RU2165269C2 - Breathing training device - Google Patents

Abstract

FIELD: medical engineering. SUBSTANCE: device has external mixing chamber having a cover and inhaler with respiratory tubes mounted inside. The inhaler unit has the shape of cylindrical glass with cover having aerosol chamber mounted inside. Chamber has perforated bottom for providing inhaled fluid to circulate mounted with free space left between it and glass. Gas- conducting canal is aligned in parallel which inlet canal is near the lower base and outlet canal being in the upper tube. Additional gas dynamic chambers are mounted between the bottom and the cover coaxially to gas-conducting canal and one above the other in height direction. An opening is available that connects their gas dynamic volumes with working volume of the mixing chamber. Outlet valve and tube tightly joined to the wide knee manometer tube are mounted in the bottom part of the inhaler unit. EFFECT: high security level of training within the broad range of parameter values. 3 cl, 1 dwg

Description

 The invention relates to the field of health, sanitation and human hygiene, and in particular to means for teaching methods of treating breathing, as well as for the effective coordination of the administration of drugs during inhalation and the regulation of carbon dioxide in the body.

 Known inhaler (RF patent N1790417, class A 61 M 15/02, publ. 23.01.93) containing a sealed vessel with an opening for inhaling air through an additional tube and a coaxially mounted cylindrical aerosol chamber with liquid with holes at the bottom for spraying medicinal substances . It also contains an external mixing chamber and can be used both in the inhalation mode and in the mode of forming resistance on inhalation and exhalation and allows to increase the carbon dioxide content in the working volume of the simulator.

 The disadvantages of the known device are due to the combination of the channel for supplying fresh air to the external chamber and the output of exhaust gases from it. Due to the difference in the specific gravity of air and carbon dioxide and their separation along the height of the chamber, the effectiveness of the training effect is reduced. In addition, the amount of liquid contained in the aerosol chamber is not regulated by anything, which limits the functionality of the simulator.

 Also known is a breathing simulator (RF patent N 2112557, publ. 06/10/98), containing an external mixing chamber with a cover, on which openings are made for supplying and removing air, an inhaler installed inside the outer chamber in the form of a vessel, inside of which an aerosol chamber with a breathing tube passing through an opening in the lid of the outer chamber, the bottom of which is made with holes and separated by a gap from the bottom of the vessel chamber of the inhaler. The simulator has a gas channel with inlet and outlet channels, hermetically connected to the hole for air inlet and outlet in the cover of the outer chamber, and the passage of the breathing tube through this cover is gapless. The simulator may have an ionizer installed in the gas channel, and a removable partition to change the working volume of the mixing chamber. In the known device, the fresh air supply channels to the mixing chamber and the exhaust gas outlet from it are separated, and the inlet valve of the gas supply channel is located in the lower part of the outer chamber, which ensures optimal use of the hypercapnic mixture concentrated in the bottom of the device. The simulator performs both therapeutic and preventive-training functions with the optimal one-time and individual choice of its parameters.

 However, the amount of fluid contained in the aerosol chamber, on which the specific value of the resistance to breathing during medical training depends, is not regulated or controlled in the known device. This limits the functionality of the device in the medical and training process, when it is necessary to flexibly and quickly change the respiratory resistance on the inspiration and expiration of a given patient or to take into account the individual characteristics of different patients.

 The technical problem solved by the invention is to expand the parametric and functional capabilities of the device and ensure the safety of the training process in a wide range of parameters by introducing a feedback system into the process of breathing training at the level of gas dynamics and aeroionization of the air flow.

