharging air in the cover of the outer chamber is shifted relative to the passage opening breathing tube, and the inlet valve of the gas channel is located at its lower end in the bottom of the outer chamber, and the exhaust at its upper end, Hinnom to the opening for supplying / air outlet.

 If necessary, use an ionized and / or activated gas mixture and, respectively, the presence of an ionizer and / or activator, they are installed in the gas channel between the inlet and outlet valves.

 At least one removable partition may be installed inside the outer chamber to change the working volume of the outer chamber.

 Due to the presence of the gas channel, shifted relative to the axis of the inhaler, and the location of its inlet valve in the lower part of the outer chamber during inhalation, the best use of the hypercapnic mixture concentrated in the bottom is ensured. The upper location of the outlet valve of the gas channel near the air supply / exhaust hole provides for the most rapid removal of moisture particles contained in the exhaled air during exhalation and, on the one hand, more efficient use of ionized (activated) components of the gas mixture, and on the other hand, protects those installed in the gas pipeline channel ionizer activator from exposure to exhaled water vapor and anthropotoxins.

 The following example of a breathing simulator allows a more detailed explanation of the resulting technical effect.

 The drawing shows a longitudinal section of the proposed breathing simulator.

 The simulator is an external mixing chamber 1, made in the form of a box with a cover 2, and an inhaler 3 with a breathing tube 4 located inside the outer chamber 1. A hole 5 is made in the cover 2 of the outer chamber 1 for the passage of the breathing tube 4, and the tube 4 is installed in the hole 5 without clearance. The inhaler 3 is made in the form of a closed vessel 6, which is, for example, a cylindrical glass with a cap 7, in which an aerosol chamber 8 is coaxially mounted, the upper end of which is connected to the breathing tube 4. An opening 9 is made in the cap 7 of the inhaler, through which passes with a gap breathing tube 4. The bottom 10 of the aerosol chamber 8 is made with holes for supplying the inhaled substance and is located with a gap relative to the bottom of the closed vessel 6.

 In the outer chamber 1 there is a gas conducting channel 11, the axis of which is offset from the axis of the inhaler 3. At one end of the gas conducting channel 11, an inlet valve 12 is installed at the bottom of the outer chamber 1. The exhaust valve 13 is installed in the upper pipe 14 of the gas conducting channel 11, which is led out into the atmosphere through the hole 15 for supplying / discharging air. The hole 15 in the cover 2 of the outer chamber is offset from the hole 5 for the passage of the breathing tube 4.

 To change the working volume of the outdoor camera 1, a removable partition 16 is installed in it. The position and number of removable partitions 16 is determined by the required working volume of the camera.

 To obtain an ionized and / or activated respiratory mixture in the gas conduit 11 between the inlet 12 and outlet 13 valves, a corresponding functional unit is installed (not shown in the drawing), which can be made in the form of an ion generator of the desired polarity, an emitter with a certain wavelength and a set of interchangeable filters or without them, a therapeutic aerosol generator. The specific implementation of these nodes is not critical for solving the task and therefore is not given. Its performance is determined by the requirements for the nature of the respiratory mixture. However, it is important that in the presence of an ionizer (activator) they are installed precisely in the gas-conducting channel 11. The gas-conducting channel 11 can be, in particular, formed by the housing of the ionizer or activator itself, or both together. It is possible to perform a breathing simulator with a set of interchangeable gas-conducting channels 11 having a different set of activating elements.

 The breathing simulator works as follows.

 When inhaling, the exhaust valve 13 is closed. Air passes through the gas channel 11, the open intake valve 12 and enters through the hole 9 in the cover 7 of the inhaler 3. Depending on the type of activator installed in the gas channel 11 (or forming channel 11), air passing through channel 11 is activated as necessary , for example, it is saturated with negative oxygen ions under the influence of an electric discharge of the ionizer and / or particles with atoms excited by electromagnetic radiation.

 Next, the gas mixture is sucked in through the openings in the bottom 10 of the aerosol chamber 8, sparges through the liquid under the suction vacuum, rises and through the breathing tube 4 enters the patient.

 When exhaling, the air mixture through the breathing tube 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 leaves through the hole 9 in the cover 7 into the outer chamber 1. Due to the fact that the breathing tube 4 is installed in the hole 5 without a gap and due to the presence of the upper exhaust valve 12 in the gas-conducting relative to the inhaler 3 The air coming up through the gap 9 displaces the ionized (activated) gas of the previous breathing cycle down. Saturated with carbon dioxide, exhaled air as heavier is concentrated in the bottom of the outer mixing chamber 1.

 Moreover, the moisture vapor contained in the exhaled air, whose density is 1.6 times less than air, is concentrated in the upper layer, and therefore it is primarily removed through the open exhaust valve 13 and the nozzle 14. Due to this, the losses of activated particles that would have occurred due to them are reduced contacts with water vapor and wall condensate. In addition, the passage through activators located in the gas-conducting channel 11 only of fresh atmospheric air and only upon inhalation allows one to strictly maintain the parameters of gas activation and improve the working conditions of the activators.

 It should be borne in mind that with such an organization of gas exchange during inspiration, three pools of gases sequentially enter the patient's respiratory tract. First, gases come from the upper layer of the outer chamber 1, containing less carbon dioxide. Then the gases of the bottom layer with a maximum concentration of carbon dioxide and at the end are activated gases, the composition of which is practically equivalent to fresh air. This sequence ensures the almost complete use of all components of the respiratory mixture, including hypercapnic, and also allows you to influence different structures of the respiratory system with a wide range of therapeutic agents.

 Given the variety of functions provided by the proposed breathing simulator, possible breathing patterns and parameters of the respiratory mixture, the optimal working volume of the outer chamber 1 may be different. The change in the working volume of the outer chamber 1 can be obtained by rearranging the removable partition 16 or installing an additional partition 16. The presence of removable partitions 16 also allows for optimal working volume for patients of different ages and with different physical data.

 The invention can be used to train breathing in the regime of resistance on inhalation and exhalation, in the regime of hypercapnia and moderate hypoxia with the introduction of aerosol medications. 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.

Claims (3)

 1. A breathing simulator comprising an external mixing chamber with an opening for supplying / discharging air in the cover of the external chamber, an inhaler 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 being made with holes for supplying the inhaled substance and located with a gap relative to the bottom of the closed vessel, and a breathing tube connected to the aerosol chamber passing through an opening in the lid of the outer mixing chamber and with a gap of without a hole in the lid of a closed vessel, characterized in that it is equipped with a gas channel with inlet and outlet valves installed in the outer chamber with an offset relative to the axis of the inhaler, the passage of the breathing tube through the lid of the outer chamber is clearance-free, the hole for supplying / discharging air in the lid of the outer chamber offset from the opening for the passage of the breathing tube, and the inlet valve of the gas conduit is located at its lower end in the bottom of the outer chamber, and the exhaust on its upper the end connected to the air inlet / outlet.  2. The simulator according to claim 1, characterized in that in the presence of an ionizer and / or activator, they are installed in a gas-conducting channel between the inlet and outlet valves.  3. The simulator according to claim 1, characterized in that at least one removable partition is installed inside the outer mixing chamber to change the working volume of the outer chamber.