This is achieved by the fact that in the well-known breathing simulator containing an external mixing chamber with a cover and openings for supplying and discharging air, an inhaler is installed inside, the body of which is made in the form of a glass with a cover and inside of which is located an aerosol chamber hermetically connected in the upper parts with a breathing tube, the bottom of which is made with holes and installed with a gap relative to the bottom of the inhaler, the breathing tube with a gap passes through the hole in the cap of the inhaler and hermetically passes through a hole in the lid of the outer chamber, a cylindrical gas channel with inlet and outlet valves installed parallel to the axis of the inhaler, and connected to the second hole in the lid of the outer chamber, the simulator is equipped with two additional gas-dynamic chambers located one above the other, made with holes connecting them with a mixing chamber, in which the chambers are mounted coaxially to the gas-conducting channel, embracing respectively the inlet and outlet valves, vertically mounted bone manometer with two cylindrical bends which are hermetically connected with additional hoses gazodinamicheskimi chambers in the inhaler body in the bottom part of the discharge passage is a pipe hermetically connected with wide knee liquid manometer
The breathing simulator is equipped with a support cup mounted on the bottom of the mixing chamber, a piezoelectric support element with conductive plates, the support cup is made in such a way that the inhaler body, which rests on the piezoelectric element, with the bottom resting on it, and an electric arrester located on the base of the gas supply channel and connected to the conductive plates of the piezoelectric element.

 In addition, the breathing simulator is equipped with a heating element located in the support cup under the bottom of the inhaler body.

 The invention is illustrated in the drawing, which shows a General view of a breathing simulator.

 The simulator contains an external mixing chamber 1 with a cover 2, inside of which an inhaler 3 with a breathing tube 4 is mounted axisymmetrically, which is sealed in the hole 5 of the cover of the external mixing chamber 1. The inhaler 3 is made in the form of a cylindrical glass 6 with a cover 7, in which an aerosol chamber is coaxially mounted 8, the upper end of which is connected to the breathing tube 4. An opening 9 is made in the cover 7 of the inhaler 3, through which the breathing tube 4 passes with a gap. The bottom 10 of the aerosol chamber 8 is made with openings for the compass tion of inhaled fluid and is located with a gap relative to the glass 6.

 Parallel to the axis of the inhaler 3 is a gas channel 11 with an inlet channel 12 at the lower base and an exhaust channel 13 in the upper pipe 14. The gas channel 11 is vented to the atmosphere through an opening 15 on the cover of the outer mixing chamber 1, additional gas-dynamic chambers 16 and 17, located coaxially with the gas channel 11 and in height above each other and having an opening 18 connecting their gas-dynamic volumes with the working volume of the mixing chamber. Symmetrically with the gas channel 11 in the volume of the mixing chamber 1, a manometer with cylindrical elbows 19 and 20 is vertically mounted. Moreover, both additional gas-dynamic chambers in the upper part are equipped with nozzles that are flexiblely connected to the elbows of the manometer by flexible hoses 21 and 22. In the bottom of the inhaler 6 there is an exhaust valve 23 and a pipe sealed by a channel 24 with a wide elbow 19 of the pressure gauge.

 At the bottom 25 of mixing chamber 1, a piezoceramic, in a particular case annular, element 26 and a support cup 27 are installed, into which the inhaler body 6 is included on a sliding fit and telescopically, the bottom of which 28 rests on a piezoceramic ring 26 having conductive plates 29 isolated on ends, and acting as a piezoelectric transformer or transducer.

 At the lower base in the gas-conducting channel 11 there is an electric spark gap 30 connected to the conductive plates 29 of the piezoceramic element 26. A heating element 31 can be located directly under the bottom of the inhaler 28. The chamber 1 for volume control can also have removable partitions. In the inhaler 6 there is an inhalation liquid 32, and the liquid level in the system is fixed by the position of the float 33 of the pressure gauge.

 The breathing simulator works as follows.

 When inhaling, the exhaust channel 13 is closed and air enters the mixing chamber 1 through the hole 15, the gas-conducting channel 11 and the open inlet channel 12, through the volume of the chamber 16, then through the hole 18 and enters the inhaler 3 through the hole 9 in the cover 7. Depending on of the given training regime, the air is also activated by the spark gap 30 in the chamber 11. Then the gas mixture is sucked in with the ions through the hole in the bottom 10 of the aerosol chamber 8, sparges through the liquid 32, changes the pressure balance in the knees of the pressure gauge 19 and 20, and rises up and through the respirator a new tube 4 enters the patient. When you exhale, the air mixture through the breathing tube 4 enters the aerosol chamber 8, pushes the liquid through the hole in the bottom 10 into the gap between the bottom of the glass 6 and the bottom of the chamber 8, generates a pressure pulse in the pressure gauge circuit and enters the volume through the wall layer of the inhaler 3 into the hole 9 mixing chambers 1.

 Saturated carbon dioxide exhaled air is concentrated in the bottom of the mixing chamber 1. Vapors of moisture are concentrated in the upper part of the chamber 1 and cyclically removed, passing through the hole 18 in the gas-dynamic chamber 17, and then through the exhaust channel 13 and the pipe 14. The presence of two gas-dynamic intermediate chambers 16 and 17, coaxially covering the gas channel 11 and its valves - inlet 12 and outlet 13, and the valves of the liquid manometer, the elbow of which 19 and 20 are connected to the volume of the inhaler 6, allows flexible control of resistance to inhalation and exhalation in the simulator. In this case, the connecting hoses 21, 22 and 24 perform the functions of internal feedbacks in the system. Through the exhaust valve 23 in the bottom of the inhaler 6, a part of the inhalation liquid along the channel 24, depending on the pressure level in the system, flows into the channel of the manometer. By adjusting the volume of inhalation fluid in the device, the level of which is fixed by the position of the float 33 of the manometer, it is possible to control not only the resistance of the gas-liquid circuit on the patient's inhalation and exhalation, but also to regulate their relations.

 The presence of the piezoelectric support element 26, which performs the functions of a piezoelectric transformer, and an electric spark gap 30 located in the gas-conducting channel 11, forms the second internal feedback loop in the breathing simulator. When inhaling, the liquid in the inhaler 3 rises and the pressure on the surface of the piezoelectric support element 26 decreases, since the body of the inhaler 6 is telescopically displaced in the support cup 27.

 After the end of the inhalation phase, the liquid falls down and a pressure pulse is transmitted through the bottom of the inhaler 3 to the piezoelectric element 26. As a result of the piezoelectric effect, a voltage pulse is generated on the conductive plates 29 of the element 26, which is supplied to the spark gap 30, the electrode system of which can operate in corona modes or spark discharge. As a result, the magnitude and duration of the voltage pulse generated by the circuit elements 3, 26, 30 will depend on the main parameters of the patient’s inhalation-exhalation cycle, which means that the level and maximum of activation (ionization) of the air flow contains an internal feedback link. Given the inertia of the gas-dynamic path, a pulse in the spark gap 30 can also be initiated in the pause between inspiration and expiration. And with optimal tuning of the system as a whole, the simulator automatically performs both therapeutic and training functions.

Claims (3)

 1. A breathing simulator containing an external mixing chamber with a cover and openings for supplying and discharging air, mounted inside an inhaler, the body of which is made in the form of a glass with a cover, inside which an aerosol chamber is located coaxially, hermetically connected in the upper part to the breathing tube, the bottom of which is made with holes and installed with a gap relative to the bottom of the inhaler, and the breathing tube with a gap passes through the hole in the cap of the inhaler and hermetically passes through the hole in the ke of the outer chamber, a cylindrical gas channel with inlet and outlet valves installed parallel to the axis of the inhaler, and connected to a second hole in the lid of the outer chamber, characterized in that the simulator is equipped with two additional gas-dynamic chambers located one above the other, made with holes connecting them with a mixing chamber, in which the chambers are mounted coaxially to the gas-conducting channel, embracing the inlet and outlet valves, respectively, vertically mounted by a liquid a pressure gauge with two cylindrical elbows, which are hermetically connected by hoses to additional gas-dynamic chambers, in the inhaler body in its bottom part there is an exhaust channel with a nozzle sealed to the wide elbow of the liquid manometer.  2. The breathing simulator according to claim 1, characterized in that it is equipped with a support cup mounted on the bottom of the mixing chamber and a piezoelectric support element with conductive plates, the support cup is made in such a way that the inhaler body enters it telescopically and on a sliding fit, which bottom rests on a piezoelectric element, and an electric spark gap located on the base of the gas-conducting channel and connected to the conductive plates of the piezoelectric element.  3. The breathing simulator according to claim 1 or 2, characterized in that it is equipped with a heating element located in the support cup under the bottom of the inhaler body.